Load derivation method

Abstract

A load derivation method includes: a distance measurement step of measuring, by a displacement meter attached to a rim, a distance from the displacement meter to an inner surface of a tire; an internal pressure measurement step of measuring an internal pressure of the tire, by a sensor attached in a chamber of the tire; and a load derivation step of deriving, by a derivation section, a load on the tire during running, based on the measured distance and the measured internal pressure.

Claims

1. A tire life prediction method comprising: measuring, by a displacement meter attached to a rim, a distance from the displacement meter to an inner surface of a tire; measuring an internal pressure of the tire, by a sensor attached in a chamber of the tire; deriving, by a derivation section, a load on the tire during running, based on the measured distance and the measured internal pressure, predicting a tire life by a determination section based on the load derived based on the measured distance and the measured internal pressure, wherein the displacement meter is attached on or in a hole of a rim base portion.

2. The tire life prediction method according to claim 1, wherein the load is derived per tire.

3. The tire life prediction method according to claim 1, wherein the load is derived based on the measured distance, the measured internal pressure, and information indicating a relationship between the distance, the internal pressure, and the load prepared.

4. The tire life prediction method according to claim 1, wherein the displacement meter is a laser displacement meter.

5. The tire life prediction method according to claim 1, wherein the measuring is performed continuously in real time.

6. The tire life prediction method according to claim 1, wherein the predicting comprises evaluating wear amount.

7. A tire life prediction method comprising: measuring, by a displacement meter attached to a rim, a distance from the displacement meter to an inner surface of a tire; measuring an internal pressure of the tire, by a sensor attached in a chamber of the tire; and deriving, by a derivation section, a load on the tire during running, based on the measured distance and the measured internal pressure, predicting a tire life by a determination section based on the load derived based on the measured distance and the measured internal pressure, wherein the displacement meter is attached on or in a hole of a rim base portion, and wherein the displacement meter is attached at a position that deviates from a bead sheet band portion in the tire width direction.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) In the accompanying drawings:

(2) FIG. 1 is a perspective sectional view of a tire/rim assembly and a diagram illustrating an external functional section for describing a load derivation method according to one of the disclosed embodiments;

(3) FIG. 2 is a flowchart illustrating a load derivation method according to one of the disclosed embodiments; and

(4) FIG. 3 is a schematic diagram illustrating the relationship between the measurement time and the measured distance by a displacement meter.

DETAILED DESCRIPTION

(5) Disclosed embodiments are described in detail below, with reference to the drawings.

(6) FIG. 1 is a perspective sectional view of a tire/rim assembly and a diagram illustrating an external functional section for describing a load derivation method according to one of the disclosed embodiments. This embodiment is suitable for deriving a load on a pneumatic tire for construction/mine vehicles (hereafter also simply referred to as tire). As illustrated in FIG. 1, a tire/rim assembly 1 is formed by attaching a tire 2 to a rim 3. In the illustrated example, the rim 3 is a segment rim. The rim 3 includes a rim base portion 3a extending in the tire width direction in the state where the tire 2 is attached to the rim 3, and a rim flange portion 3b in contact with a bead portion of the tire 2. On one side in the extending direction of the rim base portion 3a which is the tire width direction, the rim base portion 3a and the rim flange portion 3b directly fit to each other. On the other side in the extending direction of the rim base portion 3a which is the tire width direction, the rim flange portion 3b is fittable to a bead sheet band portion 3c, and the bead sheet band portion 3c and the rim base portion 3a are removably attachable to each other by a lock ring 3d.

(7) The rim base portion 3a of the rim 3 has one hole at a tire width direction position on an extension of a tire equatorial plane CL, in the example illustrated in FIG. 1. A displacement meter 4 is attached in this hole through an attachment plate 5, thus being attached and fixed to the rim 3. The displacement meter 4 is capable of measuring the distance from the position of the displacement meter 4 to the tire inner surface (in the case where an inner liner is attached to the tire inner surface, the distance from the position of the displacement meter 4 to the inner liner). The displacement meter 4 is preferably an optical displacement meter, and particularly preferably a laser displacement meter. Such a displacement meter can measure the above-mentioned distance easily. The displacement meter 4 may be any meter capable of measuring the above-mentioned distance. Examples include not only an optical displacement meter, but also other well-known displacement meters such as a contact-type displacement meter. The arrow in FIG. 1 indicates the position of the tire inner surface subjected to the distance measurement. In the example illustrated in FIG. 1, the displacement meter 4 is attached at a position that deviates from the bead sheet band portion 3c in the tire width direction, in one part on the circumference.

