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JP2009040080A - Tire internal pressure drop detecting method and apparatus, and tire internal pressure drop detecting program - Google Patents

Tire internal pressure drop detecting method and apparatus, and tire internal pressure drop detecting program Download PDF

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JP2009040080A
JP2009040080A JP2007204097A JP2007204097A JP2009040080A JP 2009040080 A JP2009040080 A JP 2009040080A JP 2007204097 A JP2007204097 A JP 2007204097A JP 2007204097 A JP2007204097 A JP 2007204097A JP 2009040080 A JP2009040080 A JP 2009040080A
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vehicle
tire
internal pressure
dynamic load
load radius
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JP5069970B2 (en
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Mitsuhiro Wada
充浩 和田
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Sumitomo Rubber Industries Ltd
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Abstract

<P>PROBLEM TO BE SOLVED: To provide a tire internal pressure drop detecting method realizing quantitative correction of load-induced reduction of a dynamic load radius and accurate determination of a tire internal pressure drop. <P>SOLUTION: In the method, the tire dynamic load radius of a running vehicle is calculated to detect the tire internal pressure drop based on the magnitude of change of the obtained dynamic load radius from its reference value under a normal internal pressure. The method includes the steps of detecting wheel rotation information of each vehicle tire, calculating a wheel speed from the detected wheel rotation information, obtaining a vehicle speed, obtaining the dynamic load radius of each tire from the wheel speed and the vehicle speed, obtaining a vehicle mass, comparing the obtained vehicle mass with a vehicle mass under normal internal pressure and with no load mounted thereon to obtain a wheel load change amount of a predetermined tire to correct the reference value of the dynamic load radius of the predetermined tire based on the wheel load change amount, and determining the tire internal pressure drop when the magnitude of change of the obtained tire dynamic load radius from the corrected reference value exceeds a predetermined threshold value. At the vehicle mass obtaining step, with the vehicle running on a road surface of an inclined angle θ, the vehicle mass is obtained from an equation m(α+gsin(θ))+AV<SP>2</SP>=Fx=T/R wherein m is the vehicle mass, V is the vehicle speed, α is a vehicle acceleration, T is a vehicle axle shaft, Fx is fore and aft force, R is the tire load radius, θ is the road surface inclined angle, A is an aerodynamic drag and g is a gravity acceleration. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

本発明はタイヤ内圧低下検出方法及び装置、並びにタイヤ内圧低下検出プログラムに関する。   The present invention relates to a tire internal pressure drop detection method and apparatus, and a tire internal pressure drop detection program.

車両のタイヤの内圧低下を検出する方法として、従来、種々の方法が提案されており、例えば特許文献1には、車両の絶対速度と、タイヤの回転角速度との関係から走行中の車両のタイヤ動荷重半径を算出し、算出された動荷重半径が、予め正常内圧時の動荷重半径として記憶された初期値(基準値)よりも所定の程度だけ小さくなったときに、タイヤの内圧低下を警報する方法が開示されている。   Conventionally, various methods have been proposed as a method for detecting a decrease in the internal pressure of a tire of a vehicle. For example, Patent Document 1 discloses a tire of a running vehicle based on the relationship between the absolute speed of the vehicle and the rotational angular velocity of the tire. The dynamic load radius is calculated, and when the calculated dynamic load radius becomes smaller by a predetermined degree than the initial value (reference value) stored in advance as the dynamic load radius at the normal internal pressure, the internal pressure of the tire is reduced. A method for alarming is disclosed.

この特許文献1記載の方法では、タイヤ内圧の低下以外の原因によって警報が発せられるのを防止するために、車両の走行状態を限定(平坦路を一定速度で直進している走行状態に限定)し、かかる状態のときに得られた動荷重半径を有効値としてタイヤの内圧低下の検出に用いている。   In the method described in Patent Document 1, in order to prevent an alarm from being issued due to a cause other than a decrease in tire internal pressure, the traveling state of the vehicle is limited (limited to a traveling state in which a flat road is traveling straight at a constant speed). In addition, the dynamic load radius obtained in such a state is used as an effective value for detecting a decrease in the internal pressure of the tire.

特開2007−45295号公報JP 2007-45295 A

ところで、タイヤの動荷重半径は、車両が加速又は減速しているときや旋回しているとき以外にも、車両に搭乗する人や車両に搭載される物の荷重の大小や有無によっても変化することが知られているが、従来、荷重による動荷重半径の変化を考慮したものはなかった。特に後輪タイヤの場合、トランクに重い荷物を載せることが多く、荷重変動が大きいことから、タイヤの減圧判定を正確に行うのが困難である。   By the way, the dynamic load radius of a tire changes not only when the vehicle is accelerating or decelerating or turning, but also depending on the magnitude of the load on the person who rides on the vehicle or on the vehicle. However, there has been no conventional method that considers the change in the dynamic load radius due to the load. In particular, in the case of a rear wheel tire, a heavy load is often placed on the trunk, and the load fluctuation is large. Therefore, it is difficult to accurately determine the pressure reduction of the tire.

