JP4263400B2 - Road friction coefficient estimation method and road friction coefficient estimation device - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to a device for estimating the running state of a tire during running and the state of a road surface on which the tire is grounded.
[0002]
[Prior art]
In order to improve the running stability of an automobile, it is required to accurately estimate the state of the tire during traveling and the road surface state where the tire is in contact with the ground and feed it back to the vehicle control. Here, the tire state includes tire internal pressure, wear, prediction of failure, and the like, and the road surface state mainly indicates a friction coefficient (road surface friction coefficient μ) between the road surface and the tire.
If the tire running condition and road surface condition can be estimated in advance, for example, before stopping the car and inspecting it before the tire breaks down, or before performing a risk avoidance operation such as braking / driving or steering, It is expected that more advanced control and the like will be possible, and safety will be further enhanced. In addition, simply telling the driver the degree of danger of the road surface condition while driving allows the driver to perform an early deceleration operation, and can reduce the number of accidents.
Conventionally, as a method of estimating the road surface friction coefficient, a method of estimating the road surface friction coefficient by utilizing the fact that the uniformity level of the tire, which is a physical quantity representing the fluctuation of the rotational speed of the wheel, varies depending on the magnitude of the road surface friction coefficient. (Japanese Patent Laid-Open No. 2000-55790), an accelerometer is attached to the lower arm that connects the front wheel and the vehicle body, and the lateral vibration of the tire having a toe angle is detected, and the vibration level varies depending on the road surface friction coefficient. A method of estimating the road surface friction coefficient using Japanese Patent Application Laid-Open No. 6-258196 has been proposed.
[0003]
[Problems to be solved by the invention]
However, in the method of estimating the road surface friction coefficient from the uniformity level of the tire, a flat spot is generated in the tire, the uniformity is deteriorated, and accurate estimation is difficult in the process of recovery.
On the other hand, in the method of estimating the road surface friction coefficient from the lateral vibration of the front wheel with the toe angle, the measurement accuracy is low when the tire slip angle is completely zero or when the tire has a large slip angle. There was a problem.
Further, a method for estimating a road surface friction coefficient from a transmission characteristic between an unsprung acceleration that is an acceleration in the vertical direction of a wheel and an unsprung acceleration that is an acceleration in the vertical direction of a vehicle body has been proposed (Japanese Patent Laid-Open No. 11-94661). Publication). Since this method does not use steering force to estimate the road surface friction coefficient, there is an advantage that the road surface friction coefficient can be estimated even on a straight road where steering is hardly performed, but there is a buffer characteristic such as a spring or a damper. Since the road surface friction coefficient is estimated from the transmission characteristics of vibrations between two points via a large suspension device, there is a problem that the road surface is easily affected by unevenness of the road surface. For example, on rough roads such as on snow, the vibration below the spring increases, so the vibration level difference between the vibration on the spring that is absorbed by the suspension and the vibration below the spring increases. The road friction coefficient could not be estimated accurately.
[0004]
The present invention has been made in view of conventional problems, and accurately estimates the road surface state where the tire is in contact with the ground and the traveling state of the tire at a constant speed when operation such as braking / driving is not applied, It aims at improving the running safety of vehicles.
[0005]
[Means for Solving the Problems]
  As a result of a detailed examination of the ground contact behavior of a running tire and the tire behavior at the time of failure, the present inventors have obtained a frequency analysis of the circumferential vibration or the widthwise vibration of the running tire. In addition, it is understood that the vibration level in one or a plurality of frequency bands of the vibration frequency spectrum (vibration spectrum) changes characteristically depending on the condition of the road surface on which the tire is in contact with the ground and the failure mode of the tire. did.
  Therefore, such vibration is caused as a minute change on the time axis of the tire itself, the vibration of the wheel or suspension transmitted from the tire, or the pressure of the gas (usually air) filled in the tire. As a result of the detection, it has been found that the road surface condition and the tire running condition can be accurately estimated, and the present invention has been achieved.
