Pneumatic tire with groove having three different cross-sectional shapes

A pneumatic tire is provided which has an improved tread portion capable of preventing a wandering phenomenon caused by the rain-grooves of the roads and reducing the running noise of the tire. The circumferentially extending main groove is made up of parts having at least three pitch lengths wherein the short pitch length has a first cross-sectional shape and the long pitch length has a second cross sectional shape or a third cross section shape and the groove width at the tread face in the second and third cross sectional shapes is in the range of from 1.05 to 2.5 times that in the first-cross sectional shape.

BACKGROUND OF THE INVENTION 
The present invention relates to a pneumatic tire having an improved tread 
portion which is capable of preventing the wandering phenomenon of a 
vehicle when running on a road provided with rain grooves. The present 
invention is also directed to a tire tread which is capable of reducing 
the running noise of the tire. 
In recent years, as the expressway network is developed and vehicle 
performance is remarkably improved, to obtain a superior drainage 
performance during high speed running, tires having wide main grooves 
extending substantially straight in the circumferential direction of the 
tire are widely used, for example, in passenger cars. 
In some regions in some countries, to improve drainage and thereby to 
prevent accidental slip under wet conditions, so called rain groove are 
provided on the roads surface. The rain grooves are parallel narrow 
grooves extending in the longitudinal direction of the road and their 
pitch in the transverse direction of the road are about 15 to 30 mm. 
Therefore, when tires having the above-mentioned pattern run on such a 
road, the edges of the tire grooves and the edges of the rain grooves 
often engaged with each other, and the rain groves interfere with the 
lateral movement of the tire. This is felt by the driver as a wandering 
phenomenon of the vehicle. If the pitch of the main grooves of a tire 
coincides with the pitch of the rain grooves, there is the possibility 
that the tire grooves and the rain grooves will tightly engaged each other 
during running, which can be very dangerous. 
In a tread pattern including straight wide main grooves, a so called air 
resonance noise is generated when running on well-paved roads at high 
speed. The air existing in the tubes formed between the road surface and 
main grooves in the ground contacting patch is excited by vibrations of 
the tread elements and pulsative air flow, and the air resonates at a 
certain frequency (about 800 to 1250 Hz) to generate an air resonance 
noise. If the depth of the main grooves is decreased, the resonance noise 
can be reduced, but the wet performance of the tire is greatly decreased. 
An object of the present invention is therefore to provide a pneumatic tire 
in which the wandering phenomenon caused by rain grooves is effectively 
prevented. 
Another object of the present invention is to provide a pneumatic tire in 
which the running noise due to air resonance in the main grooves is 
effectively reduced without sacrificing the wet performance of the tire. 
SUMMARY OF THE INVENTION 
According to one aspect of the present invention, a pneumatic tire 
comprises 
a main groove extending in the circumferential direction of the tire and 
lateral grooves extending in the axial direction of the tire, 
the lateral grooves intersecting the main groove to divide the main groove 
into a plurality of main groove parts, each defined by the 
clrcumferentially adjacent intersections of the lateral grooves with the 
main groove, 
the main groove parts having at least three different circumferential pitch 
lengths: a short pitch length, a middle pitch length and a long pitch 
length, 
the short pitch length having a first cross sectional shape, 
the long pitch length having a second cross-sectional shape or a third 
cross sectional shape which is different from the first cross sectional 
shape. 
In a meridian section including the tire axis, the first cross sectional 
shape comprises a pair of opposite groove sidewalls, each of which extends 
straight from the tread surface to the groove bottom at a certain 
inclination angle so that the groove width increases towards the radially 
outside of the tire. 
The second cross sectional shape comprises a pair of opposite groove 
sidewalls, one of which extends straight from the tread surface to the 
groove bottom at a certain inclination angle, and the other is convexly 
curved and extends from the tread surface towards the groove bottom, so 
that the groove width increases towards the radially outside of the tire. 