本発明は、このような事情に鑑みてなされたものであり、荷重による動荷重半径の減少を定量的に補正することができ、タイヤの内圧低下を正確に判定することができるタイヤ内圧低下検出方法及び装置、並びにタイヤ内圧低下検出プログラムを提供することを目的としている。   The present invention has been made in view of such circumstances, and it is possible to quantitatively correct a decrease in the dynamic load radius due to a load, and to detect a decrease in tire internal pressure accurately. It is an object of the present invention to provide a method and apparatus, and a tire internal pressure drop detection program.

本発明のタイヤ内圧低下検出方法は、走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出する方法であって、
前記車両の各タイヤの車輪回転情報を検出する工程と、
検出した車輪回転情報から車輪速度を算出する工程と、
車両速度を求める工程と、
前記車輪速度及び車両速度から各タイヤの動荷重半径を求める工程と、
前記車両の質量を求める工程と、
得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する工程と、
得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する工程と
を含んでおり、
前記車両質量を求める工程において、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めることを特徴としている。
The tire internal pressure drop detection method of the present invention calculates the tire dynamic load radius of a running vehicle, and based on the magnitude of change of the obtained dynamic load radius from the reference value of the dynamic load radius at normal internal pressure. A method for detecting a decrease in tire internal pressure,
Detecting wheel rotation information of each tire of the vehicle;
Calculating the wheel speed from the detected wheel rotation information;
Determining vehicle speed;
Obtaining a dynamic load radius of each tire from the wheel speed and vehicle speed;
Determining the mass of the vehicle;
A wheel load change amount of a predetermined tire is obtained by comparing the obtained vehicle mass with a normal internal pressure and a vehicle mass when no load is mounted, and based on the wheel load change amount, a reference for a dynamic load radius of the predetermined tire is obtained. Correcting the value;
A step of determining a decrease in the internal pressure of the tire when a magnitude of a change from the corrected reference value of the obtained tire dynamic load radius exceeds a predetermined threshold value, and
In the step of determining the vehicle mass, it is assumed that the vehicle is traveling on a road surface with an inclination angle θ, the vehicle mass is m, the vehicle speed is V, the vehicle acceleration is α, the axle shaft of the vehicle is T, and the longitudinal force is When Fx, tire load radius is R, road inclination angle is θ, aerodynamic resistance is A, and gravitational acceleration is g, m (α + gsin (θ)) + AV 2 = Fx = T / R
The vehicle mass is obtained by the following.

本発明のタイヤ内圧低下検出方法では、CAN(Control Area Network)情報である車両のアクスルシャフトトルク、例えばGPSから算出される車両速度、さらにはそこから算出される車両の加速度、車両が走行している路面の傾斜角αなどを用いて、車両質量を算出(推定)している。そして、この推定された車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により、所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正し、輪荷重による動荷重半径減少量を超えて動荷重半径が小さくなった場合にタイヤ内圧が低下していると判定している。すなわち、走行中の車両の質量を算出することにより、所定タイヤ(例えば、トランクに荷物を載せた場合における後輪タイヤ)について、輪荷重による動荷重半径の減少量を把握することができ、タイヤ内圧の低下により動荷重半径が減少した場合にのみ内圧低下の判定を行うことができる。これにより、誤警報を防止して、内圧低下の検出精度を向上させることができる。   In the tire internal pressure drop detection method of the present invention, the axle shaft torque of the vehicle, which is CAN (Control Area Network) information, for example, the vehicle speed calculated from GPS, the vehicle acceleration calculated therefrom, and the vehicle travels. The vehicle mass is calculated (estimated) using the inclination angle α of the road surface. Then, a wheel load change amount of a predetermined tire is obtained by comparing the estimated vehicle mass with a vehicle mass at a normal internal pressure and when no load is mounted, and based on the wheel load change amount, the movement of the predetermined tire is calculated. The reference value of the load radius is corrected, and it is determined that the tire internal pressure is reduced when the dynamic load radius becomes smaller than the decrease in the dynamic load radius due to the wheel load. That is, by calculating the mass of the running vehicle, the amount of decrease in the dynamic load radius due to the wheel load can be grasped for a predetermined tire (for example, a rear wheel tire when a load is placed on the trunk). Only when the dynamic load radius decreases due to a decrease in internal pressure, a determination of a decrease in internal pressure can be made. Thereby, a false alarm can be prevented and the detection accuracy of the internal pressure drop can be improved.

前記基準値を補正する工程において、予め求めておいたタイヤの輪荷重と動荷重半径との関係から得られる、動荷重半径の変化に対する輪荷重の寄与度を示す動荷重半径の荷重感度を用いて、基準値の補正を行うことができる。   In the step of correcting the reference value, the load sensitivity of the dynamic load radius indicating the contribution of the wheel load to the change of the dynamic load radius obtained from the relationship between the wheel load and the dynamic load radius of the tire obtained in advance is used. Thus, the reference value can be corrected.