  That is, the road surface according to claim 1.Coefficient of frictionIn the estimation method, vibration detection means is attached to the tire or the hub of the wheel or suspension to detect the vibration of the tire of the vehicle running at a constant speed or the vibration of the tire transmitted to the hub of the wheel or suspension. Of the vibration spectrum obtained by frequency analysisSliding vibration level of tread surface in frequency range of 800-5000HzRoad surface when traveling at a constant speedCoefficient of frictionIt is characterized by estimating.
[0009]
  The road surface according to claim 2Coefficient of frictionThe estimation method detects a vehicle speed, detects a tire pattern pitch frequency from the detected vehicle speed data, detects a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum, When the detected vibration level exceeds a certain threshold value, it is estimated that the road surface is in a hydroplaning state.
  The road surface according to claim 3.Coefficient of frictionThe estimation method detects a vehicle speed, detects a tire pattern pitch frequency from the detected vehicle speed data, detects a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum, and The vibration level in the frequency band not affected by the pattern pitch frequency is obtained, and when the ratio of the vibration level in the pattern pitch frequency band with respect to this exceeds a certain threshold, it is estimated that the road surface is in the hydroplaning state. It is characterized by that.
[0010]
  The invention according to claim 4 is the road surface at the time of constant speed driving.Coefficient of frictionThis is a device that estimates the vibration of the tire of a vehicle running at a constant speed or the vibration of the tire transmitted to the hub of the wheel or suspension. Obtained by frequency analysis of the detected vibration and the detected vibrationvibrationOut of spectrumSliding vibration level of tread surface in frequency range of 800-5000HzFrom the detected vibration level and the road surface when traveling at a constant speedCoefficient of frictionAnd a means for estimating.
[0011]
  The invention according to claim 5 is the road surface according to claim 4.Coefficient of frictionAn estimation device, a means for detecting a vehicle speed, a pattern pitch frequency calculating means for detecting a tire pattern pitch frequency from the detected vehicle speed data, and a frequency including the pattern pitch frequency of the vibration spectrum Hydroplaning vibration level detection means for detecting the vibration level of the band and a hydroplaning vibration estimation means for estimating that the road surface is in a hydroplaning state when the vibration level detected by the hydroplaning vibration level detection means exceeds a certain threshold value. And a planing state estimating means.
[0012]
  The invention according to claim 6 is the road surface according to claim 4.Coefficient of frictionAn estimation device, a means for detecting a vehicle speed, a means for detecting a tire pattern pitch frequency from the detected vehicle speed data, and a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum Level ratio calculating means for calculating a vibration level in the frequency band that is not affected by the pattern pitch frequency and calculating a ratio of the vibration level in the pattern pitch frequency band with respect to this, and a threshold value at which the level ratio is constant The vehicle is characterized by comprising a hydroplaning state estimating means for estimating that the road surface is in a hydroplaning state when the road surface is exceeded.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to the drawings.
Embodiment 1 FIG.
  FIG. 1 is a functional block diagram of a road surface state and tire running state estimating device 10 according to the first embodiment, in which 11 is a pressure sensor provided in the tire,
Reference numeral 12 includes a frequency band setting unit 13 and a vibration level detection unit 14, which is a minute fluctuation component on the time axis of the output of the pressure sensor 11, which is a pressure fluctuation signal of gas in the tire detected by the pressure sensor 11. AC component) is subjected to frequency analysis, and the frequency range of the pressure fluctuation frequency spectrum (hereinafter referred to as the pressure fluctuation spectrum) is characteristically changed in vibration level depending on the road surface condition and the tire running condition, that is, at least 10 to 10.5000A frequency analyzing means 15 for detecting a vibration level in a frequency band included in the Hz range, 15 is a road surface condition obtained in advance, or a condition of a running tire and a pressure fluctuation level (hereinafter referred to as pressure fluctuation) in a predetermined frequency band. Pressure fluctuation level storage means for storing a G-table 15G indicating the relationship with the G-table 15G. The pressure fluctuation level storage means 16 stores the G-table 15G indicating the relationship with the G-table 15G. It is a road surface state and tire running state estimating means for estimating the inside road surface state and the running tire state.
