JP2022050094A - Evaluation method of tyre - Google Patents

Abstract

To provide an evaluation method of a tyre 2, capable of evaluating a displacement of a tyre 2 to a rim R accurately at a low cost.SOLUTION: An evaluation method includes: (1) a running-in process S2 of running a tyre 2 assembled to a rim R in a state with a load applied to the tyre 2 for a prescribed time to heat the tyre 2; (2) a confirmation process S3 of measuring a temperature of the tyre 2 to confirm a heating state of the tyre 2; (3) an actual running process S4 of running the tyre 2 further for a prescribed time to increase a displacement of the tyre 2 to the rim R; and (4) a measurement process S5 of measuring an amount of the displacement of the tyre 2 to the rim R. A reference temperature is set for determining whether or not to execute the actual running process S4, and the actual running process S4 is executed if the temperature of the tyre 2 measured at the confirmation process S3 is below the reference temperature.SELECTED DRAWING: Figure 3

Description

The present invention relates to a tire evaluation method. In particular, the invention relates to a method for assessing tire misalignment with respect to a rim.

Tires are used by assembling on the rim. Tires may shift with respect to the rim while driving. Tire misalignment with respect to the rim (hereinafter, also referred to as rim misalignment) leads to transmission loss of power generated by a power generator such as an engine or a motor. It is important to assess tire rim misalignment. A method for evaluating a tire rim deviation is disclosed in, for example, Patent Documents 1 and 2 below.

Solid tires (hereinafter, also referred to as tires) are used for industrial vehicles such as forklifts. The tires are solid type and do not require air filling. This tire is assembled to the rim in the same way as a pneumatic tire.

Japanese Unexamined Patent Publication No. 2008-309723 Japanese Unexamined Patent Publication No. 05-249001

Industrial vehicles carry luggage. High load acts on solid tires. Industrial vehicles frequently run and stop. Tires generate heat. Heat generation reduces the rigidity of the tire. The road surface on which industrial vehicles travel is smooth and has high frictional resistance. This tire is used in an environment where rim slippage is likely to occur.

The evaluation of the rim deviation of a solid tire is usually performed by actually driving the vehicle. The evaluation results are easily affected by the test environment such as air temperature and road surface temperature, and the reproducibility is poor. It is difficult to confirm the effectiveness of the technology adopted to suppress the occurrence of rim misalignment in the evaluation using an actual vehicle. Moreover, in this evaluation, it is necessary to arrange the vehicle and the course on which the vehicle runs. Even if the test environment is prepared, there is a concern that damage such as porous fracture due to heat generation may occur in the tire before the rim shift occurs. There is a need to establish an evaluation method that can accurately evaluate tire displacement with respect to the rim at low cost.

The present invention has been made in view of such an actual situation, and an object of the present invention is to provide a tire evaluation method capable of accurately evaluating a tire deviation with respect to a rim at low cost.

The tire evaluation method according to one aspect of the present invention is a method for evaluating the displacement of the tire with respect to the rim. The evaluation method for this tire is
(1) A break-in running process in which the tire is run for a predetermined time with a load applied to the tire assembled on the rim to generate heat.
(2) A confirmation step of measuring the temperature of the tire to confirm the heat generation state of the tire.
(3) The running step further comprises running the tire for a predetermined time to increase the displacement of the tire with respect to the rim, and (4) measuring the amount of displacement of the tire with respect to the rim. The main running step is performed when the reference temperature for determining whether or not the main running step can be carried out is set and the temperature of the tire measured in the confirmation step is equal to or lower than the reference temperature.

Preferably, in this tire evaluation method, the rim and the tire are marked in order to measure the amount of displacement of the tire with respect to the rim.

Preferably, in this tire evaluation method, a hole is made in the tire, and the temperature in the hole is measured as the temperature of the tire.

Preferably, in this tire evaluation method, the tire is perforated with a plurality of holes, the plurality of holes having different depths.

Preferably, in this tire evaluation method, when the temperature of the tire measured in the confirmation step exceeds the reference temperature, the load is adjusted and the break-in running step is performed again.