また、本発明のタイヤ内圧低下検出装置は、走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出する装置であって、
前記車両の各タイヤの車輪回転情報を検出する車輪回転情報検出手段と、
検出した車輪回転情報から車輪速度を算出する車輪速度算出手段と、
車両速度を求める車両速度算出手段と、
前記車輪速度及び車両速度から各タイヤの動荷重半径を求める動荷重半径算出手段と、
前記車両の質量を求める車両質量算出手段と、
得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する基準値補正手段と、
得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する判定手段と
を含んでおり、
前記車両質量算出手段は、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めるように構成されていることを特徴としている。
In addition, the tire internal pressure drop detecting device of the present invention calculates the tire dynamic load radius of the running vehicle, and changes the magnitude of the obtained dynamic load radius from the reference value of the dynamic load radius at normal internal pressure. A device for detecting a decrease in tire internal pressure based on
Wheel rotation information detecting means for detecting wheel rotation information of each tire of the vehicle;
Wheel speed calculation means for calculating wheel speed from the detected wheel rotation information;
Vehicle speed calculation means for determining the vehicle speed;
A dynamic load radius calculating means for determining a dynamic load radius of each tire from the wheel speed and the vehicle speed;
Vehicle mass calculating means for determining the mass of the vehicle;
A wheel load change amount of a predetermined tire is obtained by comparing the obtained vehicle mass with a normal internal pressure and a vehicle mass when no load is mounted, and based on the wheel load change amount, a reference for a dynamic load radius of the predetermined tire is obtained. A reference value correcting means for correcting the value;
Determination means for determining a decrease in the internal pressure of the tire when the magnitude of a change in the tire dynamic load radius obtained from the corrected reference value exceeds a predetermined threshold,
The vehicle mass calculation means assumes that the vehicle is traveling on a road surface with an inclination angle θ, the vehicle mass is m, the vehicle speed is V, the vehicle acceleration is α, the axle shaft of the vehicle is T, and the longitudinal force is Fx. M (α + gsin (θ)) + AV 2 = Fx = T / R where R is the tire load radius, θ is the slope of the road surface, A is the aerodynamic resistance, and g is the acceleration of gravity.
The vehicle mass is obtained by the following.

さらに、本発明のタイヤ内圧低下検出プログラムは、走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出するためにコンピュータを、車両の各タイヤの車輪回転情報から車輪速度を算出する車輪速度算出手段、前記車輪速度及び車両速度から各タイヤの動荷重半径を求める動荷重半径算出手段、前記車両の質量を求める車両質量算出手段、得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する基準値補正手段、得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する判定手段として機能させ、且つ、前記車両質量算出手段が、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めるようにしたことを特徴としている。
Further, the tire internal pressure drop detection program according to the present invention calculates the tire dynamic load radius of the running vehicle, and changes the obtained dynamic load radius to the magnitude of change from the reference value of the dynamic load radius at normal internal pressure. Based on the wheel speed calculation means for calculating the wheel speed from the wheel rotation information of each tire of the vehicle, and the dynamic load for determining the dynamic load radius of each tire from the wheel speed and the vehicle speed. Radius calculation means, vehicle mass calculation means for determining the mass of the vehicle, a wheel load change amount of a predetermined tire is obtained by comparing the obtained vehicle mass with a vehicle mass at a normal internal pressure and when no load is mounted. Reference value correction means for correcting the reference value of the dynamic load radius of the predetermined tire based on the load change amount, and a large change from the corrected reference value of the obtained tire dynamic load radius. The vehicle mass calculation means is assumed to be running on a road surface with an inclination angle θ, and the vehicle mass calculation means Mass is m, vehicle speed is V, vehicle acceleration is α, vehicle axle shaft is T, longitudinal force is Fx, tire load radius is R, road slope is θ, aerodynamic resistance is A, and gravitational acceleration is g. Sometimes m (α + gsin (θ)) + AV 2 = Fx = T / R
The vehicle mass is obtained by the above.

本発明のタイヤ内圧低下検出装置及びタイヤ内圧低下検出プログラムでは、CAN情報である車両のアクスルシャフトトルク、例えばGPSから算出される車両速度、さらにはそこから算出される車両の加速度、車両が走行している路面の傾斜角αなどを用いて、車両質量を算出している。そして、この推定された車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により、所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正し、輪荷重による動荷重半径減少量を超えて動荷重半径が小さくなった場合にタイヤ内圧が低下していると判定している。すなわち、走行中の車両の質量を算出することにより、所定タイヤについて、輪荷重による動荷重半径の減少量を把握することができ、タイヤ内圧の低下により動荷重半径が減少した場合にのみ内圧低下の判定を行うことができる。これにより、誤警報を防止して、内圧低下の検出精度を向上させることができる。   In the tire internal pressure decrease detection device and the tire internal pressure decrease detection program of the present invention, the axle shaft torque of the vehicle, which is CAN information, for example, the vehicle speed calculated from GPS, the vehicle acceleration calculated therefrom, and the vehicle travels. The vehicle mass is calculated using the inclination angle α of the road surface. Then, a wheel load change amount of a predetermined tire is obtained by comparing the estimated vehicle mass with a vehicle mass at a normal internal pressure and when no load is mounted, and based on the wheel load change amount, the movement of the predetermined tire is calculated. The reference value of the load radius is corrected, and it is determined that the tire internal pressure is reduced when the dynamic load radius becomes smaller than the decrease in the dynamic load radius due to the wheel load. That is, by calculating the mass of a running vehicle, the amount of decrease in the dynamic load radius due to wheel load can be grasped for a given tire, and the internal pressure decreases only when the dynamic load radius decreases due to a decrease in tire internal pressure. Can be determined. Thereby, a false alarm can be prevented and the detection accuracy of the internal pressure drop can be improved.