  The G-table 15G has a pressure sensor 11 attached to a test vehicle, and the vehicle is driven on a road surface having a different road surface condition (road surface friction coefficient μ) at a predetermined speed V, for example, a part of a tread. It is created by running a vehicle equipped with a prototype tire corresponding to the failed tire that has been peeled off, and measuring the pressure fluctuation of the gas in the tire.
[0014]
In this example, as shown in FIGS. 2 (a) and 2 (b), the pressure sensor 11 is attached to a substrate 17 on which circuit components such as a detection circuit are mounted, and the wheel rim 2 of the wheel 1 has a recess on the tire side. In addition, the wheel side (rolling side) A and the non-rolling side vehicle body side B are wirelessly connected as shown in FIG.
The wheel side A includes a pressure sensor 11, a data processing unit 21 that digitally converts and compresses the pressure fluctuation signal of the gas filled in the tire detected by the pressure sensor 11, and this compression signal is transmitted to the vehicle body side B. An RF (Radio Frequency) unit 22 that transmits wirelessly is provided. Further, the vehicle body side B includes a receiving unit 23 that receives the compression signal, a frequency analysis by restoring the received compression signal, and a road surface state and a tire traveling state during traveling from the obtained pressure fluctuation spectrum. A road surface state and tire running state calculation unit 24 for estimating The road surface state and tire running state calculation unit 24 includes the frequency analysis unit 12, the pressure fluctuation level storage unit 15, and the road surface state and tire running state estimation unit 16.
Thereby, without providing a signal connection line, the pressure fluctuation signal detected by the wheel part on the rolling side can be processed on the vehicle body side B to estimate the road surface condition and the tire running condition.
[0015]
  Next, the operation of the road surface state and tire running state estimation device 10 having the above-described configuration will be described by taking as an example the case of obtaining an estimated value of the road surface friction coefficient μ.
  First, the pressure fluctuation of the gas filled in the running tire is detected by the pressure sensor 11, and the frequency analysis means 12 performs frequency analysis to detect the pressure fluctuation level in a predetermined frequency band. Specifically, the pressure fluctuation level detected by the frequency analysis means 12 is such that the center frequency has a frequency range in which the vibration level characteristically changes depending on the road surface condition and the tire running condition, that is, at least 10 to 10.5000A pressure fluctuation level of a frequency band having a predetermined bandwidth in the range of Hz, for example, a pressure fluctuation level of one frequency band having a relatively wide bandwidth such as 800 to 3500 Hz, or 800 Pressure fluctuation levels (plurality) in a plurality of frequency bands having a relatively narrow bandwidth, such as pressure fluctuation levels at ˜1000 Hz, 1600 to 2000 Hz, 3000 to 3500 Hz, and the like may be used. In the frequency analysis means 12, the one or more frequency bands are set by the frequency band setting means 13, and the vibration level detection means 14 detects the vibration level.
  The detected vibration level is sent to the road surface condition and tire running condition estimating means 16, and the road surface condition and tire running condition estimating means 16 detects the pressure fluctuation level (frequency band of pressure fluctuation) in the detected predetermined frequency band. Value) and a G-table 15G indicating the relationship between the road surface friction coefficient μ stored in the pressure fluctuation level storage means 15 and the frequency band value of the pressure fluctuation in advance, and an estimated value (μ estimation) of the road surface friction coefficient By calculating (value), the road surface condition (road surface friction coefficient μ) can be estimated with high accuracy.
[0016]
In addition, it is not an estimated value of the road surface friction coefficient μ, such as normal road surface conditions (dry), cautionary road surface conditions (wet road, snow road, etc.), dangerous road surface conditions (hydroplaning state, snow pressure road, mirror burn, etc.), etc. Such a road surface condition may be estimated.
Further, the slipperiness, which is the state of the running tire, may be estimated from the road surface friction coefficient μ.
It is also possible to estimate the failure state of the tire using the pressure fluctuation spectrum. Specifically, when peeling occurs in a part of the tire tread, a specific vibration is generated every time the part comes into contact with the road surface. Therefore, the pressure in the frequency band of 10 to 100 Hz of the pressure fluctuation spectrum is described. By detecting the fluctuation level and comparing it with the normal tire pressure fluctuation level, it is possible to estimate that some abnormality has occurred in the tire.
