JP5089253B2 - Sound source identification device for tires - Google Patents

Description

  The present invention relates to an apparatus for specifying an abnormal sound source generated from a tire when a vehicle travels.

  The tire tread has many grooves. These grooves form a tread pattern on the tire. Noise is generated by rolling of the tire. Noise is generated when the tread collides with the road surface. Noise is also generated when the groove air is compressed. Noise gives driver discomfort. Tires with low noise are desired. Japanese Patent Application Laid-Open No. 10-90125 discloses a method for measuring tire noise.

  There is a tread pattern in which a single unit is repeated in the circumferential direction. There is also a tread pattern in which a plurality of units having different patterns are combined. In a tread pattern in which a plurality of units are combined, an abnormal sound due to the arrangement of the units may occur. This abnormal sound is particularly uncomfortable for the driver. This abnormal noise is generated when the vehicle travels at a specific speed. This abnormal sound has a specific frequency. The sound pressure of this abnormal sound is large. The abnormal sound source is unevenly distributed in the axial direction and the circumferential direction of the tire. The number of sound sources is usually one to several. Tires that are less prone to abnormal noise are desired.

In tire development, noise from prototype tires is measured. When abnormal noise is generated in the prototype tire, the tread pattern is improved. In order to improve the tread pattern, it is necessary to specify the sound source of the abnormal sound. For example, a part of the groove of the tread pattern is filled and noise measurement is performed again. If no abnormal sound is generated in the measurement again, the buried groove is the sound source.
JP 10-90125 A

  In specifying the sound source, trial and error are repeated. It takes a lot of time and labor to specify a sound source. There are also tread patterns where it is virtually impossible to specify the sound source. An object of the present invention is to provide an apparatus in which a sound source is specified reliably and easily.

The sound source identification device according to the present invention is
(1) A microphone for measuring the sound pressure of a specific frequency generated from a rotating tire,
(2) A rotation amount meter for measuring the rotation amount of the tire, and (3) a computer that associates the time axis data of the sound pressure with the time axis data of the rotation amount.

  Preferably, the device includes a plurality of microphones for continuously measuring the sound pressure of a specific frequency generated from the rotating tire. These microphones are arranged along the tire axial direction. In this apparatus, time axis data of the sound pressure distribution in the axial direction can be calculated.

  Preferably, the device comprises a number of microphones for continuously measuring the sound pressure of a specific frequency arising from the rotating tire. These microphones are arranged along the tire axial direction and the direction orthogonal to the axial direction. In this apparatus, time axis data of the sound pressure distribution in the axial direction and the direction orthogonal to the axial direction can be calculated.

  Preferably, the device further comprises an acoustic holography device. With this acoustic holography apparatus, image data of sound pressure distribution can be obtained.

The sound source identification method according to the present invention is:
(1) a step of measuring a sound pressure of a specific frequency generated from a rotating tire;
(2) Simultaneously with the measurement of the sound, the step of measuring the amount of rotation of the tire and (3) the rotation of the sound source of a specific frequency based on the correlation between the time axis data of the sound pressure and the time axis data of the rotation amount. Including a step in which a directional position is identified.

  In the device according to the present invention, the sound source of the abnormal sound can be reliably and easily specified by associating the time axis data of the sound pressure and the time axis data of the rotation amount.

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

  FIG. 1 is a conceptual diagram showing a sound source identification device 2 according to an embodiment of the present invention. The apparatus 2 includes a number of microphones 4, an acoustic holography apparatus 6, a rotary encoder 8 as a rotation amount meter, a computer 10, and a monitor 12. The microphone 4 is directional.

  FIG. 2 is a front view showing a sound source specifying method using the device 2 of FIG. 1, and FIG. 3 is a left side view thereof. 2 and 3, the tire 14, the rotating shaft 16, the drum 18, the microphone 4, and the rotary encoder 8 are shown. The tire 14 includes a tread 20. Although not shown, the tread 20 has a groove and a tread pattern is formed. The tire 14 is attached to the rotating shaft 16. The rotating shaft 16 is free. A predetermined load is applied to the tire 14 through the rotating shaft 16. The tread 20 is grounded to the drum 18. The microphone 4 is disposed near the ground plane of the tread 20. The microphone 4 is connected to the acoustic holography device 6 by a cable (not shown). The rotary encoder 8 is attached to the rotary shaft 16. The rotary encoder 8 is connected to the computer 10 by a cable (not shown).