本発明のタイヤ内圧低下検出方法及び装置、並びにタイヤ内圧低下検出プログラムによれば、荷重による動荷重半径の減少を定量的に補正することができ、タイヤの内圧低下を正確に判定することができる。   According to the tire internal pressure drop detection method and apparatus and the tire internal pressure drop detection program of the present invention, the decrease in the dynamic load radius due to the load can be corrected quantitatively, and the tire internal pressure drop can be accurately determined. .

以下、添付図面を参照しつつ、本発明のタイヤ内圧低下検出方法(以下、単に「検出方法」ともいう)及び装置(以下、単に「検出装置」ともいう)、並びにタイヤ内圧低下検出プログラムの実施の形態を詳細に説明する。
図1に示されるように、本発明の一実施の形態に係る検出装置は、4輪車両に備えられた4つのタイヤFL(左前輪)、FR(右前輪)、RL(左後輪)及びRR(右後輪)の車輪回転情報を検出するため、各タイヤに関連して設けられた通常の車輪速度検出手段(車輪回転情報検出手段)1を備えている。
Hereinafter, with reference to the accompanying drawings, a tire internal pressure drop detection method (hereinafter also simply referred to as “detection method”) and device (hereinafter also simply referred to as “detection device”), and a tire internal pressure drop detection program according to the present invention will be described. Will be described in detail.
As shown in FIG. 1, the detection apparatus according to an embodiment of the present invention includes four tires FL (left front wheel), FR (right front wheel), RL (left rear wheel), and In order to detect wheel rotation information of the RR (right rear wheel), normal wheel speed detection means (wheel rotation information detection means) 1 provided in association with each tire is provided.

前記車輪速度検出手段1としては、電磁ピックアップなどを用いて回転パルスを発生させてパルスの数から回転角速度及び車輪速度を測定するための車輪速センサ又はダイナモのように回転を利用して発電を行い、この電圧から回転角速度及び車輪速度を測定するためのものを含む角速度センサなどを用いることができる。前記車輪速度検出手段1の出力は、ABSなどのコンピュータである制御ユニット2に与えられる。この制御ユニット2には、内圧が低下したタイヤを知らせるための液晶表示素子、プラズマ表示素子又はCRTなどで構成された表示器3、ドライバーによって操作することができる初期化ボタン4、タイヤの内圧低下をドライバーに知らせる警報器5、及び車両速度算出手段を構成するGPS装置6が接続されている。   The wheel speed detection means 1 generates power using rotation like a wheel speed sensor or dynamo for generating rotation pulses using an electromagnetic pickup or the like and measuring the rotation angular speed and wheel speed from the number of pulses. It is possible to use an angular velocity sensor including that for measuring the rotational angular velocity and the wheel speed from this voltage. The output of the wheel speed detecting means 1 is given to a control unit 2 which is a computer such as ABS. The control unit 2 includes a liquid crystal display element for informing a tire whose internal pressure has decreased, a display 3 composed of a plasma display element or a CRT, an initialization button 4 that can be operated by a driver, and a decrease in tire internal pressure. Are connected to a GPS device 6 that constitutes a vehicle speed calculation means.

制御ユニット2は、図2に示されるように、外部装置との信号の受け渡しに必要なI/Oインターフェース2aと、演算処理の中枢として機能するCPU2bと、このCPU2bの制御動作プログラムが格納されたROM2cと、前記CPU2bが制御動作を行う際にデータなどが一時的に書き込まれたり、その書き込まれたデータが読み出されたりするRAM2dとから構成されている。なお、図2において、6aはGPSアンテナである。
前記車輪速度検出手段1では、タイヤの回転数に対応したパルス信号(以下、「車輪速パルス」ともいう)が出力される。また、CPU2bでは、車輪速度検出手段1から出力された車輪速パルスに基づいて、所定のサンプリング周期ΔT(sec)、例えばΔT=0.05秒毎に各タイヤの回転角速度が算出される。
As shown in FIG. 2, the control unit 2 stores an I / O interface 2a necessary for passing signals to and from an external device, a CPU 2b that functions as a center of arithmetic processing, and a control operation program for the CPU 2b. The ROM 2c and the RAM 2d from which data is temporarily written or the written data is read when the CPU 2b performs a control operation. In FIG. 2, 6a is a GPS antenna.
The wheel speed detection means 1 outputs a pulse signal corresponding to the number of rotations of the tire (hereinafter also referred to as “wheel speed pulse”). Further, the CPU 2b calculates the rotation angular velocity of each tire at a predetermined sampling period ΔT (sec), for example, ΔT = 0.05 seconds, based on the wheel speed pulse output from the wheel speed detecting means 1.