The third cross sectional shape comprises a pair of opposite groove 
sidewalls, each of which is convexly curved and extends from the tread 
surface towards the groove bottom, so that the groove width increases 
towards the radially outside of the tire. 
The groove width at the tread face in the second and third cross sectional 
shapes is in the range of from 1.05 to 2.5 times that in the first 
cross-sectional shape. 
Accordingly, as the above-mentioned second and third cross sectional shapes 
include a convexly curved sidewall, the edges of those groove parts are 
not sharp. Further, as the first shape is different from the second and 
third shapes with respect to the groove width at the tread face, the edges 
of the main groove change in axial positions as the tire rotates. 
Furthermore, the cross-sectional shape is also changed. 
Therefore, the groove parts having the second or third shape become 
superior in running across the rain groove edges. As a result, the 
wondering phenomenon can be prevented. Further, the possible dangerous 
tight engagement between the main grooves and the rain grooves during 
running is avoided. Accordingly, as the resonance mode of the 
above-mentioned tube is altered as the tire rotates, the occurence of the 
air resonance is decreased which reduces tire running noise.

DETAILED DESCRIPTION OF THE INVENTION 
In the figures, the pneumatic tire 1 according to the present invention is 
a passenger car tire having a low aspect ratio (tire section height H/tire 
maximum width WT) of not more than 80%. 
The tire 1 has a tread portion 5, a pair of axially spaced bead portions 3, 
and a pair of sidewall portions 4 extending between the tread edges and 
the bead portions. Further, the tire 1 comprises a pair of bead cores 2 
disposed in each of the bead portions 3, a carcass 6 extending between the 
bead portions through the tread portion 5 and sidewall portions 4 and 
turned up around the bead core 2 from the inside to the outside of the 
tire, and a stiff belt 7 disposed radially outside the carcass 6 and 
inside the tread portion 5. 
The carcass 6 comprises at least one ply of cords arranged radially at an 
angle of from 60 to 90 degrees with respect to the tire equator C to have 
a radial or semi-radial structure. 
For the carcass cords, organic fiber cords, e.g. polyester, nylon, rayon 
and the like and steel cords can be used. 
The belt 7 comprises at least one ply, in this embodiment two plies 7A and 
7B, of cords laid at an angle of from not more than 30 degrees with 
respect to the tire equator C. 
The cords in the radially inner ply 7A cross the cords in the radially 
outer ply 7B. 
For the belt cords, metal cords such as steel and organic fiber cords, e.g. 
nylon, polyester, rayon and the like can be used. 
The above-mentioned tread portion 5 is provided with tread grooves defining 
a block pattern or block/rib pattern. The tread grooves include main 
grooves 10 extending in the circumferential direction of the tire and 
lateral grooves 11 extending in the tire width direction and intersecting 
the main grooves 10. Here, a rib is a circumferentially continuous tread 
element, and therefore, a block-rib pattern consists of at least one 
circumferentially continuous element and a plurality of circumferentially 
discontinuous elements, and a block pattern consists of only a plurality 
of circumferentially discontinuous elements. 
As shown in FIG. 2, in this embodiment, the main grooves 10 are straight in 
the circumferential direction of the tire. The main grooves 10 include a 
pair of axially inner main grooves 10A and 10A each disposed on each side 
of the tire equator C, and a pair of axially outer main grooves 10B and 
10B each disposed axially outside of each of the inner main grooves 10A. 
Each of the main grooves 10A and 10B has, at the tread face K, a width GW 
of not less than 3% of the tread width TW and not less than 5 mm, and the 
groove depth D is substantially constant along its entire length. 
The lateral grooves 11 in this embodiment include lateral grooves 11A 
extending axially Inwardly from one of the tread edges eA and terminating 
near the tire equator C, and lateral grooves lib extending axially 
inwardly from the other tread edge 11B and terminating near the tire 
equator C. The lateral grooves 11A are disposed within a half K1 of the 
tread face K, for example on the left side of the tire equator C, and the 
lateral grooves 11B are disposed within a right half K2 of the tread face 
K. Therefore, the axially inner ends of all the lateral grooves 11A and 
11B are positioned before the tire equator C. However, it may be possible 
that the axially inner ends extend over the tire equator C, while being 
positioned near the tire equator C. 