Preferably, in this tire evaluation method, when the main running step is performed a plurality of times, the interval from one main running step to the next main running step is 12 hours or more.

Preferably, in this tire evaluation method, the tire is a pneumatic solid tire for industrial vehicles.

According to the present invention, it is possible to obtain a tire evaluation method capable of accurately evaluating a tire displacement with respect to a rim at low cost.

FIG. 1 is a cross-sectional view showing an example of a tire used in a tire evaluation method. FIG. 2 is a perspective view showing an example of the test device. FIG. 3 is a flow chart showing a flow of a tire evaluation method. FIG. 4 is a side view showing a measurement example of the amount of displacement of the tire with respect to the rim. FIG. 5 is a cross-sectional view showing an example of forming a hole for temperature measurement. FIG. 6 is a cross-sectional view showing another example of forming a hole for temperature measurement.

Hereinafter, the present invention will be described in detail based on a preferred embodiment with reference to the drawings as appropriate.

[tire]
With reference to FIG. 1, the tire 2 used in the tire evaluation method according to the embodiment of the present invention will be described. FIG. 1 shows an example of the tire 2 used in this evaluation method. In FIG. 1, the left-right direction is the axial direction of the tire 2, and the vertical direction is the radial direction of the tire 2. The direction perpendicular to the paper surface is the circumferential direction of the tire 2. The tire 2 is assembled on the rim R. The rim R is a standard rim. The alternate long and short dash line CL represents the equatorial plane of this tire 2.

The regular rim means the rim R defined in the standard on which the tire 2 relies. The "standard rim" in the JATMA standard, the "Design Rim" in the TRA standard, and the "Measuring Rim" in the ETRTO standard are regular rims.

The tire 2 is a pneumatic solid tire for industrial vehicles. The tire 2 includes a base portion 4, a reinforcing element 6, and a tread portion 8. The base portion 4 is made of crosslinked rubber. The base portion 4 is fitted to the rim R. The reinforcing element 6 extends in the circumferential direction in the base portion 4. The reinforcing element 6 is made of a steel wire rod. The tread portion 8 is made of crosslinked rubber. The outer surface of the tread portion 8 is the tread surface 10. The tire 2 comes into contact with the road surface on the tread surface 10.

[Test equipment]
The test apparatus 12 used in the evaluation method of the tire 2 will be described with reference to FIG. FIG. 2 shows an example of the test apparatus 12 used in this evaluation method. The test device 12 is a drum running tester.

The test device 12 includes a drum 14 and a support device 16. The drum 14 and the support device 16 are installed on the gantry 18.

The drum 14 is rotatably supported by the gantry 18. A drive means (not shown) rotates the drum 14. Examples of the driving means include an electric motor. In this test device 12, the tire 2 runs on the outer peripheral surface of the drum 14. This outer peripheral surface is a traveling surface 20. The diameter of the drum 14 is appropriately set in the range of 1.0 m to 2.0 m.

The support device 16 includes a rotating shaft 22. The rim R to which the tire 2 is assembled is supported by the rotating shaft 22. The rotary shaft 22 is rotatably supported by the support device 16 by a bearing (not shown).

Although not shown, the support device 16 further comprises a rotary drive mechanism and a brake mechanism. In this support device 16, it is possible to rotatably support the rotary shaft 22, rotate the rotary shaft 22 regardless of the drum 14, and restrain the rotary shaft 22. In this test apparatus 12, it is possible to accelerate, decelerate, and stop the tire 2 assembled on the rim R.

The support device 16 is provided with an elevating device (not shown) such as a fluid pressure cylinder. This elevating device adjusts the position of the tire 2 with respect to the drum 14. By this adjustment, the tire 2 is brought into contact with the traveling surface 20. By pressing the tire 2 against the traveling surface 20, a predetermined load is applied to the tire 2.

