JP2020114740A - tire - Google Patents

Abstract

To provide a tire that can obtain a satisfactory silencing effect, and secure rigidity of a land part to keep steering stability excellent.SOLUTION: A silencing groove, provided with a narrowing part, whose one end opens to a shoulder groove and whose other end terminates in a land part 15 and an air chamber having a cross sectional area larger than the narrowing part communicated with the narrowing part, is formed in the land part 15. The air chamber is constituted of a slit part 223a and a hollow part 223b with a cross sectional area larger than a cross sectional area of the slit part 223a, provided inside in a tire radial direction of the slit part 223a and communicated with the slit part 223a. The hollow part 223b is formed only at the shoulder groove side of the slit part 223a, at an end at a kicking-out side of the tire, and is formed so that a volume at the shoulder groove side of the slit part 223a is the same as a volume at the other side of the shoulder groove side, at an end at a stepping-side of the tire.SELECTED DRAWING: Figure 3

Description

The present invention relates to a tire capable of reducing pattern noise.

Conventionally, a slit extending in the tire width direction is provided in a land portion partitioned by a circumferential groove, and a hollow portion is provided inside the slit in the tire radial direction to prevent increase of uneven wear and deterioration of pattern noise. Technology is known (for example, refer to Patent Document 1).

JP, 2003-159911, A

However, in the tire of Patent Document 1 described above, not only is the hollow portion penetrating the two circumferential grooves that partition the land portion, but the cross-sectional area on the circumferential groove side and the cross-sectional area on the center side of the land portion are equal. Therefore, there is a problem in that a sufficient noise reduction effect cannot be obtained, and as a result, pattern noise cannot be effectively reduced.

The present invention has been made in view of the problems of the related art, and provides a tire that can obtain a sufficient silencing effect, and that can secure the rigidity of the land portion and maintain good steering stability. With the goal.

The present invention is a tire comprising a plurality of circumferential grooves formed on the surface of a tread so as to extend along the tire circumferential direction, and a plurality of land portions partitioned by the circumferential grooves, Of the land portions, when the land portion divided by two adjacent circumferential grooves is referred to as an inner land portion, at least one inner land portion has one end of one of the two circumferential grooves. Muffler having a narrowed portion that opens to the circumferential groove and the other end of which terminates in the land portion, and an air chamber portion that communicates with the circumferential groove through the narrowed portion and has a larger cross-sectional area than the narrowed portion. A groove is formed, and the air chamber portion has a slit portion having one end communicating with the other end of the narrowed portion and the other end terminating in the land portion, and the slit provided on the tire radial direction inner side of the slit portion. A hollow portion having a cross-sectional area larger than the cross-sectional area of the slit portion, the one circumferential groove partitioning the inner land portion is a shoulder groove, and the air chamber portion and the narrowed portion. The extension direction is a direction that intersects both the tire circumferential direction and the tire width direction, and the air chamber portion is inclined so as to approach the shoulder groove as going from the kicking side to the stepping side of the tire. The hollow portion of the air chamber portion is formed only on the shoulder groove side of the slit portion at the end portion on the kicking side of the tire, and at the end portion on the stepping side of the tire, at the slit portion. It is characterized in that the volume on the shoulder groove side and the volume on the side opposite to the shoulder groove side are the same.

In this way, in the land portion partitioned by the two circumferential grooves, a narrowed portion (narrowed neck) that acts as a Helmholtz type resonator and has one end opening to the circumferential groove and communicates with this narrowed portion. Since the sound deadening groove provided with the air chamber (resonance chamber) having a large cross-sectional area is formed, the pattern noise (air column resonance sound) caused by the circumferential groove can be significantly reduced.
Further, since the air chamber portion that reduces the rigidity of the land portion is composed of the slit portion having a narrow groove width and the hollow portion having a larger cross-sectional area than the slit portion, it is possible to secure the rigidity and reduce the pattern noise.
In addition, even if a large force acts on the tread during braking or cornering, the slit part closes and the land parts partitioned by the slit part (hereinafter referred to as blocks) come into contact with each other to support each other. Therefore, the steering stability can be kept good.