[0017]
Here, the frequency band f when the pressure fluctuation level used for estimating the road surface condition (road surface friction coefficient μ) by the frequency band setting means 13 is detected._iA setting method of (i = 1 to n) will be described.
First, the pressure sensor 11 is attached to a test vehicle, and the vehicle is driven on a road surface having a different road surface condition (road surface friction coefficient μ) at a predetermined speed V to obtain a tire pressure vibration spectrum. From the pressure vibration spectrum, At least one frequency band f_iFrequency band value x of pressure fluctuation at (i = 1 to n)_i(I = 1 to n) is detected, and the road surface friction coefficient estimated value (μ estimated value) is calculated using the following equation (1).
μ estimated value = 1 / [1 + exp {− (a₀+ A₁x₁+ A₂x₂+ ... + a_nx_n)}] (1)
Where a₀Constant, a₁, A₂, ..., a_n;coefficient
Then, a correlation coefficient between the μ estimated value calculated by the above formula (1) and the road friction coefficient μ measured in advance is obtained, and the plurality of frequency bands f are set so that the correlation coefficient becomes the highest._i(i = 1 to n) is set, and this set frequency band f_iFrom the pressure fluctuation level (i = 1 to n), the estimated value μ is calculated using the above equation (1).
Thus, the frequency band f for detecting the pressure vibration level for calculating the μ estimated value_i(I = 1 to n) is a frequency band f having a high correlation with the road surface friction coefficient μ._iIf (i = 1 to n) is set, the pressure fluctuation frequency band values x are simply compared by comparing the pressure fluctuation spectra obtained by running on different road surfaces._iMultiple frequency bands f_iAs compared with the case where the estimated value of μ is calculated by setting, the accuracy of the estimated value of μ can be improved with certainty.
At this time, the pressure fluctuation level x used to detect the road surface friction coefficient μ_iFrequency band f for detecting_iIs preferably 3 or more, but the frequency band f in which the road surface condition (the road surface friction coefficient μ) is reflected fairly clearly is shown._iIf there is, it is good also as one frequency band.
If only the road surface condition or the road surface friction coefficient μ is estimated, the pressure fluctuation level storage means 15 is omitted in the device 10, and the road surface condition and tire running state estimation means 16 uses the frequency analysis means 12. Frequency band value x of detected pressure fluctuation_iTherefore, the μ estimated value may be directly obtained using the above formula (1), or the road surface condition may be estimated using the μ estimated value.
[0018]
As described above, according to the first embodiment, the pressure sensor 11 is attached to the wheel rim 2 of the wheel 1 to detect the pressure of the gas filled in the tire of the running vehicle, and the detected pressure The minute vibration component (AC component) on the time axis of the signal is subjected to frequency analysis by the frequency analysis means 12 to detect the pressure fluctuation level of the pressure fluctuation spectrum, and this road surface condition and tire running condition estimation means 16 detects this pressure fluctuation level. The pressure fluctuation level is compared with the G-table 15G indicating the relationship between the road surface state and the tire running state stored in the pressure fluctuation level storage means 15, and the road surface friction coefficient μ and the failure state of the tire are estimated. Since it did in this way, a road surface state and the running state of a tire can be estimated accurately.
[0019]
In addition, since the tire internal pressure can be detected from the absolute value (DC component) of the output of the pressure sensor 11, the present apparatus 10 is used as the pressure sensor 11 of a tire internal pressure monitoring system that has been widely used in recent years. Can be used as they are. Therefore, cost increase due to hardware addition can be avoided and cost reduction can be achieved.
Further, by detecting the tire internal pressure by the pressure sensor 11, an abnormality in the tire internal pressure, which is one of the running conditions of the tire, can be estimated.
[0020]
  In the above example, the case where the pressure of the gas filled in the tire is detected to estimate the road surface state and the running state of the tire has been described. However, as shown in FIG. 3 is attached to the inner surface 4a of the tread 4 to directly detect tire vibration, and the vibration information signal detected by the acceleration sensor 19 is frequency-analyzed to obtain a vibration spectrum, and the same signal processing and calculation as in the above example are performed. Thus, the road surface condition and the tire running condition may be estimated.