(8) In the example illustrated in FIG. 1, the displacement meter 4 is attached in the hole of the rim base portion 3a. Alternatively, the displacement meter 4 may be placed on and fixed to the rim base portion 3a. In this case, the rim base portion 3a need not have a hole for attaching the displacement meter 4. A point on the tire inner surface subjected to the measurement is preferably at a position (on a line extending in the tire radial inward direction from the below-mentioned middle position) corresponding to the tire width direction range from the tire equatorial plane CL to the middle position of the half-width of the ground contact width in the tire width direction in the state of the tire/rim assembly 1 (the state where the tire 2 is filled to a prescribed internal pressure and placed under no load) (in the example illustrated in FIG. 1, a point on the tire inner surface directly below the tire equatorial plane CL). Thus, it is preferable to measure the distance from the displacement meter 4 to the tire inner surface at a tire width direction position corresponding to the tire width direction range in which a belt layer is located.

(9) The term ground contact width refers to the width measured in the tire width direction between the tire width direction outer edges of the contact patch that comes into contact with the road surface when the tire attached to an applicable rim and filled to a prescribed internal pressure is placed under a maximum load. The term applicable rim refers to an approved rim (measuring rim in ETRTO Standards Manual, design rim in TRA Year Book) in applicable size described in an effective industrial standard in areas where tires are produced or used, such as JATMA (Japan Automobile Tyre Manufacturers Association) Year Book in Japan, ETRTO (European Tyre and Rim Technical Organisation) Standards Manual in Europe, or TRA (Tire and Rim Association, Inc.) Year Book in the United States. The term prescribed internal pressure refers to the air pressure corresponding to the maximum load capability in applicable size and ply rating described in JATMA Year Book or the like. The term maximum load capability refers to the maximum mass permitted to be loaded onto the tire in the standard. The term maximum load refers to the load corresponding to the maximum load capability.

(10) As illustrated in FIG. 1, a sensor 6 is attached in the chamber of the tire/rim assembly 1 (attached to the bead portion inner surface of the tire in the illustrated example). In this example, the sensor 6 can continuously measure the internal pressure of the tire. The sensor 6 preferably measures the internal pressure while measuring the temperature in the chamber.

(11) FIG. 2 is a flowchart illustrating a load derivation method according to one of the disclosed embodiments. In the load derivation method according to this embodiment, for example using the tire/rim assembly 1 having the structure illustrated in FIG. 1, the distance from the displacement meter 4 to the tire inner surface is measured by the displacement meter 4 attached to the rim 3 (distance measurement step: step S101). Although the distance from the displacement meter 4 to at least one point on the tire inner surface may be measured here, it is preferable to measure the distance from the displacement meter 4 to each of two or more points in the tire circumferential direction on the tire inner surface, or the distance from the displacement meter 4 to each of a plurality of points continuous on a line. Thus, the advantageous effects according to this disclosure can be achieved even in such a case where a tear occurs on the tire. Step S101 is preferably performed continuously in real time. Alternatively, step S101 may be performed intermittently. In this case, the point(s) subjected to the measurement is unchanged.

(12) Moreover, in this embodiment, for example using the tire/rim assembly 1 having the structure illustrated in FIG. 1, the internal pressure of the tire 2 is measured by the sensor 6 attached in the chamber of the tire 2 (internal pressure measurement step: step S102). Step S102 is preferably performed continuously in real time, but may be performed intermittently. In step S102, it is preferable to measure the internal pressure at the time at which the distance is measured in step S101. Alternatively, information of the internal pressure corresponding to the distance measured in step S101 may be obtained by, for example, complementing the internal pressure data measured in step S102.

(13) Next, in this embodiment, for example using the tire/rim assembly 1 having the structure illustrated in FIG. 1, the load on the tire during running is derived based on the distance measured by the displacement meter 4 and the internal pressure measured by the sensor 6 (load derivation step: step S103).

(14) FIG. 3 is a schematic diagram illustrating the relationship between the measurement time and the measured distance by the displacement meter. As illustrated in FIG. 3, the distance from the displacement meter to a specific point on the tire inner surface shortens when the point is in the contact patch. Hence, the distance can be associated with the load on the tire during running (i.e. it is possible to link a shorter distance to a greater load on the tire). Its quantitative degree, however, varies depending on the state of the internal pressure of the tire. Accordingly, the load can be derived accurately by using the measured distance and the measured internal pressure as in this embodiment. In this embodiment, it is preferable to hold, as a look-up table or the like, information indicating the relationship between the distance, the internal pressure, and the load prepared beforehand, and derive the load based on the measured distance, the measured internal pressure, and the information. Thus, the load can be derived easily. Preferably, the displacement meter 4 and the sensor 6 have a communication portion that transmits the information of the measured distance and internal pressure to the vehicle or the outside, and a derivation section 11 in an external functional section 10 having information indicating the relationship between the measured distance and internal pressure and the load on the tire during running derives the load. Thus, it is preferable to cause the functional section in the tire/rim assembly 1 to perform only simple processes. Alternatively, the derivation section 11 may be included in the tire/rim assembly 1.