Further, one circumferential groove that defines the inner land portion is a shoulder groove, the extension directions of the air chamber portion and the narrowed portion are both in a direction that intersects the tire circumferential direction and the tire width direction, and The air chamber part is inclined so as to approach the shoulder groove as it goes from the kicking side of the tire to the stepping side, and the hollow part of the air chamber part is at the kicking side end of the tire. , Is formed only on the shoulder groove side of the slit portion, and at the stepping side end of the tire, the volume of the slit portion on the shoulder groove side and the volume on the opposite side of the shoulder groove side are the same. You may form so. When the one circumferential groove that defines the inner land portion is a shoulder groove, the extending directions of the air chamber portion and the narrowed portion are both in a direction that intersects the tire circumferential direction and the tire width direction. And, the air chamber part is inclined so as to approach the shoulder groove as going from the kick-out side of the tire to the step-in side, and the hollow part of the air chamber part is an end part on the kick-out side of the tire. Then, it is formed only on the shoulder groove side of the slit portion, and at the stepping side end of the tire, the volume of the slit portion on the shoulder groove side and the volume on the opposite side of the shoulder groove side are the same. You may form so.

The above summary of the invention does not enumerate all the necessary features of the present invention, and sub-combinations of these feature groups can also be the invention.

It is a figure which shows the tread pattern of the tire which concerns on this Embodiment. It is sectional drawing of a 1st sound deadening groove. It is sectional drawing of a 2nd sound deadening groove. It is a figure which shows the other form of a sound deadening groove. It is a figure which shows the other example of the tread pattern of the tire by this invention. It is a figure which shows the other example of the tread pattern of the tire by this invention.

Embodiments of the present invention will be described below with reference to the drawings.
FIG. 1 is a diagram showing an example of a tread pattern of a tire 10 according to the present embodiment. The direction from the lower side to the upper side in the figure is the tire rotation direction, the lower side in the figure is the kicking side, and the upper side is the stepping side. Further, the left-right direction in the figure is the tire width direction, TG is the tread ground contact end, and the tread tread portion is between the TGs.
In the figure, 11 is a center groove, 12 and 13 are left and right shoulder grooves, 14 is a first inner land portion, 15 is a second inner land portion, and 16 and 17 are left and right shoulder land portions. A first sound deadening groove 21 is formed on the surface side of the inner land portion 14, and a second sound deadening groove 22 is formed on the surface side of the second inner land portion 15. Further, reference numeral 18 is a sipe formed on the front surface side of the left and right shoulder land portions 16 and 17, respectively, and extending in a direction intersecting with the tire circumferential direction. It should be noted that a fine groove or a lug groove may be provided instead of the sipe 18.
The center groove 11 and the shoulder grooves 12 and 13 are circumferential grooves that continuously extend along the tire circumferential direction, and the first inner land portion 14 is defined by the left shoulder groove 12 and the center groove 11. The second inner land portion 15 is defined by the center groove 11 and the right shoulder groove 13.