  4A is a front view showing the microphone 4 of the device 2 of FIG. 1, and FIG. 4B is a left side view thereof. The device 2 includes 48 microphones 4. These microphones 4 are arranged in 12 rows from A to L. In each row, four microphones 4 from # 1 to # 4 are arranged. In Fig.4 (a), the left-right direction is an axial direction of the tire 14, and an up-down direction is a direction orthogonal to an axial direction. A large number of microphones 4 are arranged along the axial direction and the direction orthogonal to the axial direction.

  The microphone 4 includes a main body 22, an adapter 24, and a wind screen 26. The main body 22 is fixed to the adapter 24. The adapter 24 includes a hole 28. The wind screen 26 is porous and flexible. The wind screen 26 covers the main body 22. Since the interval between the adjacent main bodies 22 is small, the wind screen 26 is compressed and deformed. Therefore, there is no space between the adjacent wind screens 26.

  The tire 14 shown in FIGS. 2 and 3 generates abnormal noise. This abnormal sound is generated when the tire 14 travels at a specific speed. This abnormal sound has a specific frequency. The abnormal sound source can be identified by the apparatus 2 shown in FIGS. Hereinafter, a sound source specifying method will be described.

  The drum 18 is rotated in the direction of arrow A1 in FIG. 3 by a driving means (for example, a motor) not shown. As described above, since the tread 20 is in contact with the drum 18, the tire 14 is rotated in the direction of the arrow A2 by the rotation of the drum 18. The drum 18 is rotated so that the speed of the vehicle when the abnormal noise is generated matches the peripheral speed of the tire 14.

  As the tire 14 rotates, noise is generated on the ground contact surface. This noise is continuously measured by 48 microphones 4. The time axis data of noise in each microphone 4 is stored.

  As the tire 14 rotates, the rotating shaft 16 rotates. As the rotary shaft 16 rotates, the rotary encoder 8 also rotates. The rotary encoder 8 generates a pulse signal corresponding to the rotation angle (rotation amount). This pulse signal is sent to the computer 10. The pulse signal is stored as time axis data.

  The computer 10 associates the time axis data of the noise in each microphone 4 with the time axis data of the pulse signal. The computer 10 performs frequency analysis on noise data for each rotation angle. By this analysis, the sound pressure for each frequency is obtained. Thereby, sound pressure distribution for every rotation angle and every frequency is obtained. The sound pressure distribution can be displayed by, for example, isobaric lines. A large number of sound pressure distribution images are output to the monitor 12 in the order of the rotation angles. In other words, the sound pressure distribution is associated with the circumferential position of the tire 14.

  The monitor 12 allows the operator to know the point where the sound pressure is maximum. This point is an abnormal sound source. Since each image is associated with the circumferential position of the tire 14 as described above, the operator can know the circumferential position of the sound source. Further, the operator can know the axial position of the sound source. By grasping the circumferential position and the axial position, the operator can specify the sound source of the abnormal sound.

  FIG. 5 is an exploded plan view showing the microphone 4 of FIG. In FIG. 5, the left-right direction is the axial direction. In FIG. 5, two microphones 4 and a bar 30 are shown. The bar 30 is passed through the hole 28 of the adapter 24. The adapter 24 is slidable with respect to the bar 30. In FIG. 5, the wind screen 26 is separated from the main body 22.

  The wind screen 26 is inserted into the main body 22 as indicated by an arrow A3. Further, the microphone 4 is slid as indicated by an arrow A4. The adjacent wind screens 26 come into contact with each other by the slide. By further sliding, the wind screen 26 is compressed and deformed. Due to the deformation, no space is generated between the adjacent microphones 4 in the axial direction. Thereby, the collection of wind noise by the microphone 4 is suppressed. The wind screen 26 may be compressed by rotating the microphone 4.