By the provision of the tread grooves, the tread face K is provided with a 
tread pattern such that the right half K2 is same as the left half K1 or 
alternatively the right half K2 is different from the left half K1. Here, 
the "different" means asymmetrical patterns in which the circumferential 
pitches of the lateral grooves, the sequence of the pitches and/or the 
configurations of the lateral grooves are differed. Accordingly, the 
"same" means patterns other than the above-explained asymmetrical 
patterns, including a so called symmetrical pattern. 
In this embodiment, as shown in FIG. 2, In the ground contacting width TW, 
all the lateral grooves are inclined to the same direction, and as a 
result, the tread portion is provided with a symmetrical tread pattern in 
which the phase of the right half K2 is clrcumferentially shifted from 
that of the left half K1. (This type of pattern is called a "symmetrical" 
pattern.) 
Therefore, using one half (left tread half K1) for convenience sake, the 
tread pattern will now be explained in conjunction with FIG. 3. 
The lateral grooves 11A extend across the inner main groove 10A, defining a 
plurality of groove parts EA between the intersections JA and JA of the 
lateral grooves 11A with the inner main groove 10A. 
Also, the lateral grooves 11A extend across the outer main groove 10B, 
defining a plurality of groove parts EB between the intersections JB and 
JB of the lateral grooves 11A with the outer main groove 10B. 
The lengths of the groove parts EA which correspond to the circumferential 
pitches PA between the intersections JA and JA include a plurality of 
different lengths, and also the lengths of the groove parts EB which 
correspond to the circumferential pitches PB between the intersections JB 
and JB include a plurality of different lengths. 
The lateral grooves 11A extend continuously and substantially parallel with 
each other, whereby in this embodiment the above-mentioned pitches PA are 
same as the pitches PB in respect to the number (n) of the different 
lengths and the sequence of the pitch arrangement. 
Hereinafter, the pitches PA and PB, the intersections JA and JB, and the 
groove parts EA and EB are called generically pitches P, intersections J, 
and groove parts E, respectively. 
Further, the following definitions are made: the number of the different 
pitches is (n); the different pitches are P(i) (i=1 to n); P(j)&lt;P(J+1) 
(j=1 to n-1), i.e., P(1)&lt;P(2)&lt;. . . &lt;P(n); and in ascending order, the 
pitch P(i) of which order (i) is in the range of from n/2 to (n+2)/2 
belongs to middle pitch group RM, the pitch of a lower order belongs to 
short pitch group RS, and the pitch of a higher order belongs to long 
pitch group RL. 
In this embodiment, the number (n) of the different pitches P(i) (i=1 to 5) 
is five. 
EQU P(1)&lt;P(2)&lt;P(3)&lt;P(4)&lt;P(5) 
In this case, the middle pitch group RM consists of only the third pitch 
P(3). The short pitch group RS consists of pitches P(1) and P(2). The long 
pitch group RL consists of pitches P(4) and P(5). 
For example, when n=6, the middle pitch group RM consists of pitches P(3) 
and P(4). When n=7, RM consists of P(4). When n=4, RM consists of P(2) and 
P(3). When n=3, RM consists of P(2). 
The cross sectional shapes of all the groove parts E(i) corresponding to 
the pitches P(i) belonging to the short pitch group RS are defined by a 
first shape 21. 
The cross sectional shapes of all the groove parts E(i) corresponding to 
the pitches P(i) belonging to the long pitch group RL are defined by a 
second shape 22 and/or a third shape 23. 
The cross sectional shapes of all the groove parts E(i) corresponding to 
the pitches P(i) belonging to the middle pitch group RM are defined by the 
first shape 21, second shape 22 and/or third shape 23. 
Preferably, in the long pitch group RL, only the third shape 23 is used. 
And in the middle pitch group RM, only the second shape 22 is used. 