Although not shown, the support device 16 is further provided with an angle adjusting means for adjusting the angle of the rotating shaft 22 with respect to the drum 14. In this test device 12, the camber angle of the tire 2 can also be adjusted. In this evaluation method, the camber angle is set to 0 °.

In this test device 12, the rotating shaft 22 of the support device 16 is rotatable, and the drum 14 is rotated with a predetermined load applied to the tire 2. As a result, the tire 2 travels on the traveling surface 20 of the drum 14.

[Evaluation methods]
Next, the evaluation method of the tire 2 will be described. This evaluation method is a method for evaluating the deviation of the tire 2 with respect to the rim R. FIG. 3 shows the flow of this evaluation method. This evaluation method includes a preparation step S1, a break-in running step S2, a confirmation step S3, a main running step S4, and a measurement step S5.

In the preparation step S1, the tire 2 is assembled to the rim R. The rim R to which the tire 2 is assembled is attached to the rotating shaft 22 of the test device 12. In the test apparatus 12, the position of the tire 2 with respect to the drum 14 is adjusted. The tire 2 is pressed against the traveling surface 20. A predetermined load is applied to the tire 2. As a result, the tire 2 is set in the test device 12. The preparation step S1 is a step of setting the tire 2 on the test device 12.

In this evaluation method, the load applied to the tire 2 is not particularly limited. In this evaluation method, the load applied to the tire 2 is appropriately determined according to the specifications of the tire 2 to be evaluated. In this evaluation method, the load applied to the tire 2 is preferably 10 kN or more, and preferably 50 kN or less.

In the break-in running step S2, the drum 14 is rotated and the running of the tire 2 is started. After running the tire 2 for a predetermined time, the rotation of the drum 14 is stopped, and the running of the tire 2 is stopped. Tire 2 generates heat as it travels. This break-in running step S2 is a step of running the tire 2 for a predetermined time in a state where a load is applied to the tire 2 assembled on the rim R to generate heat.

In this evaluation method, it is sufficient that the tire 2 generates heat due to running, and the speed and running time of the tire 2 in the break-in running step S2 are not particularly limited. The speed and running time of the tire 2 in the break-in running step S2 are appropriately set in consideration of the heat generation state, productivity, and the like of the tire 2 after running. In this evaluation method, the speed of the tire 2 in the break-in running step S2 is preferably 10 km / h or more, more preferably 20 km / h or more. This speed is preferably 50 km / h or less, more preferably 40 km / h or less. The running time of the tire 2 in the break-in running step S2 is preferably 5 minutes or more, more preferably 10 minutes or more. The traveling time is preferably 25 minutes or less, more preferably 20 minutes or less, still more preferably 15 minutes or less.

In the confirmation step S3, the temperature of the tire 2 is measured. As a result, the heat generation state of the tire 2 is confirmed. This confirmation step S3 is a step of measuring the temperature of the tire 2 and confirming the heat generation state of the tire 2. In this evaluation method, if it is determined in the confirmation step S3 that the tire 2 is in an appropriate heat generation state, the main running step S4 is performed.

In the main traveling step S4, the rotation of the stopped drum 14 is restarted. As a result, the running of the tire 2 is restarted. After running the tire 2 for a predetermined time, the rotation of the drum 14 is stopped, and the running of the tire 2 is stopped. In this evaluation method, the load applied to the tire 2 in the main traveling process S4 is the same as the load applied to the tire 2 in the break-in traveling process S2.

The tire 2 in the main traveling step S4 is in a heat generating state. The heat generation reduces the rigidity of the tire 2. The tire 2 in the main traveling step S4 is in a state of reduced rigidity. If the tire 2 is easily displaced with respect to the rim R, the displacement of the tire 2 with respect to the rim R increases in S4 in this traveling step. This running step S4 is a step of further running the tire 2 for a predetermined time to increase the deviation of the tire 2 with respect to the rim R.

In this evaluation method, the speed of the tire 2 in the main running step S4 is set to the same speed as the speed of the tire 2 in the running-in running step S2 from the viewpoint of appropriately maintaining the heat generation state of the tire 2.