(15) After the load is derived by the load derivation method according to this embodiment, a determination section 12 can predict the tire life based on the derived load (step S104). Since the durability, wear amount, etc. of the tire greatly depend on the load on the tire, the durability or wear amount of the tire can be accurately predicted based on the derived load. The determination section 12 is preferably included in the functional section 10 that includes the derivation section 11.

(16) With the load derivation method according to this embodiment, for example, an actual load on a tire for construction/mine vehicles during running can be derived accurately. Hence, for example, the durability or wear amount of the tire can be accurately predicted based on the derived load, to accurately predict the tire life. Since the tire life is predicted based on the actual load, accurate prediction is achieved as compared with the case of predicting the tire life using a load mounted on the vehicle. The user can perform management such as changing the tire use condition to a gentler condition or replacing tires between vehicles, depending on the prediction result. In the case where the displacement meter 4 is attached to the tire 2, the displacement meter 4 itself is displaced due to deformation of the tire 2, so that the distance cannot be measured accurately. Besides, To attach the displacement meter 4 to the tire 2, processes such as buffing the inner liner, then performing cleaning, and then adhering the displacement meter 4 with unvulcanized rubber are required. In this embodiment, on the other hand, since the displacement meter 4 is attached to the rim 3, not only the distance can be measured accurately but also the above-mentioned processes can be omitted. Furthermore, since the displacement meter 4 is attached to the rim 3, an external power source can be used. This makes it possible to keep using the method according to this embodiment, regardless of battery life and the like.

(17) In this disclosure, the load is preferably derived per tire rotation. Thus, the load can be derived per tire rotation, i.e. each time the point subjected to the measurement enters the contact patch as described with reference to FIG. 3, so that the data of the load derived per tire rotation can be used to accurately predict the tire life.

(18) Preferably, the load derivation method according to this disclosure further includes a step of calculating the running speed and/or the running acceleration based on the temporal change of the measured distance and the measured internal pressure. A period in which the measured distance shortens occurs per tire rotation, as illustrated in FIG. 3. Accordingly, by detecting the temporal change of the measured distance, the running speed and/or the running acceleration can be calculated easily. The relationship between the distance and the running speed and/or the running acceleration varies with the internal pressure, and so the running speed and/or the running acceleration is calculated based on the measured internal pressure. The use of the running speed and/or the running acceleration in addition to the derived load enables more accurate prediction of the tire life. In this disclosure, the running speed and/or the running acceleration is preferably calculated per tire rotation, for the same reason as stated above.

(19) In the tire life prediction step (step S104), the durability of the tire can be evaluated based on the derived load. Moreover, in the tire life prediction step (step S104), the wear amount of the tire can be evaluated based on the derived load. Having evaluated the durability or wear amount of the tire based on the derived load, the tire life can be predicted using the evaluation result as an index. The advantageous effects according to this disclosure can thus be utilized effectively. Both the durability of the tire and the wear amount of the tire may be evaluated and used as indices of the tire life.

(20) The tire life prediction step (step S104) may be performed by simulating the deformation of the tire members based on the derived load. Thus, the durability of the tire can be evaluated more accurately based on the load and the deformation of the tire members caused by the load, as a result of which the tire life can be predicted accurately. The simulation may be performed using FEM as an example. When evaluating the wear amount of the tire, on the other hand, it is preferable to derive/calculate the load, the running speed, and the running acceleration, as mentioned above. The wear amount of the tire can be evaluated more accurately using these derived/calculated information, as a result of which the tire life can be predicted accurately.

(21) While one of the disclosed embodiments has been described above, the load derivation method according to this disclosure is not limited to the above embodiment. For example, although the sensor 6 is separate from the displacement meter 4 in the above embodiment, the displacement meter 4 may have a function of measuring the internal pressure of the tire. Other various modifications are possible.

REFERENCE SIGNS LIST

(22) 1 tire/rim assembly 2 tire 3 rim 3a rim base portion 3b rim flange portion 3c bead sheet band portion 3d lock ring 4 displacement meter 5 attachment plate 6 sensor 10 functional section 11 derivation section 12 determination section