前記車両速度は、例えばGPS速度計を利用して得ることができる。カーナビゲーションの普及によりGPS装置が多くの車両に取り付けられるようになっている。このことでGPS装置による測位技術も向上し、現在では速度を算出することに特化した装置(英国Race Logic社製のGPS式速度計VBOX(商品名))も販売されている。かかるGPS情報を用いた速度計による算出速度を車両速度として利用することができる。なお、GPS装置により得られる車両の絶対速度以外に、例えば対地速度などの異なる方法で得られる車両の絶対速度を用いることができる。   The vehicle speed can be obtained using, for example, a GPS speedometer. With the widespread use of car navigation systems, GPS devices are attached to many vehicles. As a result, positioning technology using a GPS device has also been improved, and a device specialized in calculating speed (GPS speedometer VBOX (trade name) manufactured by Race Logic, UK) is now on the market. The speed calculated by the speedometer using such GPS information can be used as the vehicle speed. In addition, the absolute speed of the vehicle obtained by different methods, such as ground speed, can be used other than the absolute speed of the vehicle obtained by the GPS device.

本実施の形態に係る検出装置は、車輪速度検出手段(車輪回転情報検出手段)1と、検出された車両の各タイヤの車輪回転情報から車輪速度を算出する車輪速度算出手段と、車両速度を求めるGPS速度計と、車輪速度及び車両速度から各タイヤの動荷重半径を求める動荷重半径算出手段と、前記車両の質量を求める車両質量算出手段と、得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する基準値補正手段と、得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する判定手段とから構成されている。そして、タイヤ内圧低下検出プログラムは、前記制御ユニット2を、車輪速度算出手段、動荷重半径算出手段、車両質量算出手段、基準値補正手段及び判定手段として機能させる。   The detection device according to the present embodiment includes wheel speed detection means (wheel rotation information detection means) 1, wheel speed calculation means for calculating wheel speed from the detected wheel rotation information of each tire of the vehicle, and vehicle speed. GPS speedometer to be calculated, dynamic load radius calculating means for determining the dynamic load radius of each tire from wheel speed and vehicle speed, vehicle mass calculating means for determining the mass of the vehicle, obtained vehicle mass, and normal internal pressure And a reference value correcting means for obtaining a wheel load change amount of a predetermined tire by comparison with a vehicle mass when no load is mounted, and correcting a reference value of a dynamic load radius of the predetermined tire based on the wheel load change amount. And determining means for determining a decrease in the internal pressure of the tire when the magnitude of the change in the tire dynamic load radius from the corrected reference value exceeds a predetermined threshold value. The tire internal pressure drop detection program causes the control unit 2 to function as wheel speed calculation means, dynamic load radius calculation means, vehicle mass calculation means, reference value correction means, and determination means.

走行中の車両のタイヤ動荷重半径(R)は、車両の絶対速度(V)とタイヤの回転角速度(ω)との関係から、V=R×ωにより算出することができる。そして、タイヤ動荷重半径(R)はタイヤ内圧が低下するにしたがって減少することが知られており、このことを利用してタイヤの内圧低下をタイヤ動荷重半径(R)の減少から推定することができる。   The tire dynamic load radius (R) of the traveling vehicle can be calculated by V = R × ω from the relationship between the absolute speed (V) of the vehicle and the rotational angular velocity (ω) of the tire. The tire dynamic load radius (R) is known to decrease as the tire internal pressure decreases, and this is used to estimate the decrease in tire internal pressure from the decrease in tire dynamic load radius (R). Can do.

このタイヤ動荷重半径は、前述したようにタイヤ内圧の低下以外に、当該タイヤに作用する輪荷重によっても減少する。かかる輪荷重は、車両に搭乗する人や荷物の位置によって変動するが、本発明では、CAN情報である車両のアクスルシャフトトルク、例えばGPSから算出される車両速度、さらにはそこから算出される車両の加速度、車両が走行している路面の傾斜角αなどに基づき算出される車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により、所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて、タイヤが減圧しているか否かの判断基準となる動荷重半径の基準値を補正している。具体的には、輪荷重による動荷重半径減少分を加味した動荷重半径の基準値を設定している。なお、本明細書において「荷重非搭載時」とは、ドライバー以外の人や荷物が実質的に車両に搭載されていない状態、換言すればタイヤの動荷重半径に影響を及ぼし得る重量のものが搭載されていない状態のことをいう。   As described above, the tire dynamic load radius is reduced not only by a decrease in tire internal pressure but also by a wheel load acting on the tire. The wheel load varies depending on the position of the person or baggage on the vehicle. In the present invention, the vehicle axle shaft torque, which is CAN information, for example, the vehicle speed calculated from GPS, and the vehicle calculated from the vehicle speed. The amount of change in the wheel load of a given tire is obtained by comparing the vehicle mass calculated based on the acceleration of the vehicle, the inclination angle α of the road surface on which the vehicle is traveling, and the vehicle mass at normal internal pressure and when no load is mounted. Based on this wheel load change amount, the reference value of the dynamic load radius, which is a criterion for determining whether or not the tire is depressurized, is corrected. Specifically, a reference value of the dynamic load radius is set in consideration of the decrease in the dynamic load radius due to the wheel load. In this specification, “when the load is not mounted” means that a person other than the driver or the load is not substantially mounted on the vehicle, that is, a weight that can affect the dynamic load radius of the tire. It means the state where it is not installed.