The sound deadening groove 21 has one end opening to the left shoulder groove 12 and the other end terminating in the first inner land portion 14 in the form of a slit-shaped outer narrowing portion 211, and one end opening to the center groove 11 and the other end. Communicates with the left side shoulder groove 12 via the slit-shaped inner narrowing portion 212 and the outer narrowing portion 211, and communicates with the center groove 11 via the inner narrowing portion 212. And an air chamber portion 213 having a cross-sectional area larger than the cross-sectional areas of the outer narrowed portion 211 and the inner narrowed portion 212.
The outer narrowed portion 211 is formed so as to extend in a direction intersecting the tire radial direction and the tire circumferential direction with the opening side being on the kicking side and the terminal side being on the stepping side, and the inner narrowed portion 212 is stepped on the opening side. And is formed so as to extend in a direction that intersects the tire radial direction and the tire circumferential direction, the end side being on the kicking side. Note that either one or both of the outer narrowed portion 211 and the inner narrowed portion 212 may be extended in the tire width direction.
On the other hand, the air chamber portion 213 is formed so as to extend in a direction parallel to the tire circumferential direction.
2(a) and 2(c) are cross-sectional views of the outer narrowed portion 211 and the inner narrowed portion 212 taken along a plane orthogonal to the extension direction thereof, respectively, showing the outer narrowed portion 211 and the inner narrowed portion, respectively. When the groove width of 212 is W0 and the groove depth is H0, W0 and H0 are in the ranges of 0.1 mm≦W0≦3 mm and 0.5 mm≦H0≦8 mm, respectively. The groove width and groove depth of the outer narrowed portion 211 may be different from the groove width and groove depth of the inner narrowed portion 212.
2B is a cross-sectional view of the air chamber portion 213 taken along a plane orthogonal to its extension direction. The air chamber portion 213 includes a slit portion 213a and a hollow portion 213b. The area and volume of the groove are larger than the cross-sectional area and volume of the outer narrowed portion 211 and the inner narrowed portion 212.
The slit portion 213a is a narrow groove extending in a direction parallel to the tire circumferential direction and having a groove width W1 of 0.2 mm≦W1≦3.0 mm and a groove depth H1 of 0.5 mm≦H1≦2 mm. , Both ends communicate with the outer and inner narrowed portions 211 and 212, respectively. The size of the groove width W1 of the slit portion 213a is preferably equal to or larger than the groove width W0 of the outer narrowed portion 211 and the inner narrowed portion 212.
The hollow portion 213b is a groove portion that is provided inside the slit portion 213a in the tire radial direction and communicates with the slit portion 213a, and has a cross-sectional area larger than the cross-sectional area of the slit portion 213a. It extends in a direction parallel to the direction.
As for the cross-sectional shape of the hollow portion 213b, it is preferable that the groove width becomes narrower as it approaches the slit portion 213a, as shown in FIG. 2(b). In this way, if the slit portion 213a and the hollow portion 213b are connected by the inclined surface portion 213k, the rigidity of the block (land portion divided in the tire circumferential direction by the sound deadening groove 21) is secured while ensuring the volume of the hollow portion 213b. Since it can be ensured, the steering stability can be improved without reducing the muffling effect.
In this example, as shown in FIG. 1, since the outer narrowed portion 211 and the air chamber portion 213 are communicated with each other at the end portion of the outer narrowed portion 211, the outer narrowed portion 211 has a circumferential groove (shoulder groove 12). The entire groove from the opening to the end (the opening to the air chamber 213) can be made to act as a constriction neck. Further, since the inner narrowed portion 212 also communicates with the air chamber portion 213 at the end portion of the inner narrowed portion 211, the inner narrowed portion 212 also has a narrow neck from the opening of the circumferential groove (center groove 11) to the end portion. Acts as.
Note that the narrowed portions 211 and 212 and the air chamber portion 213 may be communicated with each other before the end portions of the narrowed portions 211 and 212, but since the block rigidity decreases, as in this example, they communicate with each other. It is preferable that the narrowed portions 211 and 212 and the air chamber portion 213 communicate with each other at their respective end portions.