  Alternatively, as shown in FIGS. 4B and 4C, the acceleration sensor 19 is attached to the wheel rim 2 or the suspension unit 5 to detect the vibration of the tire transmitted to the wheel 1 or the suspension unit 5, The road surface condition and the tire running condition may be estimated. Since the suspension unit 5 is provided with a plurality of elastic members such as rubber bushes 6 for vibration damping, in order to efficiently detect the transmitted tire vibration.In addition,Acceleration sensor 19ButIt is attached not to the suspension arms 5a and 5b but to the hub portion 7 to which the wheel 1 is attached.It is done.
[0021]
When the acceleration sensor 19 is used, it is necessary to separately measure the tire internal pressure. However, the vibration in the frequency band of 200 Hz or less of the vibration spectrum obtained by frequency analysis of the vibration information signal from the acceleration sensor 19 is required. From the level, it is possible to estimate the tire internal pressure by detecting the frequency of the natural vibration of the tire. In other words, since there is a high correlation between the tire natural vibration frequency and the actual tire internal pressure, the tire natural frequency is obtained from the vibration spectrum data, and the tire internal pressure is calculated from the relationship between the tire frequency and the tire internal pressure obtained in advance. And the estimated tire internal pressure may be used as the tire internal pressure.
[0022]
Further, a means for detecting the speed of the vehicle is provided, and a G-table 15G indicating the relationship between the road surface friction coefficient μ and the frequency band value of the pressure fluctuation for each vehicle speed is prepared. In addition to the data of the pressure fluctuation spectrum, the vehicle If the road surface condition and tire traveling state during traveling are estimated using the speed data, the estimation accuracy of the road surface state and tire traveling state can be further improved.
Furthermore, a load measuring device is installed on each wheel of the vehicle to detect the load acting on each wheel of the vehicle, and the road surface condition and the running state of the tire are estimated based on the load data of each wheel of the vehicle. Is also possible.
That is, in a vehicle such as a large transport vehicle in which the load applied to the wheel greatly fluctuates due to the weight of the load, the change in the coefficient of friction due to the load is large, so the tire vibration state changes due to the load (the load is (In order to correct this, the G-table 15G indicating the relationship between the road surface friction coefficient μ and the vibration level is created and stored for each load. If the road surface state and the tire running state are estimated according to the load data of each vehicle wheel detected by the load measuring device, the estimation accuracy can be further improved.
[0023]
<Example 1>
A pressure sensor 11 is attached to the test vehicle, and the vehicle is run on normal asphalt (dry asphalt) and slippery snow at V = 20 km / h, and the pressure fluctuation of the tire internal pressure is measured and the frequency analysis is performed. The result of obtaining the spectrum is shown in FIG. The horizontal axis of this graph is frequency, and the vertical axis is 2 × 10^-2The magnitude of the pressure fluctuation level when Pa is 0 dB. The thick solid line in the figure is dry asphalt, and the thin solid line is data on snow.
As shown in FIG. 5, it can be seen that on a snow that is slippery, the pressure fluctuation level is high in a high frequency region of 1000 Hz or higher. This is considered to be because, on slippery snow, the restraint from the road surface of the tread surface of the tire that is in contact with the road surface is reduced, and the tread surface generates sliding vibration and vibrates the gas inside the tire. .
In this way, if the correspondence between the pressure fluctuation level and the road friction coefficient μ is investigated, it is possible to estimate the road surface condition (road friction coefficient μ) by constantly monitoring the pressure fluctuation in the tire. It was confirmed that
This method can be similarly applied to tire vibration, wheel vibration, and suspension vibration.
[0024]
<Example 2>
In the same manner as in Example 1, the pressure fluctuation in the tire and the wheel vibration in various road surface conditions are measured, the estimated value μ is calculated using the above equation (1), and the actually measured road friction coefficient μ and The results of investigating the correlation are shown in FIG. 6 and FIG. At this time, the vibration level and pressure fluctuation level in the frequency band set by the method of the first embodiment were used as the vibration level and pressure fluctuation level used in the calculation of the μ estimated value.