In this evaluation method, the running time of the tire 2 in the main running step S4 is set to be longer than the running time of the tire 2 in the break-in running step S2 from the viewpoint of promoting the displacement of the tire 2 with respect to the rim R. In this evaluation method, the running time of the tire 2 in the main running step S4 is preferably 10 minutes or more, more preferably 15 minutes or more, still more preferably 20 minutes or more. From the viewpoint of maintaining an appropriate heat generation state, this traveling time is preferably 30 minutes or less, more preferably 25 minutes or less.

In the measurement step S5, the amount of displacement of the tire 2 with respect to the rim R is measured. This measurement step S5 is a step of measuring the amount of deviation of the tire 2 with respect to the rim R. In this evaluation method, it is determined whether or not the tire 2 is likely to be displaced with respect to the rim R based on the displacement amount obtained in the measurement step S5.

As described above, in this evaluation method, it is determined in the confirmation step S3 whether or not the tire 2 is in an appropriate heat generation state. If it is determined that the tire 2 is in an appropriate heat generation state, the main traveling step S4 is performed. If it is determined that the heat generation state of the tire 2 is not appropriate, in other words, the heat generation state of the tire 2 exceeds the assumption, the main traveling step S4 is not performed. In this evaluation method, a reference temperature for determining whether or not the main traveling step S4 can be carried out is set.

In this evaluation method, the temperature at which damage such as porous destruction does not occur within the traveling time set in the main traveling process S4, specifically, damage such as porous destruction within the traveling time set in the main traveling process S4. The temperature at which is not expected to occur is set as the reference temperature. When the temperature of the tire 2 measured in the confirmation step S3 is equal to or lower than the reference temperature, the main running step S4 is performed.

In this evaluation method, the ease with which the tire 2 is displaced with respect to the rim R is taken into consideration when setting the reference temperature. From this point of view, the reference temperature is set to at least a temperature higher than the temperature of the tire 2 (hereinafter referred to as the normal running temperature) confirmed in the normal use state. This is because if the reference temperature is set at a temperature lower than the normal running temperature, it takes time to evaluate. On the other hand, if the temperature of the tire 2 is too high, the tire 2 itself is deteriorated by the thermal action. In this case, the damage as described above occurs, and the rim deviation of the tire 2 cannot be accurately evaluated. From this point of view, this reference temperature is set to a temperature lower than the temperature at which the deterioration of the tire 2 due to the thermal action is suppressed. For example, when a pneumatic solid tire for an industrial vehicle is used as a tire 2, the ease of displacement of the tire 2 with respect to the rim R and the deterioration of the tire 2 due to thermal action are taken into consideration, and the reference temperature is 110 ° C. or higher and 130 ° C. or higher. It is set in the range of ℃ or less.

In this evaluation method, the break-in running step S2 is performed before the main running step S4. Since the main running step S4 is performed on the generated tire 2, as described above, if the tire 2 is easily displaced with respect to the rim R, the tire 2 with respect to the rim R is subjected to this running step in S4. The deviation increases.

In this evaluation method, the main running step S4 is performed on the tire 2 whose temperature is confirmed to be equal to or lower than the reference temperature in the confirmation step S3. Since the main running step S4 is performed on the tire 2 in an appropriate heat generation state, the risk that the main running step S4 causes damage to the tire 2 is considerably low. With this evaluation method, it is possible to evaluate the displacement of the tire 2 with respect to the rim R, which reduces the risk of damage.

Further, in this evaluation method, the deviation of the tire 2 with respect to the rim R is evaluated in the test device 12. In this evaluation method, it is possible to set conditions such as the atmospheric temperature to be evaluated, the load applied to the tire 2, the speed of the tire 2, and the running time of the tire 2. With this evaluation method, it is possible to obtain a finding with high reproducibility regarding the deviation of the tire 2 with respect to the rim R.

This evaluation method can accurately evaluate the deviation of the tire 2 with respect to the rim R. Moreover, this evaluation method does not require the arrangement of vehicles or the like. This evaluation method can accurately evaluate the deviation of the tire 2 with respect to the rim R at low cost.