以下、車両質量の算出手順及び動荷重半径の基準値の補正手順について、詳細に説明する。
[車両質量の算出]
傾斜角θの路面(坂道)を加速度αで走行中の車両に作用する車両前後方向の力のバランスを利用して、車両の全質量を推定することができる(図3参照)。すなわち、CAN情報である車両のアクスルシャフトトルクと、GPSから算出される速度、そこから算出される加速度、及び路面の傾斜角を用いて、以下の式(1)から車両質量mを算出することができる。
m(α+gsin(θ))+AV=Fx=T/R・・・・・・(1)
ここに、Tはアクスルシャフトトルク、Rはタイヤ負荷半径、Fxは前後力、gは重力加速度、Vは車両速度、Aは空力抵抗、αは車両加速度である。
Hereinafter, the procedure for calculating the vehicle mass and the procedure for correcting the reference value of the dynamic load radius will be described in detail.
[Calculation of vehicle mass]
The total mass of the vehicle can be estimated using the balance of forces in the vehicle front-rear direction acting on the vehicle traveling on the road surface (slope) with the inclination angle θ at the acceleration α (see FIG. 3). That is, the vehicle mass m is calculated from the following equation (1) using the vehicle axle shaft torque, which is CAN information, the speed calculated from the GPS, the acceleration calculated therefrom, and the inclination angle of the road surface. Can do.
m (α + gsin (θ)) + AV 2 = Fx = T / R (1)
Here, T is the axle shaft torque, R is the tire load radius, Fx is the longitudinal force, g is the gravitational acceleration, V is the vehicle speed, A is the aerodynamic resistance, and α is the vehicle acceleration.

θは車両が走行している路面の傾斜角であり、このθは、車両の平面速度をVxy(=V)、鉛直方向速度をVzとすると、θ=arctan(Vxy/Vz)で表され、また、車両加速度αはα=dVxy/dt/sinθで表される。
以上より、車両質量m及び空力抵抗Aを回帰にて算出することができる。
θ is an inclination angle of the road surface on which the vehicle is traveling, and θ is expressed by θ = arctan (Vxy / Vz) where Vxy (= V) is a plane speed of the vehicle and Vz is a vertical speed. The vehicle acceleration α is expressed by α = dVxy / dt / sin θ.
From the above, the vehicle mass m and the aerodynamic resistance A can be calculated by regression.

こうして求めた推定車両質量mと、基準時(ドライバー1名のみ乗車時)における推定車両質量との差から、所定タイヤにおける輪荷重の増加分を求めることができる。例えば、車両のトランクに荷物を載せた場合、この荷物による荷重は実質的に両後輪が負担することから、各後輪は前記差の2分の1だけ輪荷重が増加すると考えることができる。
なお、通常、助手席には人が乗り、またその荷重は重くともせいぜい100kg程度であるのに対して、後部座席及びトランクには合せて100〜300kg程度の荷重を載せる可能性があることから、後輪タイヤの方が前輪タイヤよりも荷重変動が大きいものと考えられる。したがって、車両質量の増加分を全て後輪タイヤが負担する、すなわち後輪タイヤの輪荷重が増加すると仮定しても、内圧低下の検出精度は向上するものと考えられる。この点について、本発明者は、種々の積載条件で車両の質量が増加したとき、この荷重の増分が全て後輪タイヤに乗ったと仮定し、別途求めた各輪の輪荷重実測値と比較した。その結果、車両質量の増加分が全て後輪タイヤの荷重増になると仮定したときの輪荷重実測値とのずれは、全く荷重増を考慮しなかったときの輪荷重実測値とのずれに比べて、前輪タイヤについては同程度であるが、後輪タイヤについては、荷重の増分が全て後輪タイヤに乗ったと仮定したときの方が、全く荷重増を考慮しなかったときよりも明らかにずれが小さくなることを確認している。このことから、車両質量の増分を全て後輪タイヤが負担すると仮定しても、内圧低下の検出精度が向上することが分かる。
From the difference between the estimated vehicle mass m thus obtained and the estimated vehicle mass at the reference time (when only one driver is in the vehicle), it is possible to obtain an increase in the wheel load on the predetermined tire. For example, when a load is placed on the trunk of a vehicle, the load due to this load is substantially borne by both rear wheels, so it can be considered that the wheel load of each rear wheel increases by one half of the difference. .
Normally, a passenger sits on the passenger seat and the load is about 100 kg at the maximum, but there is a possibility that a load of about 100 to 300 kg may be put on the rear seat and the trunk. The rear wheel tire is considered to have a larger load fluctuation than the front wheel tire. Therefore, even if it is assumed that the rear wheel tire bears all the increase in vehicle mass, that is, the wheel load of the rear wheel tire increases, it is considered that the detection accuracy of the internal pressure drop is improved. In this regard, the present inventor assumed that when the vehicle mass increased under various loading conditions, all of the load increments were on the rear wheel tire, and compared with the separately obtained wheel load actual measurement values for each wheel. . As a result, the deviation from the measured wheel load when all the increase in vehicle mass is assumed to be an increase in the load on the rear tire is compared to the deviation from the measured wheel load when no increase in load is taken into account. As for the front wheel tire, it is almost the same, but for the rear wheel tire, it is clear that the increase in load is assumed to have been on the rear wheel tire rather than the case where no increase in load is considered. Has been confirmed to be smaller. From this, it is understood that the detection accuracy of the internal pressure drop is improved even if it is assumed that the rear tires bear all the increments of the vehicle mass.