In both cases of the pressure fluctuation in the tire and the wheel vibration, the estimated value of μ shows a high correlation with the road surface friction coefficient μ, and it was confirmed that the value of the road surface friction coefficient can be obtained with high accuracy. Similar results were obtained for tire vibration and suspension vibration.
[0025]
Embodiment 2. FIG.
In the first embodiment, the pressure fluctuation in the tire, tire vibration, wheel vibration, and suspension vibration are detected to estimate the road surface state and the tire running state. However, the above method is a slippery road surface state. The distinction between snowy roads and hydroplaning conditions is not clear.
As a result of examining the vibration spectrum or the pressure fluctuation spectrum in detail, when the hydroplaning state occurs, the inventors have determined that the vibration level or pressure near the primary frequency of the tire pattern pitch in the vibration spectrum or the pressure fluctuation spectrum. It was found that the fluctuation level increased characteristically.
Therefore, in this example, as shown in FIG. 8, a road surface condition and tire running condition estimation device 10 </ b> H in which the hydroplaning detection means 30 is added to the apparatus 10 of the first embodiment is configured, and the tire pattern pitch is determined. By detecting the vibration level or pressure fluctuation level in the vicinity of the primary frequency, the occurrence of the hydroplaning state can be estimated at the same time.
In FIG. 8, 31 is a vehicle speed detecting means for detecting the speed of the vehicle, 32 is a pattern pitch frequency calculating means for calculating the pattern pitch frequency from the vehicle speed data from the vehicle speed detecting means 31, and 33 is the frequency output of the pressure sensor 11. The second frequency analyzing means for analyzing the second frequency band setting means 34 provided in the second frequency analyzing means 33 changes the frequency band for detecting the pressure fluctuation level to a frequency band including the pattern pitch frequency. Then, the hydroplaning vibration level detection means 35 detects the pressure fluctuation level in the frequency band.
Reference numeral 36 denotes a hydroplaning state estimation means for estimating the occurrence of a hydroplaning state by comparing the detected pressure fluctuation level with a predetermined threshold value.
[0026]
In the hydroplaning detection means 30, first, using the vehicle speed data V detected by the vehicle speed detection means 31 in the pattern pitch frequency calculation means 32, the tire circumferential length L, and the block number n of the tread pattern, the following By equation (2), the pattern pitch frequency F_pIs calculated.
F_p(Hz) = V (km / h) x 1000 (m / km) ÷ 3600 (s / h) ÷ L (m) x n (2)
Then, the hydroplaning vibration level detecting means 35 of the second frequency analyzing means 33 uses the pattern pitch frequency F of the pressure fluctuation spectrum._pWhen the pressure fluctuation level in the frequency band corresponding to is detected, the detected pressure fluctuation level is compared with a predetermined threshold value by the hydroplaning state estimation means 36, and the pressure fluctuation level exceeds the threshold value. It is estimated that a hydroplaning condition has occurred.
Thereby, it is possible to clearly distinguish an icy and snowy road which is a slippery road surface state and a hydroplaning state.
In addition, if the said threshold value can be suitably changed, for example with the load etc. which act on each wheel of a vehicle, the estimation precision of a hydroplaning state can further be improved.
[0027]
In the second embodiment, the case where the pressure variation of the gas in the tire is detected and the hydroplaning state is estimated by the pressure sensor 11 has been described. However, the acceleration sensor 19 is used to estimate the tire, tread, and suspension vibration. It is also possible to estimate the hydroplaning state from the obtained vibration spectrum.
Also. In the above example, when the pattern pitch frequency band pressure fluctuation level exceeds a certain threshold, it is estimated that the tire is in the hydroplaning state. However, the vibration level or pressure in the frequency band that is not affected by the pattern pitch frequency. If the fluctuation level is obtained and the ratio of the vibration level or pressure fluctuation level in the pattern pitch frequency band to the fluctuation level exceeds a certain threshold value, it is assumed that the tire is in the hydroplaning state. The estimation accuracy can be further improved.