As described above, in this evaluation method, the main traveling step S4 is performed when the temperature of the tire 2 measured in the confirmation step S3 is equal to or lower than the reference temperature. On the other hand, when the temperature of the tire 2 measured in the confirmation step S3 exceeds the reference temperature, the load applied to the tire 2 is adjusted, and the break-in running step S2 is performed again. By reducing the load applied to the tire 2, heat generation of the tire 2 due to running can be suppressed. In this evaluation method, the next break-in running step S2 is performed with a load lower than the load of the previous break-in running step S2. In this evaluation method, even if the tire 2 tends to generate heat, the main traveling step S4 is performed in an appropriate heat generation state. With this evaluation method, it is possible to identify the tire 2 that easily generates heat. In this evaluation method, it is possible to measure the amount of deviation of the tire 2 with respect to the rim R even for the tire 2 which has been damaged and could not measure the amount of deviation with respect to the rim R in the past. This evaluation method can accurately evaluate the deviation of the tire 2 with respect to the rim R for various tires 2 at low cost. From this point of view, in this evaluation method, when the temperature of the tire 2 measured in the confirmation step S3 exceeds the reference temperature, the load applied to the tire 2 is adjusted, and the break-in running step S2 is performed again. preferable.

The speed of the tire 2 also affects the heat generation of the tire 2. In this evaluation method, in order to suppress heat generation of the tire 2 due to running, the speed of the tire 2 in the next break-in running step S2 may be set to a speed lower than the speed in the previous running-in running step S2.

In this evaluation method, when the amount of deviation measured in the measurement step S5 is small and it is difficult to determine whether the tire 2 is a tire that is easily displaced with respect to the rim R, the main running is performed until it becomes possible to determine. Step S4 and measurement step S5 may be repeated. In this case, since the tire 2 further generates heat in the main traveling step S4, the risk of damage may increase. However, in this evaluation method, when the main traveling process S4 is performed a plurality of times, the interval from one main traveling process S4 to the next main traveling process S4 is set to 12 hours or more. As a result, the tire 2 is cooled to at least the temperature of the tire 2 confirmed in the confirmation step S3. Since the tire 2 is cooled to a temperature suitable for performing the main running step S4, the risk of damage to the tire 2 in the next main running step S4 can be reduced. From this point of view, in this evaluation method, when the main running step S4 is performed a plurality of times, the interval from one main running step S4 to the next main running step S4 is preferably 12 hours or more.

FIG. 4 shows the side surface of the tire 2 assembled on the rim R. FIG. 4A shows a state before the start of the break-in running process S2. FIG. 4B shows a state after the main traveling step S4 is completed.

In this evaluation method, a mark M is attached to the rim R and the tire 2 as shown in FIG. 4 (a). In the main traveling step S4, since the tire 2 is displaced with respect to the rim R, the mark Mt attached to the tire 2 is displaced in the circumferential direction from the mark Mr attached to the rim R as shown in FIG. 4 (b). .. In this evaluation method, the distance from the mark Mr attached to the rim R to the mark Mt attached to the tire 2 is measured as the amount of deviation of the tire 2 with respect to the rim R. Adding the mark M to the rim R and the tire 2 contributes to an accurate grasp of the amount of deviation of the tire 2 with respect to the rim R. With this evaluation method, it is possible to quantitatively grasp the amount of displacement of the tire 2 with respect to the rim R. From this point of view, in this evaluation method, it is preferable that the mark M is attached to the rim R and the tire 2 in order to measure the amount of deviation of the tire 2 with respect to the rim R. In this case, this mark M may be attached to the rim R and the tire 2 in the preparation step S1 and before the start of the main running step S4 (when performing the main running step S4 a plurality of times, the first main running). Before the start of step S4), this mark M may be attached to the rim R and the tire 2.