In the sound deadening groove 21 of this example, the groove width W2 on the groove bottom side of the hollow portion 213b is set to 3 to 16 times the groove width W1 of the slit portion 213a, and the groove depth H2 is set to 4 to 4 times the groove depth H1 of the slit portion 213a. 8 times.
As a result, the air chamber portion 213 serving as the resonance chamber has a volume much larger than the volume of the outer narrowed portion 211 (or the inner narrowed portion 212) serving as the narrowed neck, so that the silencing groove 21 serves as a Helmholtz resonator. To work. Therefore, the pattern noise (air column resonance sound) caused by the circumferential groove (here, the center groove 11 and the left shoulder groove 12) can be significantly reduced.
When the groove depth H2 of the hollow portion 213b exceeds eight times the groove depth H1 of the slit portion 213a, the blocks (land portions partitioned in the tire circumferential direction by the sound deadening groove 21) are sufficiently contacted to each other and supported. Since it is not possible to meet each other, the steering stability may be reduced. On the contrary, if the groove depth H2 of the hollow portion 213b is less than 4 times the groove depth H1 of the slit portion 213a, the volume of the air chamber portion 213 cannot be sufficiently secured, and the muffling effect is reduced.
Further, when the groove width W2 of the hollow portion 213b exceeds 16 times the groove width H1 of the slit portion 213a, the sound deadening effect is improved, but the rigidity of the tread is lowered, and the steering stability may be lowered. On the contrary, if the groove width W2 of the hollow portion 213b is less than three times the groove width W1 of the slit portion 213a, the volume of the air chamber portion 213 cannot be sufficiently secured, and the silencing effect is deteriorated.
Therefore, in order to secure both steering stability and noise reduction effect, the groove width W2 of the hollow portion 213b is set to 3 to 16 times the groove width W1 of the slit portion 213a, and the groove depth H2 is set to the groove depth of the slit portion 213a. It is preferably 4 to 8 times H1.

Further, in the sound deadening groove 21 of this example, the volume of the hollow portion 213b is reduced without reducing the pattern rigidity by making the extension direction of the slit portion 213a (the extension direction of the air chamber portion 213) parallel to the tire circumferential direction. I am able to secure it.
The angle formed by the extension direction of the slit portion 213a and the tire width direction (hereinafter referred to as the inclination angle θ) is 50°≦θ≦130° (θ=0° is the tire width direction and θ=90°. (In the tire circumferential direction). That is, when the inclination angle θ is less than 50° and exceeds 130°, the total length of the hollow portion 213b is shortened, and as a result, the volume of the air chamber portion 213 is reduced, so that a sufficient silencing effect is secured. It may not be possible. If the groove width W2 of the hollow portion 213b is increased, the volume of the air chamber portion 213 increases, but the pattern rigidity decreases, which is not preferable.
On the other hand, if the inclination angle θ is set to 50° or more and 130° or less, the entire length of the hollow portion 213b can be lengthened without widening the groove width W2, so that a sufficient silencing effect can be obtained without reducing the pattern rigidity. You can

Similarly to the sound deadening groove 21, the sound deadening groove 22 has a slit-shaped outer end that opens at one end into the shoulder groove (the right shoulder groove 13) and ends at the other end inside the inner land portion (second inner land portion 15). A narrowed portion 221, a slit-shaped inner narrowed portion 222 having one end opening in the center groove 11 and the other end terminating in the inner land portion 15, and the inner narrowed portion communicating with the shoulder groove 12 via the outer narrowed portion 221. An air chamber portion 223, which communicates with the center groove 11 via the portion 222, has a large cross-sectional area of the inner and outer narrowed portions 221 and 222.
The sound deadening groove 22 may have the same structure as the sound deadening groove 21 or a structure symmetrical with the sound deadening groove 21, but in this example, as shown in FIG. 1, the outer narrowed portion 221 is moved from the kicking side to the stepping side. The inner narrowing portion 222 is formed so as to extend in a direction that extends in a direction that intersects the tire circumferential direction and that extends in a direction that extends from the stepping side to the kicking side and that intersects the tire circumferential direction. did. Further, the extension direction of the air chamber portion 223 is made to intersect the tire circumferential direction and the tire width direction (inclination angle θ≈70°), and the cross-sectional shape of the hollow portion 223b forming the air chamber portion 223 is taken from the kicking side. It is configured to change toward the stepping side.
Specifically, as shown in FIG. 3A, the hollow portion 223b is formed only on the right side shoulder groove 13 side at the end on the kicking side, and at the center of the land portion width direction, as shown in FIG. As shown in FIG. 5, the volume on the right side shoulder groove 13 side is reduced and the volume on the center groove 11 side is increased. In addition, as shown in FIG. 3C, the hollow portion 223b is formed at the end portion on the stepping side such that the volume on the right shoulder groove 13 side and the volume on the center groove 11 side are the same.
It should be noted that the preferable range of the groove width and the groove depth of the outer narrowed portion 221 and the inner narrowed portion 222 is the same as the preferable range of the groove width W0 and the groove depth H0 of the sound deadening groove 21 described above.
Further, a suitable range of the groove width and the groove depth of the slit portion 223a of the air chamber portion 223, the relationship between the groove width of the hollow portion 223b on the groove bottom side and the groove width of the slit portion 223a, and the groove of the hollow portion 223b. The relationship between the depth and the groove depth of the slit portion 223a is preferably the same as that of the sound deadening groove 21.
As a result, both the noise reduction effect and the steering stability can be improved.