It is also possible to adopt a configuration in which the function of the second frequency analysis means 33 is provided to the frequency analysis means 12.
[0028]
<Example 3>
A pressure sensor was attached to the test vehicle, and the vehicle was run on a road with a water depth of 10 mm at V = 90 km / h. At this time, hydroplaning occurred, and it was in a dangerous state in which it was impossible to control the vehicle body by steering operation or braking operation.
In the above state, the pressure fluctuation in the tire was measured and subjected to frequency analysis, and the pressure fluctuation spectrum was obtained. As shown in FIG. 9, it was found that the vibration level around 900 to 1000 Hz was characteristically increased. It was.
Further, when a vibration sensor was attached to the test vehicle and the same experiment was performed to obtain a vibration spectrum, a peak of the vibration level was found in the same frequency band as in FIG. 9 as shown in FIG.
Here, the tire used for the test vehicle is a passenger car tire of 195 / 60R15 size, and the pitch frequency is calculated as follows using the above equation (2).
90 (km / h) x 1000 (m / km) ÷ 3600 (s / h) ÷ 1.885 (m) x 70 = 943Hz
That is, in the vicinity of 900 to 1000 Hz in FIGS. 9 and 10, the pressure fluctuation level and the vibration level are high because the water film between the tire tread and the road surface collides with the tread block. It can be seen that this is due to an increase in pressure fluctuation and vibration at the primary frequency. Thus, it was confirmed that the hydroplaning state can be estimated by detecting the fluctuation of the tire internal pressure of the tire exhibiting the above behavior or the vibration of the tire, wheel, and suspension.
[0029]
<Example 4>
An acceleration sensor is attached to the test vehicle, and the vehicle is run on a road with a depth of 10 mm and a dry asphalt road at different speeds to obtain a vibration spectrum, and the ratio of vibration levels in the following two frequency bands is calculated and plotted. The results are shown in FIG.
(Vibration level in the 900 to 1000 Hz band) / (Vibration level in the 100 to 200 Hz band)
In the case of a water depth of 10 mm, it has been found that the vibration level ratio increases abruptly when the vehicle speed exceeds 75 km / h. Therefore, if the threshold value is set to 0.3, the hydroplaning state can be reliably estimated.
[0030]
【The invention's effect】
  As described above, according to the present invention, vibration detected by attaching a vibration detection means to the tire or the hub of the wheel or suspension, or the vibration of the tire itself during traveling at a constant speed, or transmitted to the hub of the wheel or suspension. Frequency analysis of tire vibrations, and out of the obtained frequency spectrumSliding vibration level of tread surface in frequency range of 800-5000HzAnd detect the road surface from the detected vibration level.Coefficient of frictionThe road surface when driving at a constant speedCoefficient of frictionCan be estimated with high accuracy.
  Further, when the tire pattern pitch frequency is detected from the vibration spectrum data and the vehicle speed data, and the vibration level in the pattern pitch frequency band exceeds a certain threshold, the road surface is in a hydroplaning state. It is possible to reliably estimate the hydroplaning state. In addition, the vibration level in the frequency band not affected by the pattern pitch frequency is obtained, and when the ratio of the vibration level in the pattern pitch frequency band to this exceeds a certain threshold, it is estimated that the road surface is in the hydroplaning state. Thus, the estimation accuracy can be further improved.
[Brief description of the drawings]
FIG. 1 is a functional block diagram of a road surface state and tire traveling state estimation device according to a first embodiment of the present invention.
FIG. 2 is a diagram showing a mounting location of a pressure sensor.
FIG. 3 is a diagram illustrating a configuration example of the apparatus.
FIG. 4 is a diagram showing a place where an acceleration sensor is mounted.
FIG. 5 is a diagram showing a pressure fluctuation spectrum when a vehicle equipped with a pressure sensor is driven on a dry asphalt road and on snow.
FIG. 6 is a diagram showing a correlation between an actual road surface friction coefficient μ and an estimated value μ due to fluctuations in tire internal pressure.
FIG. 7 is a diagram showing a correlation between an actual road surface friction coefficient μ and an estimated μ value due to wheel vibration.