As described above, the temperature of the tire 2 is measured in the confirmation step S3. In this evaluation method, as shown in FIG. 5, a hole 24 is formed in the tire 2 in the preparation step S1 for the temperature measurement of the tire 2. Although not shown, the temperature in the hole 24 is measured as the temperature of the tire 2 by inserting the sensor portion of the thermometer into the hole 24. In this evaluation method, the internal temperature of the tire 2, which is not easily affected by the atmospheric temperature, is measured, so that the heat generation state of the tire 2 can be accurately grasped. This evaluation method can effectively reduce the risk of damage due to heat generation. From this point of view, in this evaluation method, it is preferable that a hole 24 is formed in the tire 2 and the temperature in the hole 24 is measured as the temperature of the tire 2.

The tire 2 is provided with a hole 24 extending inward from the tread surface 10. A hole 24 extending inward from the side surface 26 may be provided in the tire 2 for measuring the internal temperature of the tire 2. The position, size, and depth of the hole 24 are appropriately determined from the viewpoint of grasping an appropriate heat generation state in consideration of the risk of damage starting from the hole 24.

In this evaluation method, a plurality of holes 24 may be provided in the tire 2 in order to measure the temperature of the tire 2. In this case, a plurality of holes 24 having different depths may be provided in the tire 2. For example, as shown in FIG. 6, a first hole 24a whose bottom is located inside the tread portion 8, a second hole 24b whose bottom is located at the boundary between the tread portion 8 and the base portion 4, and a base portion 4 By providing a third hole 24c whose bottom is located inside the tread portion 8, it is possible to measure the temperature inside the tread portion 8, the temperature at the boundary between the tread portion 8 and the base portion 4, and the temperature inside the base portion 4. It becomes. Since it is possible to more accurately grasp the heat generation state of the tire 2, this evaluation method can more effectively reduce the risk of damage due to heat generation. From this point of view, in this evaluation method, it is preferable that a plurality of holes 24 are formed in the tire 2 and these holes 24 have different depths. In this evaluation method, when a plurality of holes 24 are provided in the tire 2, these holes 24 may be arranged at intervals in the axial direction or may be arranged at intervals in the circumferential direction.

As described above, according to the present invention, it is possible to obtain a tire 2 evaluation method capable of accurately evaluating the deviation of the tire 2 with respect to the rim R at low cost. In particular, the present invention exerts a remarkable effect in the evaluation of the deviation of the pneumatic solid tire 2 for industrial vehicles, which is a solid type, with respect to the rim R.

Hereinafter, the present invention will be described in more detail with reference to Examples and the like, but the present invention is not limited to such Examples.

[Tire preparation]
We prepared a tire (hereinafter, tire G) that has been confirmed to be less likely to cause displacement with respect to the rim, and a tire (hereinafter, tire B) that has been confirmed to be prone to displacement with respect to the rim. Both tire G and tire B are pneumatic solid tires for industrial vehicles. Both the tire G and the tire B have a size of T.6.50-10.

[Example 1]
The tire G was attached to the rim (size = 10 × 5.00F DT) and set in the test device. The load applied to the tire G was set to 25 kN, and the running speed in the break-in running process and the main running process was set to 15 km / h.
The running time in the running-in process was set to 10 minutes. After the break-in process, a confirmation process was performed and the temperature of the tire G was measured. The results are shown in Table 1 below.
The reference temperature for determining whether or not the running process can be carried out was set to 120 ° C. In Example 1, since the tire temperature measured in the confirmation step was 120 ° C. or lower, the main running step was continued.
The traveling time in this traveling process was set to 20 minutes. After the main running step, a measuring step was performed, and the temperature and the amount of deviation of the tire G were measured. The results are shown in Table 1 below.
The tire B was also evaluated for the displacement of the tire with respect to the rim in the same manner as the tire G.

[Comparative Example 1]
The tire G and the tire B were evaluated for the displacement of the tire with respect to the rim in the same manner as in the first embodiment except that the running-in process was not performed.

[Example 2]
Tire G and Tire B were evaluated for tire displacement with respect to the rim in the same manner as in Example 1 except that the load was as shown in Table 1 below.

