Patent Description:
In recent years, with an increasing demand for fuel efficiency of tires, attempts have been made to reduce the rolling resistance of a tire by applying a low-loss rubber composition to the tire. From the standpoint of reducing the rolling resistance of a tire, it is advantageous to apply a low-loss rubber composition to various case members constituting the tire, in addition to a low-loss tread rubber.

Meanwhile, conventionally, as a means for releasing the electricity generated from a vehicle body to the outside, a method of allowing the electricity to escape into the ground via a tire is generally employed. However, further promoting the low loss of a rubber composition used in the tire causes an increase in the electrical resistance of the tire and the electricity is thus not released adequately, which results in, for example, radio noise and generation of static electricity at the time of opening or closing a door of a vehicle. The electrical resistance of a tire can be reduced by using a high-loss member as a part of a tire member; however, this causes problems, such as deterioration of the rolling resistance of the tire.

In this respect, conventionally, various attempts have been made to reduce the electrical resistance of a tire by arranging a conductive member in the tire. For example, Patent Document <NUM> discloses a tire including a conductive portion continuously extending at least from a bead portion to a belt layer, which conductive portion has a linear structure configured to include a conductive linear body obtained by molding a conductive substance having a prescribed electrical resistivity into a linear shape.

[Patent Document <NUM>] <CIT> (Claims, etc.). Attention is also drawn to the disclosures of <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, WP<CIT> and <CIT>.

<CIT> discloses a pneumatic tire with an electrically conductive path from tread to bead, this tire does not comprise a belt-end cushion rubber between belt and carcass.

However, merely arranging a conductive fiber as in Patent Document <NUM> can secure only a part of a conductive path, which is not satisfactory in terms of reducing the electrical resistance of a tire as a whole while aiming for the further improvement of the low loss of a case member of the tire.

In view of the above, an object of the present invention is to provide a pneumatic tire which solves the above-described problems and in which the electrical resistance of the whole tire can be lowered even when the rolling resistance is further reduced by further improving the low loss of a case member of the tire.

The present inventor intensively studied to discover that the above-described problems can be solved by adopting the below-described constitution, thereby completing the present invention.

That is, the present invention provides a pneumatic tire as claimed in claim <NUM>.

When at least one belt layer is arranged between the carcass and the tread rubber and a belt-end cushion rubber is arranged between the belt layer and the carcass at a tire widthwise end of the belt layer, the conductive member may consist of the conductive fibers and the belt-end cushion rubber. In this case, the conductive fibers are preferably arranged in regions from the tire radial-direction inner end of the conductive rubber portion to the belt-end cushion rubber and from the belt-end cushion rubber to the rubber chafer.

Further, in the present invention, it is preferred that at least two conductive fibers be arranged in the whole tire. Still further, in the present invention, the rubber chafer preferably has a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or lower, a coating rubber of the belt layer preferably has a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or higher, and a coating rubber of the carcass preferably has a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or higher.

According to the present invention, a pneumatic tire in which the electrical resistance of the whole tire can be lowered even when the rolling resistance is further reduced by further improving the low loss of a case member of the tire can be realized.

Embodiments of the present invention will now be described in detail referring to the drawings.

<FIG> is a half widthwise cross-sectional view illustrating one example embodiment of a pneumatic tire of the present invention. The illustrated pneumatic tire includes: a pair of bead portions <NUM>; a pair of side wall portions <NUM>, which continuously extend on a tire radial-direction outer side from the respective bead portions <NUM>; and a tread portion <NUM>, which extends between the pair of the side wall portions <NUM> and forms a ground-contact part. The illustrated tire has, as its skeleton, a carcass <NUM> which is composed of at least one carcass ply (e.g., one to three carcass plies; one carcass ply in the illustrated example) toroidally extending between the pair of the bead portions <NUM>, and includes at least one belt layer <NUM> (e.g., two to four belt layers <NUM>; two belt layers <NUM> in the illustrated example) arranged on the tire radial-direction outer side of the carcass <NUM> in a crown portion. Further, a rubber chafer <NUM> is arranged on a tire width-direction outer surface of each of the bead portions <NUM>. Still further, on the tire radial-direction outer side of the belt layer <NUM>, a cushion rubber 13C and a tread rubber <NUM> constituting a ground-contact surface are sequentially arranged, and a belt-end cushion rubber <NUM> is arranged between the belt layer <NUM> and the carcass <NUM> at a tire widthwise end of the belt layer <NUM>. Yet still further, in the illustrated tire, a conductive rubber portion <NUM>, which penetrates through the tread rubber <NUM> from a ground-contact region of the tire surface toward a tire radial-direction inner side, is arranged. A symbol CL represents the tire equator.