[動荷重半径の基準値の補正]
(1)補正に先立ち、該当タイヤの荷重による動荷重半径の減少量を実験により求め、初期値として把握しておく。具体的には、例えば車両装着予定のタイヤについてフラットベルトによる台上動荷重半径測定を行い、荷重による動荷重半径の減少量を測定する。基準荷重及び基準内圧のときの動荷重半径を基準としたときに、質量が1kg増加することで減少する動荷重半径、すなわち動荷重半径の質量感度(%/kg)を求める。なお、分子の単位が(%)であるのは、動荷重半径の減少を、(動荷重半径の変化量/基準荷重及び基準内圧のときの動荷重半径の値)で評価しているからである。
[Correction of standard value of dynamic load radius]
(1) Prior to correction, the amount of decrease in the dynamic load radius due to the load of the relevant tire is obtained by experiment and is grasped as an initial value. Specifically, for example, on a tire to be mounted on a vehicle, a table top dynamic load radius measurement is performed using a flat belt, and a reduction amount of the dynamic load radius due to the load is measured. Based on the dynamic load radius at the reference load and the reference internal pressure, the dynamic load radius that decreases as the mass increases by 1 kg, that is, the mass sensitivity (% / kg) of the dynamic load radius is obtained. The unit of the numerator is (%) because the decrease in the dynamic load radius is evaluated by (dynamic load radius change / value of the dynamic load radius at the reference load and reference internal pressure). is there.

(2)ついで、前述した「車両質量の算出」において求めた推定車両質量と基準時における推定車両質量との差から、所定タイヤの輪荷重の増加分を算出する。この増加分(kg)に、初期値として求めておいた動荷重半径の質量感度(%/kg)を乗じることで、荷重による動荷重半径の減少量(%)を算出することができる。例えば、車両のトランクに重い荷物を積載した場合、推定車両質量の増加分は、後輪タイヤが負担すると考えられるので、この後輪タイヤ(所定タイヤ)について動荷重半径の基準値の補正を行う。   (2) Next, an increase in the wheel load of the predetermined tire is calculated from the difference between the estimated vehicle mass obtained in the above-described “calculation of vehicle mass” and the estimated vehicle mass at the reference time. By multiplying the increase (kg) by the mass sensitivity (% / kg) of the dynamic load radius obtained as the initial value, the decrease (%) of the dynamic load radius due to the load can be calculated. For example, when a heavy load is loaded on the trunk of the vehicle, the increase in the estimated vehicle mass is considered to be borne by the rear wheel tire, so the dynamic load radius reference value is corrected for this rear wheel tire (predetermined tire). .

この減少量(%)を、100%から減じることにより、タイヤ内圧が低下しているか否かの判断基準となる動荷重半径の基準値を補正することができる。例えば、タイヤの輪荷重増加分が20kgであり、質量感度が0.003%/kgであるとすると、荷重による動荷重半径の減少量は20×0.003=0.06%となる。したがって、補正後の基準値は、100−0.06=99.4(%)となり、この基準値と、実測された動荷重半径とを比較してタイヤ内圧の低下を判定する。動荷重半径の減少から輪荷重の増加による減少分を引くことで、タイヤ内圧の低下による動荷重半径の減少であるか否かを正確に判定することができる。   By reducing this reduction amount (%) from 100%, it is possible to correct the reference value of the dynamic load radius, which is a criterion for determining whether or not the tire internal pressure is reduced. For example, if the increase in the wheel load of the tire is 20 kg and the mass sensitivity is 0.003% / kg, the amount of decrease in the dynamic load radius due to the load is 20 × 0.003 = 0.06%. Therefore, the corrected reference value is 100−0.06 = 99.4 (%), and a decrease in tire internal pressure is determined by comparing this reference value with the actually measured dynamic load radius. By subtracting the decrease due to the increase in the wheel load from the decrease in the dynamic load radius, it is possible to accurately determine whether or not the decrease is due to the decrease in the tire internal pressure.