[Example]
The present invention will be described based on examples.
A tire according to the present invention (Examples 1 to 5) shown in FIG. 1 in which a sound deadening groove having a narrowed portion and an air chamber portion is provided in the inner land portion, and a tire not having the sound deadening groove (comparative example). Table 1 below shows the results of evaluation of the noise performance and steering stability of each tire prepared.
In the tire of Example 1, the ratio (H2/H1) of the groove depth H2 of the hollow portion to the groove depth H1 of the slit was 6, and the ratio of the groove width W2 on the groove bottom side of the hollow portion to the groove width W1 of the slit. The tire has a (W2/W1) of 10.
The tire of Example 2 has H2/H1 of 4, and W2/W1 is the same as that of Example 1.
The tire of Example 3 has H2/H1 of 8, and W2/W1 is the same as that of Example 1.
In the tire of Example 4, H2/H1 is the same as that of Example 1, and H2/H1 is 3.
In the tire of Example 5, H2/H1 is the same as that of Example 1, and H2/H1 is 16.
The tire size of each tire is 195/65R15 and the internal pressure is 220 kPa.
Noise performance is measured by rotating the tire on a drum with a diameter of 1.7 m, installing a microphone near the contact surface of the tire, raising the drum to the measurement start speed, and then coasting the tire to make the sound pressure level of noise. Was measured.
The sound pressure level was measured at four speeds with a measurement start speed of 40, 60, 80, and 100 km/h, and the average value was used as a representative value. The evaluation result was an index with Comparative Example being 100. The larger the number, the better the noise performance.
In addition, the steering stability was evaluated by a sensory test performed by a driver when a new tire was mounted on a test vehicle and running on a dry road surface. In addition, the evaluation result is an index with the comparative example being 100. The larger the number, the better the steering stability.

As shown in Table 1, all the tires of Examples 1 to 5 provided with the sound deadening groove can improve both noise performance and steering stability as compared with the tire of the comparative example having no sound deadening groove. Was confirmed.
In addition, comparing Example 1 with Examples 2 and 3, when H2/H1 is decreased, steering stability is improved, but noise performance tends to decrease. Conversely, when H2/H1 is increased, noise performance is increased. It is understood that the steering stability tends to decrease, though the steering stability is improved.
Therefore, when the ratio of the groove depth H2 of the hollow portion to the groove depth H1 of the slit becomes small, the volume of the air chamber cannot be sufficiently secured, so that the sound deadening effect decreases and the groove depth of the hollow portion with respect to the groove depth H1 of the slit decreases. It was confirmed that when the ratio of the depth H2 increases, the block rigidity decreases and the steering stability decreases.
In addition, comparing Example 1 with Examples 4 and 5, when W2/W1 is decreased, steering stability is improved, but noise performance tends to decrease. Conversely, when W2/W1 is increased, noise performance is increased. It is understood that the steering stability tends to decrease, though the steering stability is improved.
Therefore, when the ratio of the groove width W2 of the hollow portion to the groove width W1 of the slit becomes small, the volume of the air chamber cannot be sufficiently secured, so that the silencing effect is reduced and the groove width 2 of the hollow portion with respect to the groove width W1 of the slit is reduced. It was confirmed that as the ratio increased, the block rigidity decreased and the steering stability decreased.