The tire of the present invention includes a conductive member <NUM>, which electrically connects from a tire radial-direction inner end of the conductive rubber portion <NUM> to the rubber chafer <NUM> and has a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or lower, is arranged, and the conductive member <NUM> includes conductive fibers <NUM> at least in the vicinity of the tire radial-direction inner end of the conductive rubber portion <NUM> and the vicinity of the rubber chafer <NUM>. By arranging the conductive member <NUM>, in which the conductive fibers <NUM> are used at least partially, in such a manner that it can provide an electrical conduction from the tire radial-direction inner end of the conductive rubber portion <NUM> to the rubber chafer <NUM>, a conductive path in the tire from the conductive rubber portion <NUM> coming into contact with a road surface to the rubber chafer <NUM> in contact with a rim <NUM> can be certainly secured. Consequently, a conductive path is secured even when the rolling resistance is reduced by achieving the low loss of a rubber composition used in a case member such as the belt layer <NUM> that is conventionally used as a conductive path; therefore, the electrical resistance of the whole tire can be reduced while ensuring low fuel consumption performance. In addition to the belt layer <NUM>, examples of the case member include the carcass <NUM>, the rubber chafer <NUM>, the belt-end cushion rubber <NUM>, a side rubber <NUM>, and a cap layer and a layered layer that are arranged on the tire radial-direction outer side of the belt layer <NUM> at a width covering the belt layer <NUM> (these layers are not illustrated in the drawings).

The conductive member <NUM> according to the present embodiment may be any member as long as it can provide an electrical conduction from the conductive rubber portion <NUM> to the rubber chafer <NUM> and at least parts thereof in the vicinity of the tire radial-direction inner end of the conductive rubber portion <NUM> and the vicinity of the rubber chafer <NUM> are composed of the conductive fibers <NUM>. Specifically, the conductive member <NUM> may consist of a combination of the conductive fibers <NUM> and the belt-end cushion rubber <NUM>. When the belt-end cushion rubber <NUM> is used in the conductive member <NUM>, it is necessary to use a conductive rubber composition as the belt-end cushion rubber <NUM>; therefore, a low loss thereof cannot be achieved.

In the example illustrated in <FIG>, the conductive member <NUM> is constituted by the conductive fibers <NUM> and the belt-end cushion rubber <NUM>, and the conductive fibers <NUM> are arranged in regions from the tire radial-direction inner end of the conductive rubber portion <NUM> to the belt-end cushion rubber <NUM> and from the belt-end cushion rubber <NUM> to the rubber chafer <NUM>. <FIG> is an enlarged partial cross-sectional view illustrating the vicinity of the conductive rubber portion <NUM> illustrated in <FIG>. As illustrated in <FIG>, in this case, the conductive fibers <NUM> are arranged between the belt layer <NUM> and the cushion rubber 13C in the tread portion.

<FIG> illustrate other variations of the arrangement mode of the conductive member according to embodiments of the present invention. <FIG> illustrates an example in which the cushion rubber 13C is not arranged, and the conductive fibers <NUM> are arranged between the belt layer <NUM> and the tread rubber <NUM>. In <FIG>, the conductive fibers <NUM> are arranged between the cushion rubber 13C and the tread rubber <NUM>. <FIG> illustrates an example in which a cap layer <NUM> is arranged on the tire radial-direction outer side of the belt layer <NUM>, and the conductive fibers <NUM> are arranged between the cap layer <NUM> and the cushion rubber 13C. <FIG> illustrates an example in which the cap layer <NUM> is arranged on the tire radial-direction outer side of the belt layer <NUM> with the conductive rubber portion <NUM> penetrating through the cap layer <NUM> and being in contact with the belt layer <NUM>, and the conductive fibers <NUM> are arranged between the cap layer <NUM> and the cushion rubber 13C. <FIG> illustrates an example in which the cap layer <NUM> is arranged on the tire radial-direction outer side of the belt layer <NUM> with the conductive rubber portion <NUM> penetrating through the cap layer <NUM> and being in contact with the belt layer <NUM>, and the conductive fibers <NUM> are arranged between the cushion rubber 13C and the tread rubber <NUM>. <FIG> illustrates an example in which the cap layer <NUM> is arranged on the tire radial-direction outer side of the belt layer <NUM> with the conductive rubber portion <NUM> penetrating through the cap layer <NUM> and being in contact with the belt layer <NUM>, and the conductive fibers <NUM> are arranged between the belt layer <NUM> and the cap layer <NUM>. The cap layer <NUM> is formed by winding a rubber-coated reinforcing cord substantially in the tire circumferential direction; therefore, the conductive rubber portion <NUM> can also be arranged in such a manner to be inserted between the wound reinforcing cords of the cap layer <NUM> as illustrated in <FIG>.