[Comparative Example 2]
The load and speed are as shown in Table 1 below, and the reference temperature for determining the feasibility of this traveling process is not set. , We evaluated the tire displacement with respect to the rim.

[Example 3]
Tire G and Tire B were evaluated for tire displacement with respect to the rim in the same manner as in Example 1 except that the load and speed were as shown in Table 1 below.
In this Example 3, since the temperature of the tire G measured in the confirmation step exceeded the reference temperature, the second break-in running step was performed with the load and speed as shown in Table 1 below.
Since the temperature of the tire G measured in the second confirmation step was 120 ° C. or lower, the main running step was continued. The load and speed in this running step were set in the same manner as in the second running-in step. After the main running step, a measuring step was performed, and the temperature and the amount of deviation of the tire G were measured.
As for tire B, as with tire G, the temperature of tire B measured in the confirmation step exceeded the reference temperature, so the second break-in step was performed with the load and speed as shown in Table 1 below.
Since the temperature of the tire B measured in the second confirmation step was 120 ° C. or lower, the main running step was continued. The load and speed in this running step were set in the same manner as in the second running-in step. After the main running step, a measuring step was performed, and the temperature and the amount of deviation of the tire B were measured.

[Effectiveness of evaluation]
The effectiveness of the evaluation was confirmed based on the amount of deviation measured in the measurement process. The case where the deviation of the tire with respect to the rim can be evaluated is [G], and the case where the evaluation cannot be made is [NG], which are shown in Table 1 below.

As shown in Table 1, in Comparative Example 1 in which the running-in process was not performed, no deviation with respect to the rim occurred even in the tire B. In Comparative Example 2 in which the reference temperature was not set, the temperature measured in the confirmation step exceeded 120 ° C., but since the main running step was performed as it was after the running-in running step, the tire B was damaged and the amount of deviation was reduced. I couldn't measure it. On the other hand, in the examples, a small amount of deviation was confirmed in the tire G in which the deviation with respect to the rim was unlikely to occur, and a large amount of deviation was confirmed in the tire B in which the deviation with respect to the rim was likely to occur. From this evaluation result, the superiority of the present invention is clear.

The technique described above that can accurately evaluate the displacement of a tire with respect to the rim at low cost can also be applied to the evaluation of various tires.

2 ... Tire 10 ... Tread surface 12 ... Test device 14 ... Drum 20 ... Running surface 22 ... Rotating shaft 24, 24a, 24b, 24c ... Hole 26 ... Side surface

Claims (7)

It is a method to evaluate the displacement of the tire with respect to the rim.
A break-in running process in which the tire is run for a predetermined time with a load applied to the tire assembled on the rim to generate heat.
A confirmation process that measures the temperature of the tire and confirms the heat generation state of the tire.
The main running step of further running the tire for a predetermined time to increase the displacement of the tire with respect to the rim.
Including a measurement step of measuring the amount of displacement of the tire with respect to the rim.
A reference temperature for determining whether or not the main traveling process can be carried out is set, and the reference temperature is set.
When the temperature of the tire measured in the confirmation step is equal to or lower than the reference temperature, the main running step is performed.
Tire evaluation method. The rim and the tire are marked to measure the amount of displacement of the tire with respect to the rim.
The tire evaluation method according to claim 1. A hole is made in the tire, and the temperature in the hole is measured as the temperature of the tire.
The tire evaluation method according to claim 1 or 2. A plurality of holes are drilled in the tire, and the plurality of holes have different depths.
The tire evaluation method according to claim 3. When the temperature of the tire measured in the confirmation step exceeds the reference temperature, the load is adjusted and the break-in running step is performed again.
The tire evaluation method according to any one of claims 1 to 4. When the main running process is performed a plurality of times, the interval from one main running process to the next main running process is 12 hours or more.
The tire evaluation method according to any one of claims 1 to 5. The tire is a pneumatic solid tire for industrial vehicles.
The tire evaluation method according to any one of claims 1 to 6.

Images