In a meridian section including the tire axis, as shown in FIG. 4, the 
first shape 21 consists of a groove bottom 21a and a pair of groove 
sidewalls 21b and 21c, and each groove sidewall 21b, 21c extends straight 
from each edge of the groove bottom 21a to the tread face, increasing the 
width therebetween. The groove bottom 21a in this embodiment is a flat 
plane substantially parallel with the tread face K. The angle (alpha) 
between each of the groove sidewalls 21b and 21c and the tread face K is 
in the range of from 95 to 105 degrees. 
As shown in FIG. 5, the second shape 22 consists of a groove bottom 22a, 
and a pair of groove sidewalls 22b and 22c. The groove bottom 22a is a 
flat plane substantially parallel with the tread face K. The groove 
sidewall 22c extends straight from one edge of the groove bottom 22a to 
the tread face, inclining in the same manner as the above-mentioned first 
shape 21. The groove sidewall 22b consists of a convexly curved main 
portion 22b1 and a concavely curved lower portion 22b2. The main portion 
22b1 extends from the tread face K to near the groove bottom 22a. The 
lower portion 22b2 extends from the radially inner end of the main portion 
22b1 to the other edge of the groove bottom 22a. 
As shown in FIG. 6, the third shape 23 consists of a groove bottom 23a, and 
a pair of groove sidewalls 23b and 23c. The groove bottom 23a is a flat 
plane substantially parallel with the tread face K. Each of the groove 
sidewalls 23b and 23c consists of a convexly curved main portion 23b1 and 
23c1 and a concavely curved lower portion 23b2 and 23c2. The main portion 
23b1, 23c1 extends from the tread face K to near the groove bottom 23a. 
The lower portion 23b2, 23c2 extends from the radially inner end of the 
main portion 23b1, 23c1 to the other edge of the groove bottom 23a. 
Further, at the tread face K, the groove widths GW2 and GW3 of the second 
and third shapes 22 and 23 are in the range of from 1.05 to 2.5 times the 
groove width GW1 of the first shape 21. In a main groove, the following 
relationship: GW1&lt;GW2&lt;GW3 is satisfied. The radius of curvature R of each 
of the above-mentioned groove sidewall 22b1, 23b1 and 23c1 is preferably 
in the range of from 0.5 to 1.5 times the groove depth D. If the radius of 
curvature R is less than 0.5 D, the ground contacting area is decreased to 
decrease the wet grip performance and wear durability. If the radius of 
curvature R is more than 1.5 D, the prevention of wandering performance 
becomes insufficient, and the noise reducing effect is decreased. 
Preferably, the above-mentioned convexly curved sidewall main portions 
22b1, 23b1 and 23c1 intersect the tread face K, with forming an obtuse 
angle at the intersection. However, it may be possible to connect the 
sidewall to the tread face smoothly without forming any angle. 
The convexly curved main portions 22b1, 23b1 and 23c1 are connected to the 
concavely curved lower portions 22b2, 23b2 and 23c2 smoothly without 
forming any angle. 
Further, the groove bottoms 21a, 22a and 23a may be curved. 
In this embodiment, the first shape 21 and third shape 23 are substantially 
geometrically symmetric about the groove center line. However, the first 
shape 21 and/or third shape 23 can be asymmetric. 
In a lateral groove 11A, a groove segment 11A1 between the main grooves 10B 
and the tread edge eA, a groove segment 11A2 between the main grooves 10B 
and 10A, and a groove segment 11A3 axially inside of the main grooves 10A 
are usually aligned, However, they can be circumferentially shifted if the 
shift L is less than 2 times the width YW of the lateral grooves 11A. In 
FIG. 3, between the segments 11A1 and 11A2, a shift L1 substantially equal 
to the width YW exists. 
As described above, in the present Invention, the pneumatic tire has main 
grooves, each made up of parts having different widths and different 
sectional shapes. Therefore, the wandering phenomenon due to the rain 
grooves on the road surface can be prevented, and the tire running noise 
due to the air resonance in the main groove can be reduced.