<FIG> is an enlarged partial cross-sectional view illustrating the vicinity of the belt-end cushion rubber <NUM>, corresponding to <FIG>. As illustrated in <FIG>, in this case, the conductive fibers <NUM> are arranged between the belt layer <NUM> and the tread rubber <NUM>. The conductive fibers <NUM> extending from the tire radial-direction inner end of the conductive rubber portion <NUM> and the conductive fibers <NUM> extending from the rubber chafer <NUM> conduct with the belt-end cushion rubber <NUM> arranged at the tire widthwise end of the belt layer <NUM>, whereby a conductive path is secured.

<FIG> is a half widthwise cross-sectional view illustrating an example of a pneumatic tire not according to the present invention, but useful for understanding the present invention. <FIG> is the same as <FIG> except that the conductive member consists of only conductive fibers; therefore, descriptions of common parts are omitted. In the illustrated arrangement mode, since the conductive fibers <NUM> alone can provide an electrical conduction from the conductive rubber portion <NUM> to the rubber chafer <NUM>, the belt-end cushion rubber <NUM> does not have to be arranged, and a low loss can be attained even when the belt-end cushion rubber <NUM> is arranged. The conductive member <NUM> may be arranged on the inner side of the side rubber <NUM> in a region farther on the tire radial-direction inner side than the tire widthwise end of the belt layer <NUM>.

In the present example, the conductive member <NUM> may consist of the conductive fibers <NUM> alone, or a combination of the conductive fibers <NUM> and the belt-end cushion rubber <NUM>. When the conductive member <NUM> consists of only the conductive fibers <NUM>, there is an advantage that a reduction in the weight can be attained. From the standpoint of the degree of freedom in molding, it is also possible to constitute the conductive member <NUM> by joining plural separated members.

The conductive fibers <NUM> may be arranged between the members in the form of fibers as they are, or in the form of an assembly thereof, such as a woven fabric or a knitted fabric. Specifically, at the time of molding, the conductive fibers <NUM> may be arranged by being pasted onto the raw rubber surface of any of the members, or may be arranged between the members in the form of a rubber-coated sheet, and the arrangement conditions are not particularly restricted.

The conductive member <NUM> according to the present invention is required to have a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or lower, preferably <NUM> × <NUM><NUM> Ω·cm or lower, and the lower the volume resistivity, the more preferable. When the volume resistivity of the conductive member <NUM> is higher than <NUM> × <NUM><NUM> Ω·cm, the electrical resistance of the whole tire cannot be reduced sufficiently. In cases where the conductive member <NUM> is constituted by plural members, it is required that the plural members each have a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or lower.

The resistivity of the conductive fibers <NUM> in terms of wire resistivity, which is the resistance per unit length, is preferably <NUM> × <NUM><NUM> Q/cm or lower, more preferably <NUM> × <NUM><NUM> Q/cm or lower, and the lower the resistivity, the more preferable. By controlling the wire resistivity of the conductive fibers <NUM> to be <NUM> × <NUM><NUM> Q/cm or lower, an effect of reducing the electrical resistance of the tire can be favorably obtained.

The conductive fibers <NUM> may have any structure, and different kinds of conductive fibers may be used in combination. Preferably, as the conductive fibers <NUM>, composite fibers, each having a conductive part and a non-conductive part, can be used. Specific examples of the conductive part constituting each conductive fiber <NUM> include a metal-containing fiber, a carbon-containing fiber and a metal oxide-containing fiber, and any one or more thereof can be used. In the present invention, the "metal-containing fiber" refers to a fiber having a metal content of <NUM> to <NUM>% by mass, and examples of the metal and the metal oxide include stainless steel, steel, aluminum, copper, and oxides thereof. Further, examples of the non-conductive part include an organic material, such as cotton, nylon, a polyester (e.g., polyethylene terephthalate (PET)) and a polypropylene (PP), and any one or more thereof can be used. Composite fibers composed of such conductive part and non-conductive part exhibit favorable elongation and have excellent adhesiveness; therefore, they are not broken even when a stress is applied thereto in the tire production process or a strain is input thereto during travel of a vehicle, and can thus be preferably used as the conductive fibers <NUM>.