  FIG. 6 is an exploded left side view showing the microphone 4 of FIG. In FIG. 6, the direction perpendicular to the paper surface is the axial direction. The adapter 24 is rotatable with respect to the bar 30. In FIG. 6, the wind screen 26 is separated from the main body 22.

  The wind screen 26 is inserted into the main body 22 as indicated by an arrow A5. Further, the microphone 4 is rotated as indicated by an arrow A6. The adjacent wind screens 26 come into contact with each other by the rotation. With further rotation, the wind screen 26 is compressed and deformed. Due to the deformation, no space is generated between the adjacent microphones 4 in the direction orthogonal to the axial direction. Thereby, the collection of wind noise by the microphone 4 is suppressed. The wind screen 26 may be compressed by sliding the microphone 4.

  In FIG. 4, what is indicated by an arrow P is the pitch between adjacent microphones 4. When the pitch P is excessively small, the sound collection range of one microphone 4 greatly overlaps with the sound collection range of the other microphone 4. Significant duplication hinders measurement accuracy. From the viewpoint of measurement accuracy, the pitch P is preferably 25 mm or more. In the future, if a microphone with better directivity than the current microphone 4 is developed, the pitch P can be set to less than 25 mm. Even if the pitch P is excessive, sufficient measurement accuracy cannot be obtained. From the viewpoint of accuracy, the pitch P is preferably 130 mm or less.

  The number of rows of the microphones 4 is determined in consideration of the width of the tread 20. Usually, the number of rows is preferably 3 or more, more preferably 5 or more, and particularly preferably 10 or more. In the example of FIG. 4, the number of columns is 12. In a tread having main grooves, the number of rows is preferably equal to or greater than the number of main grooves. The main groove is annular and extends in the circumferential direction of the tire 14. The axial width W (see FIG. 4) of the microphone group is preferably larger than the width of the tread 20.

  The number of microphones 4 per row is preferably 2 or more, more preferably 3 or more, and particularly preferably 4 or more. In the example of FIG. 4, this number is four.

  Hereinafter, the effects of the present invention will be clarified by examples. However, the present invention should not be construed in a limited manner based on the description of the examples.

  A tire 14 was prepared in which abnormal noise was generated when the vehicle speed was 80 km / h. The size of this tire is “225 / 55R17”. As a result of noise measurement based on a known method, the frequency of this abnormal sound was 630 Hz. The tread pattern of the tire 14 includes a combination of five units of USS, US, UM, UL, and ULL shown in FIG. The left-right direction in FIG. 7 is the circumferential direction of the tire 14. These units have different circumferential lengths. The unit layout in this tread pattern is US, USS, USS, US, US, US, UM, UM, ULL, UL, UL, UL, UM, US, US, US, USS, USS, USS, US, US , UM, UL, UL, UL, UL, UM, US, US, USS, US, UM, UL, UM, USS, US, UL, ULL, ULL, UL, UM, US, US, US, UM, UL , UL, UL, US, USS, USS, US, UM, UM, UL, UL, UL, US, US, USS, USS, USS, US, UL, UL, UL, and UL. FIG. 8 shows a development view of a part of the tread pattern 32. The tread pattern 32 includes four main grooves 34, a large number of sub grooves 36, and a large number of sipings 38. The main groove 34 extends in the circumferential direction and is annular.

  The tire 14 was mounted on the apparatus 2 shown in FIGS. In the apparatus 2, “20 kHz Array Microphone” is used as the microphone 4. In this apparatus 2, “PULSE Non-Stationary STSF” manufactured by Brüel & Kjær is used as the acoustic holography apparatus 6. In the apparatus 2, “HP xw8200 / CT Workstation” manufactured by Hewlett-Packard Company is used as the computer 10.

 The drum 18 was rotated so that the peripheral speed of the tire 14 was 80 km / h. The sound signals measured by the 48 microphones 4 were transmitted to the acoustic holography device 6. In this acoustic holography device 6, based on the pulse signal of the rotary encoder 8, frequency analysis was performed every 1 ° at the rotation angle of the tire 14. By this analysis, image data of sound pressure distribution with a frequency of 630 Hz was obtained. An average value was obtained based on image data during 10 revolutions of the tire 14. An image obtained by this average value was displayed on the monitor 12. On the monitor 12, 360 still image images were continuously displayed. These images were observed, and an image showing the maximum sound pressure was selected. This image is shown in FIG.