Although the present invention has been described above using the embodiments and examples, the technical scope of the present invention is not limited to the scope described in the above embodiments. It is apparent to those skilled in the art that various modifications and improvements can be added to the above-described embodiment. It is apparent from the scope of the claims that the embodiments added with such changes or improvements can be included in the technical scope of the present invention.

For example, in the above-described embodiment, the case where the sound deadening groove 21 having the outer narrowed portion 211 and the inner narrowed portion 212 is formed in the inner land portion 14 has been described, but as shown in FIG. The sound deadening groove 21A having only the inner narrowed portion 212 or the sound deadening groove 22A having only the inner narrowed portion 222 may be formed. Further, the sound deadening groove 21B having only the outer narrowed portion 211 (or the outer narrowed portion 221) may be formed.
Also in this case, as in the above-described embodiment, the inner constriction portion 212 (or the inner constriction portion 222) and the air chamber portion 213 are separated from the inner constriction portion 212 (or the inner constriction portion 222) by the air chamber. It is preferable to communicate with the part 213 (or the air chamber part 223).
Alternatively, as shown in FIG. 4B, a narrow portion 212 having one end opening to one circumferential groove (center groove 11) and the narrow portion 212 are formed in one land portion (for example, the inner land portion 14). The sound absorbing groove 21A including an air chamber portion 213 having a large cross-sectional area that communicates with the one circumferential groove via the narrow groove portion 211 having one end opening to the other circumferential groove (the left shoulder groove 12) and the narrow portion. Even if the sound deadening groove 21B including the air chamber portion 213 having a large cross-sectional area and communicating with the other circumferential groove via the portion 211 is provided, both the sound deadening effect and the steering stability can be improved.
Further, in the above embodiment, the cross-sectional shape of the hollow portion 213b is a polygon whose bottom side is rectangular and whose side communicating with the slit portion 213a is narrower as the groove width is closer to the slit portion 213a. The portion and the groove bottom may be arcuate. Also in this case, the block rigidity can be secured by narrowing the width of the hollow portion 213b as it becomes closer to the slit portion 213a, so that both the silencing effect and the steering stability can be improved.

Further, in the above-described embodiment, the tire 10 having the tread pattern having three circumferential grooves has been described, but as shown in FIGS. 5 and 6, the circumferential grooves may be four or more. Also, it is not necessary to provide muffling grooves on all the inner land portions.
The tire 10A shown in FIG. 5 includes two center grooves 31 and 32, left and right shoulder grooves 12 and 13, three inner land portions 33 to 35, and left and right shoulder land portions 16 and 17. On the surface side of the inner land portion 33 on the left side in the tire width direction, a sound deadening groove 36 having an outer narrowed portion 361, an inner narrowed portion 362 and an air chamber portion 363 is formed, and the surface side of the inner land portion 35 on the right side. The sound absorbing groove 37 including the outer narrowed portion 371, the inner narrowed portion 372, and the air chamber portion 373 is formed therein. Further, a sipe 38 and a narrow groove 39 are formed on the surface side of the central inner land portion 34.
Since the muffling groove 36 has the same structure as the first muffling groove 21 of the above-mentioned embodiment, its description is omitted.
In the sound deadening groove 37, the hollow portion 373b forming the air chamber portion 373 has the same volume on the stepping side on the right shoulder groove 12 side and the volume on the center groove 11 side, and on the kicking side, the right center portion. It was formed only on the groove 32 side.
Even if the muffling groove 37 is configured as described above, both the muffling effect and the steering stability can be improved.
Further, the tire 10B shown in FIG. 6 includes two center grooves 41 and 42, left and right shoulder grooves 12 and 13, three inner land portions 43 to 45, and left and right shoulder land portions 6 and 17. , A muffling groove 46 on the surface side of the inner land portion 43 on the left side in the tire width direction, a muffling groove 47 on the surface side of the inner land portion 45 on the right side, and a sipe 48 on the surface side of the inner land portion 44 in the center. , Respectively.
In the sound deadening groove 46, the hollow portion 463b forming the air chamber portion 463 is formed only on the left side shoulder groove 12 side on the stepping side, and on the left side center groove 41 side on the kicking side.
Further, in the sound deadening groove 47, the cross-sectional shape of the hollow portion 473b forming the air chamber portion 473 is formed only on the left side of the shoulder groove 13 on both the stepping side and the kicking side.
As described above, even if the sound deadening groove is configured as described above, both the sound deadening effect and the steering stability can be improved as in the first sound deadening groove 21 of the embodiment.