The mass ratio of the conductive part in each of the conductive fibers <NUM> used in the present invention is not particularly restricted; however, in embodiments it is preferably <NUM> to <NUM>% by mass, more preferably <NUM> to <NUM>% by mass. By incorporating the non-conductive part at such a ratio, a favorable elongation of the conductive fibers <NUM> can be ensured and, by incorporating the conductive part at the above-described ratio, an effect of reducing the electrical resistance of the tire can be favorably obtained, both of which are preferred.

As the conductive fibers <NUM> in embodiments of the present invention, specifically, for example, BEKINOX (registered trademark) manufactured by Bekaert Corporation and CLACARBO (registered trademark) KC-500R and KC-793R manufactured by Kuraray Trading Co. can be used.

From the standpoint of satisfying the below-described air release performance, electrical conductivity and durability at the same time, the fineness of the conductive fibers <NUM> is preferably <NUM> to <NUM>,<NUM> dtex, more preferably <NUM> to <NUM>,<NUM> dtex, still more preferably <NUM> to <NUM> dtex.

In embodiments of the present invention, when the conductive fibers <NUM> are arranged in the form of fibers as they are, the conductive fibers <NUM> may be arranged linearly, or in a zigzag shape or an undulating shape. Further, in embodiments of the present invention, a conductive path from the tread portion <NUM> to each bead portion <NUM> can be secured as long as the conductive fibers <NUM> are inclined with respect to the tire circumferential direction, and the conductive fibers <NUM> are arranged in such a manner to extend in a direction of preferably <NUM>° to <NUM>°, more preferably <NUM>° to <NUM>°, with respect to the tire circumferential direction. Particularly, the conductive fibers <NUM> are arranged in such a manner to extend in the tire width direction. When the conductive fibers <NUM> are arranged in a zigzag shape or an undulating shape, the direction in which the conductive fibers <NUM> extend as a whole is defined as the extending direction of the conductive fibers.

In embodiments of the present invention, the conductive fibers <NUM> can be arranged in place of bleeder cords that are conventionally arranged for the purpose of removing air during tire vulcanization. A bleeder cord, which is a cord member arranged on one or both sides of a carcass or a belt layer for the purpose of reducing an inflation defect occurring in the tire production process, is generally composed of a cotton yarn or a polyester yarn. By arranging a bleeder cord, the air incorporated into the tire during the tire production process adsorbs to or permeates through the bleeder cord, whereby the occurrence of an inflation defect can be reduced. By replacing some or all of bleeder cords arranged on the carcass with the conductive fibers <NUM>, an effect attributed to the conductive fibers <NUM> can be obtained without an addition of a new member. As a matter of course, the expected effects of the present invention can also be obtained by leaving the bleeder cords as they are and additionally arranging the conductive fibers <NUM>.

When the conductive fibers <NUM> are arranged in place of conventional bleeder cords, the conductive fibers <NUM> may replace <NUM> to <NUM>% by mass, preferably <NUM> to <NUM>% by mass of the bleeder cords. The expected effects of embodiments of the present invention can be certainly obtained by replacing such a number of bleeder cords with the conductive fibers <NUM>.

The conductive fibers <NUM> used in embodiments of the present invention may be either spun yarns or filament yarns, and are preferably spun yarns (blended yarns) obtained by spinning short fibers. In order to ensure adhesion between the conductive fibers <NUM> and a rubber, it is necessary to perform a dipping treatment, which uses an adhesive agent for ensuring adhesion between organic fibers and a rubber, on the conductive fibers <NUM>; however, the formation of a surface coating of such an adhesive agent on the conductive fibers <NUM> by the dipping treatment leads to deterioration of the air release performance through the conductive fibers <NUM>. Accordingly, when the conductive fibers <NUM> are arranged in place of bleeder cords, it is preferred to perform the dipping treatment for only a part of each conductive fiber <NUM>, and it is more preferred not to perform the dipping treatment. Nevertheless, in the absence of a surface coating of an adhesive agent, a small adhesive force between the conductive fibers <NUM> and an unvulcanized rubber may cause the conductive fibers <NUM> to fall off during the production. In this case, it is preferred to use spun yarns (blended yarns) since adhesion thereof with a rubber can be ensured because of an anchoring effect of short fibers even without a dipping treatment, and the air release performance can be maintained while securing a conductive path. In the case of using filament yarns, the filament yarns are preferably twisted so as to maintain the air release performance and, in this case, the number of twists is preferably not less than <NUM> times/<NUM> and may be, for example, <NUM> to <NUM> times/<NUM>.