  FIG. 9 shows isobars from 93 dB to 100 dB. From FIG. 9, it was found that the sound pressure of the abnormal sound is on the order of 100 dB. From FIG. 9, it was found that the position of the sound source in the axial direction is an intermediate point between the microphone 4 in the E row and the microphone 4 in the F row. FIG. 9 further shows the rotation angle of the tire 14 when this image is obtained. The rotation angle from the reference was 51 °. From this rotation angle, it was found that the circumferential position of the abnormal sound source was 51 ° from the reference. The sound source was identified by identifying the axial position and the circumferential position. In this example, the siping indicated by reference numeral 38X in FIG. 8 is an abnormal sound source. The siping 38X is present at a place where three shortest units USS are continuous.

  Another tire in which the shape of the siping 38X was changed was manufactured. This tire was mounted on the apparatus 2 shown in FIGS. 1 to 6 and an image when the rotation angle was 51 ° was displayed. This image is shown in FIG. FIG. 10 shows the isobaric line from 93 dB to 96 dB. As apparent from FIG. 10, the maximum value of the sound pressure was 96 dB. In this tire, no abnormal noise due to the siping 38X is generated.

  With the apparatus according to the present invention, the sound source of abnormal sound can be specified in various tires.

FIG. 1 is a conceptual diagram illustrating a sound source identification device according to an embodiment of the present invention. FIG. 2 is a front view showing a sound source identification method using the apparatus of FIG. FIG. 3 is a left side view showing a sound source specifying method using the apparatus of FIG. 4 (a) is a front view showing the microphone of the apparatus of FIG. 1, and FIG. 4 (b) is a left side view thereof. FIG. 5 is an exploded plan view showing the microphone of FIG. FIG. 6 is an exploded left side view showing the microphone of FIG. FIG. 7 is a developed view showing a tire unit used in the method according to the embodiment of the present invention. FIG. 8 is a development view showing a part of the tread pattern of the tire of FIG. 7. FIG. 9 is a schematic diagram showing an image of the sound pressure distribution displayed by the apparatus of FIG. FIG. 10 is a schematic diagram showing an image of the sound pressure distribution displayed by the apparatus of FIG.

Explanation of symbols

2 ... Sound source identification device 4 ... Microphone 6 ... Acoustic holography device 8 ... Rotary encoder 10 ... Computer 12 ... Monitor 14 ... Tire 16 ... Rotating shaft 18 ... drum

Claims (5)

A microphone for measuring the sound pressure of a specific frequency generated from a rotating tire,
A rotation amount measuring instrument for measuring the rotation amount of the tire, and a sound source specifying device for a tire comprising a computer for associating the time axis data of the sound pressure and the time axis data of the rotation amount. It is equipped with a plurality of microphones for continuously measuring the sound pressure of a specific frequency generated from the rotating tire,
These microphones are lined up along the tire axial direction,
The apparatus according to claim 1, wherein the time axis data of the sound pressure distribution in the axial direction can be calculated. It is equipped with a number of microphones for continuously measuring the sound pressure of a specific frequency generated from a rotating tire,
These microphones are arranged along the tire axial direction and the direction orthogonal to the axial direction,
The apparatus according to claim 2, wherein the time axis data of the sound pressure distribution in the axial direction and a direction orthogonal to the axial direction can be calculated.   The apparatus according to claim 3, further comprising an acoustic holography device, wherein the acoustic holography device obtains image data of the sound pressure distribution. The step of measuring the sound pressure of a specific frequency arising from the rotating tire;
Simultaneously with the measurement of the sound, the circumferential position of the sound source of the specific frequency is specified based on the step of measuring the rotation amount of the tire and the correlation between the time axis data of the sound pressure and the time axis data of the rotation amount. A sound source identification method including steps.

Images