10 tires, 11 center groove, 12, 13 shoulder groove,
14 first inner land portion, 15 second inner land portion, 16, 17 shoulder land portion,
18 sipe, 21 first silencing groove, 211, 221 outer constriction,
212, 222 inner narrowing portion, 213, 223 air chamber portion, 213a slit portion,
213b Hollow part, TG tread ground end.

Claims (2)

A tire having a plurality of circumferential grooves formed so as to extend along the tire circumferential direction on the surface of the tread, and a plurality of land portions defined by the circumferential grooves,
Of the land portions, when the land portion divided by two adjacent circumferential grooves is the inner land portion,
At least one inland area
A narrowed portion, one end of which opens to one circumferential groove of the two circumferential grooves and the other end of which terminates in the land portion, and the narrowed portion which communicates with the circumferential groove through the narrowed portion. A sound deadening groove with an air chamber part having a larger cross-sectional area than is formed,
The air chamber is
A slit portion, one end of which communicates with the other end of the narrowed portion and the other end of which terminates in the land portion,
A hollow portion provided on the inner side in the tire radial direction of the slit portion and communicating with the slit portion, and having a hollow portion having a cross-sectional area larger than the cross-sectional area of the slit portion,
One circumferential groove that defines the inner land portion is a shoulder groove,
The extending directions of the air chamber portion and the narrowed portion are both directions intersecting the tire circumferential direction and the tire width direction, and the air chamber portion goes from the kicking side of the tire to the stepping side. It is inclined so that it approaches the shoulder groove,
The hollow part of the air chamber part,
At the kick-out side end of the tire, it is formed only on the shoulder groove side of the slit portion,
The tire is characterized in that an end portion on the stepping side of the tire is formed such that a volume of the slit portion on the shoulder groove side is the same as a volume of the slit portion on a side opposite to the shoulder groove side. A tire having a plurality of circumferential grooves formed so as to extend along the tire circumferential direction on the surface of the tread, and a plurality of land portions defined by the circumferential grooves,
Of the land portions, when the land portion divided by two adjacent circumferential grooves is the inner land portion,
At least one inland area
A narrowed portion, one end of which opens to one circumferential groove of the two circumferential grooves and the other end of which terminates in the land portion, and the narrowed portion which communicates with the circumferential groove through the narrowed portion. A sound deadening groove with an air chamber part having a larger cross-sectional area than is formed,
The air chamber is
A slit portion, one end of which communicates with the other end of the narrowed portion and the other end of which terminates in the land portion,
A hollow portion provided on the inner side in the tire radial direction of the slit portion and communicating with the slit portion, and having a hollow portion having a cross-sectional area larger than the cross-sectional area of the slit portion,
One circumferential groove that defines the inner land portion is a shoulder groove,
The extension direction of the air chamber portion is a direction intersecting the tire circumferential direction and the tire width direction, and the air chamber portion is closer to the shoulder groove as it goes from the kicking side to the stepping side of the tire. Is inclined,
The narrowed portion is inclined so as to extend in a direction opposite to the extending direction of the air chamber portion,
The hollow part of the air chamber part,
At the kick-out side end of the tire, it is formed only on the shoulder groove side of the slit portion,
A tire characterized in that only the side opposite to the shoulder groove side of the slit portion is formed at an end portion on the stepping side of the tire.