FIG. 8 is a diagram showing a configuration of a hydroplaning state estimation unit according to the second embodiment.
FIG. 9 is a diagram showing a pressure fluctuation spectrum in a hydroplaning state.
FIG. 10 is a diagram showing a vibration spectrum in a hydroplaning state.
FIG. 11 is a diagram showing a relationship between a vehicle speed and a ratio between a vibration level at a pattern pitch frequency and a vibration level in a 100 to 200 Hz band.
[Explanation of symbols]
1 wheel, 2 wheel rim, 3 tires, 4 tread, 4a inner surface side of the tread, 5 suspension part, 5a, 5b suspension arm,
6 rubber bush, 7 hub part, 10 road surface state and tire running state estimating device, 11 pressure sensor, 12 frequency analyzing means, 13 frequency band setting means,
14 pressure fluctuation level detection means, 15 pressure fluctuation level storage means, 15G G-table, 16 road surface condition and tire running state estimation means, 17 substrate, 18 sensor box, 19 acceleration sensor, 21 data processing section, 22 RF section,
23 receiving unit, 24 road surface condition and tire running state calculation unit,
30 hydroplaning detection means, 31 vehicle speed detection means, 32 pattern pitch frequency calculation means, 33 second frequency analysis means, 34 second frequency band setting means, 35 hydroplaning vibration level detection means, 36 hydroplaning state estimation means.

Claims (6)

A vibration detection means is attached to the hub of the tire or wheel or suspension to detect the vibration of the tire of the vehicle running at a constant speed or the vibration of the tire transmitted to the hub of the wheel or suspension, and this is the frequency. A road surface friction coefficient estimation method characterized by detecting a sliding vibration level of a tread surface in a frequency range of 800 to 5000 Hz in a vibration spectrum obtained by analysis, and estimating a road surface friction coefficient during traveling at a constant speed. The vehicle speed is detected, the tire pattern pitch frequency is detected from the detected vehicle speed data, and the vibration level in the frequency band including the pattern pitch frequency of the vibration spectrum is detected. 2. The road surface friction coefficient estimating method according to claim 1, wherein when the vibration level exceeds a certain threshold value, it is estimated that the road surface is in a hydroplaning state. A vehicle speed is detected, a tire pattern pitch frequency is detected from the detected vehicle speed data, a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum is detected, and the pattern pitch frequency is detected. The vibration level in the frequency band that is not affected by the vibration is obtained, and when the ratio of the vibration level in the above pattern pitch frequency band exceeds a certain threshold, it is estimated that the road surface is in the hydroplaning state. The road surface friction coefficient estimation method according to claim 1, wherein the road surface friction coefficient is estimated. A vibration detecting means for detecting vibration of a tire of a running vehicle, or vibration of a tire transmitted to a hub of a wheel or suspension, provided on a tire or a hub of a wheel or suspension; and the detected vibration Means for detecting a sliding vibration level of a tread surface in a frequency range of 800 to 5000 Hz out of a vibration spectrum obtained by frequency analysis, and means for estimating a road surface friction coefficient during constant speed traveling from the detected vibration level. A road surface friction coefficient estimating device. Means for detecting vehicle speed, pattern pitch frequency calculating means for detecting a tire pattern pitch frequency from the detected vehicle speed data, and detecting a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum. Hydroplaning vibration level detecting means, and hydroplaning state estimating means for estimating that the road surface is in a hydroplaning state when the vibration level detected by the hydroplaning vibration level detecting means exceeds a certain threshold value. The road surface friction coefficient estimating device according to claim 4, comprising: a road surface friction coefficient estimating device. Means for detecting vehicle speed; means for detecting a tire pattern pitch frequency from the detected vehicle speed data; and detecting a vibration level in a frequency band including the pattern pitch frequency of the vibration spectrum, and Level ratio calculating means for calculating a vibration level in the frequency band not affected by the pattern pitch frequency and calculating a ratio of the vibration level in the pattern pitch frequency band to this, and when the level ratio exceeds a certain threshold 5. The road surface friction coefficient estimating device according to claim 4, further comprising hydroplaning state estimating means for estimating that the road surface is in a hydroplaning state.

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