Meanwhile, when some of the bleeder cords are replaced with the conductive fibers <NUM>, since the air release performance can be ensured by the remaining bleeder cords composed of cotton yarns, the adhesion with a rubber and the air release performance can both be satisfied even if the conductive fibers <NUM> have been subjected to a dipping treatment. Therefore, in embodiments of the present invention, a dipping treatment may be performed on the conductive fibers <NUM>; however, from the standpoint of securing the degree of freedom in design such as replacement of all bleeder cords with the conductive fibers <NUM>, a dipping treatment is preferably not performed on the conductive fibers <NUM>.

From the standpoint of certainly securing a conductive path over the entire tire circumferential direction, it is preferred that at least two conductive fibers <NUM> be arranged in the whole tire.

In embodiments of the present invention, by arranging the above-described conductive member <NUM>, the electrical resistance of the tire can be reduced even when, for example, the volume resistivity of the coating rubber of the belt layer <NUM> is reduced in loss to <NUM> × <NUM><NUM> Ω·cm or higher, particularly about <NUM> × <NUM><NUM> Ω·cm to <NUM> × <NUM><NUM> Ω·cm, or the volume resistivity of the coating rubber of the carcass <NUM> is reduced in loss to <NUM> × <NUM><NUM> Ω·cm or higher, particularly about <NUM> × <NUM><NUM> Ω·cm to <NUM> × <NUM><NUM> Ω·cm.

In embodiments of the present invention, the volume resistivity of the rubber chafer <NUM> is preferably <NUM> × <NUM><NUM> Ω·cm or lower, more preferably <NUM> × <NUM><NUM> Ω·cm or lower, still more preferably <NUM> × <NUM><NUM> Ω·cm or lower, and the lower the volume resistivity, the more preferable. By controlling the volume resistivity of the rubber chafer <NUM> to be in the above-described range, an effect of reducing the electrical resistance of the tire can be favorably obtained.

In embodiments of the present invention, as illustrated in the drawings, the conductive rubber portion <NUM> can usually be arranged in the vicinity of the tire equator CL over the entirety of the tire circumference, at least from the tread ground-contact surface to the tire radial-direction inner surface of the tread rubber <NUM>. In other words, the conductive rubber portion <NUM> is arranged in such a manner to penetrate the tread rubber <NUM> from the tread ground-contact surface and forms a conductive path from the road surface to the inside of the tire.

Further, in embodiments of the present invention, the cushion rubber 13C is a rubber member which can be arranged between the tread rubber <NUM> and the coating rubber of the belt layer <NUM> (when a cap layer is arranged, a coating rubber of the cap layer) at least on the tire equator CL. The cushion rubber 13C usually extends to the vicinity of each tire shoulder portion and is covered with the tread rubber <NUM> and, depending on the arrangement mode, the side rubber <NUM> as well; therefore, the cushion rubber 13C is a rubber member that is not exposed on the tire outer surface.

In embodiments of the present invention, what is important is only that a prescribed conductive member is arranged and, this enables to obtain the expected effects of the present invention. Other parts of the tire structure are not particularly restricted and can be configured as appropriate in accordance with a conventional method.

For example, in the illustrated tire, the carcass <NUM> is folded and rolled up from the tire inner side to the outer side around bead cores <NUM> each embedded in the pair of the bead portions <NUM>, and a bead filler <NUM> having a tapering cross-sectional shape is arranged on the tire radial-direction outer side of each bead core <NUM>. Further, although not illustrated in the drawings, in the tire of the present invention, as required, a cap layer covering the entirety of the belt layer <NUM> and/or a layered layer covering only the end portions of the belt layer <NUM> may each be arranged in one or more layers on the tire radial-direction outer side of the belt layer <NUM>. The cap layer and the layered layer are each usually formed by winding one or more rubber-coated reinforcing cords substantially in the tire circumferential direction. Moreover, an inner liner is usually arranged on the innermost surface of the tire, although this is not illustrated in the drawings.

The present invention will now be described in more detail by way of Examples thereof.

A pneumatic tire having a tire size of <NUM>/65R15, which had a carcass composed of a single carcass ply toroidally extending between a pair of bead portions as a skeleton and included two belt layers, a cushion rubber and a tread rubber that were sequentially arranged on the tire radial-direction outer side of the carcass in a crown portion, and in which a rubber chafer (volume resistivity: <NUM> × <NUM><NUM> Ω·cm) was arranged on the tire width-direction outer surfaces of the bead portions, was produced. In this pneumatic tire, a cap layer was arranged on the tire radial-direction outer side of the belt layers at a width covering the belt layers, a belt-end cushion rubber (volume resistivity: <NUM> × <NUM><NUM> Ω·cm) was arranged between the belt layers and the carcass at a tire widthwise end of the belt layers, and a conductive rubber portion (volume resistivity: <NUM> × <NUM><NUM> Ω·cm) was arranged in a tread portion in such a manner to penetrate through the tread rubber from a ground-contact region of the tire surface toward the tire radial-direction inner side.

A coating rubber of the carcass had a volume resistivity of <NUM> × <NUM><NUM> Ω·cm while a coating rubber of the belt layer had a volume resistivity of <NUM> × <NUM><NUM> Ω·cm, and a low-loss rubber composition was used for both of these coating rubbers.

Test tires of Examples and Comparative Examples were produced by arranging conductive fibers in accordance with the respective conditions shown in the table below. As the conductive fibers, BEKINOX (registered trademark, polyester-metal fiber blended yarn) manufactured by Bekaert Corporation, which is a conductive fiber having a wire resistivity of <NUM> Q/cm and a fiber diameter of <NUM> dtex, was used, and the conductive fibers were arranged at <NUM>-mm intervals along the tire circumferential direction in such a manner to extend in the tire width direction.

For each of the thus obtained test tires, the electrical resistance value was evaluated as described below. The results thereof are shown in Table <NUM> below.

As illustrated in <FIG>, the electrical resistance value of each tire was measured in accordance with WdK <NUM> sheet <NUM> of GERMAN ASSOCIATION OF RUBBER INDUSTRY using a model HP4394A High Resistance Meter manufactured by Hewlett-Packard Company. In <FIG>, symbols <NUM>, <NUM>, <NUM> and <NUM> represent the tire, a steel sheet, an insulator and the high resistance meter, respectively, and the measurement was performed by applying an electric current of <NUM>,<NUM> V between the steel sheet <NUM> on the insulator <NUM> and the rim of the tire <NUM>.

The smaller the electrical resistance value of the tire, the more favorable it is.

The rolling resistance of each tire was measured in accordance with SAE J1269 using a rolling resistance tester. The results thereof are presented below as index values based on Comparative Example <NUM>. A larger numerical value indicates more favorable rolling resistance performance.

The results of the above measurements are shown together in Table <NUM> below.

Claim 1:
A pneumatic tire (<NUM>) comprising:
a carcass (<NUM>) composed of at least one carcass ply toroidally extending between a pair of bead portions (<NUM>), as a skeleton;
a tread rubber (<NUM>) arranged on a tire radial-direction outer side of the carcass in a crown portion;
a conductive rubber portion (<NUM>) arranged in such a manner to penetrate through the tread rubber from a ground-contact region of a tire surface toward a tire radial-direction inner side; and
a rubber chafer (<NUM>) arranged on a tire width-direction outer surface of each of the bead portions,
wherein
a conductive member (<NUM>) that electrically connects from a tire radial-direction inner end of the conductive rubber portion to the rubber chafer is arranged,
the conductive member comprises conductive fibers at least in the vicinity of the tire radial-direction inner end of the conductive rubber portion and the vicinity of the rubber chafer,
the conductive member has a volume resistivity of <NUM> × <NUM><NUM> Ω·cm or lower,
at least one belt layer (<NUM>) is arranged between the carcass and the tread rubber, the pneumatic tire is characterized in that
a belt-end cushion rubber (<NUM>) is arranged between the belt layer and the carcass at a tire widthwise end of the belt layer, and
the conductive member comprises the conductive fibers and the belt-end cushion rubber.