[内圧低下検出方法]
以下、本発明の検出方法について説明する。
(1)まず、車輪速度検出手段1の出力信号(パルス信号)に基づいて、次の式(2)により各タイヤの回転角速度(ω)を算出する。
回転角速度(ω)=2π×Freq(Hz)/N(個)・・・・・(2)
ここに、Nは車輪速度検出手段1の車軸1回転あたりの歯数であり、Freq(Hz)は、その車輪速度検出手段1の歯が1秒あたりにカウントされた数値である。
[Internal pressure drop detection method]
Hereinafter, the detection method of the present invention will be described.
(1) First, based on the output signal (pulse signal) of the wheel speed detecting means 1, the rotational angular velocity (ω) of each tire is calculated by the following equation (2).
Rotational angular velocity (ω) = 2π × Freq (Hz) / N (pieces) (2)
Here, N is the number of teeth per one rotation of the axle of the wheel speed detecting means 1, and Freq (Hz) is a numerical value obtained by counting the teeth of the wheel speed detecting means 1 per second.

(2)一方、GPS速度計より車両速度(V)を求める。この車両速度(V)はシリアルデータとして直接制御ユニット2に出力される。なお、前記回転角速度(ω)の算出時刻と車両速度(V)の算出時刻のいずれか一方について、他方と同時刻での数値を内挿計算し、互いに同時刻での数値を算出して同期化を行い、例えば50msec毎のデジタルデータとして制御ユニット2に取り込むことができる。この50msec毎のデジタルデータから動荷重半径を50msec毎に算出し、例えば1秒毎の平均値として算出することができる。   (2) On the other hand, the vehicle speed (V) is obtained from the GPS speedometer. The vehicle speed (V) is directly output to the control unit 2 as serial data. For either one of the calculation time of the rotational angular velocity (ω) and the calculation time of the vehicle speed (V), the numerical value at the same time as the other is interpolated and the numerical values at the same time are calculated and synchronized with each other. For example, can be taken into the control unit 2 as digital data every 50 msec. The dynamic load radius is calculated every 50 msec from the digital data every 50 msec, and can be calculated, for example, as an average value per second.

(3)得られた回転角速度(ω)及び車両速度(V)から、R=V/ωによりタイヤ動荷重半径(R)を算出し、予め実車走行などにより設定しておいた基準荷重及び基準内圧のときの動荷重半径に対する比(%)を求める。   (3) From the obtained rotational angular velocity (ω) and vehicle speed (V), the tire dynamic load radius (R) is calculated by R = V / ω, and the reference load and the reference set in advance by actual vehicle running or the like. The ratio (%) to the dynamic load radius at internal pressure is obtained.

なお、タイヤ動荷重半径は、加減速、旋回、坂道走行など、タイヤの内圧低下以外の要因によっても変化することから、車両の走行状態を限定(平坦路を一定速度で直進している走行状態に限定)し、かかる状態のときに得られたデータを有効データとして採用するのが好ましく、こうして他の要因によるタイヤ動荷重半径の変化を内圧低下判定用のデータから排除することで、正確な内圧低下を判定することができる。
具体的には、走行条件が、定速度走行、平坦路走行、直線走行などの条件を満たすかどうかをそれぞれの判定条件と比較し、実際の走行中に得られたデータが基準値設定用のデータに適したデータであるかどうかの判定を行い、不適切なデータである場合は基準値設定用のデータとして使用せずに排除する。判定条件としては、例えば車両の前後方向|G|<0.05G、方位変化1度以下、路面勾配5%以下、ブレーキを踏んでいないこと、とすることができる。
The tire dynamic load radius also changes due to factors other than a decrease in tire internal pressure, such as acceleration / deceleration, turning, and running on a slope, so the vehicle's running condition is limited (running on a flat road at a constant speed) It is preferable to adopt the data obtained in such a state as valid data, and in this way, by excluding changes in the tire dynamic load radius due to other factors from the data for determining the internal pressure drop, A decrease in internal pressure can be determined.
Specifically, whether or not the driving condition satisfies conditions such as constant speed driving, flat road driving, and straight driving is compared with each judgment condition, and the data obtained during actual driving is used for setting the reference value. It is determined whether the data is suitable for the data. If the data is inappropriate, the data is excluded without being used as the reference value setting data. As the determination conditions, for example, the vehicle front-rear direction | G | <0.05G, the direction change is 1 degree or less, the road surface gradient is 5% or less, and the brake is not stepped on.

(4)ついで、前述した「車両質量の算出」における手順にしたがい推定車両質量を求め、この推定車両質量と基準時(ドライバー1名のみ乗車時)における車両総質量との差から、所定タイヤにおける輪荷重の増加分を求める。そして、得られた輪荷重の増加分と初期値として求めておいた動荷重半径の質量感度(%/kg)とから荷重による動荷重半径の減少量(%)を算出する。   (4) Next, an estimated vehicle mass is obtained according to the procedure in “Calculation of vehicle mass” described above, and the difference between the estimated vehicle mass and the total vehicle mass at the reference time (when only one driver is on board) Find the increase in wheel load. Then, the decrease amount (%) of the dynamic load radius due to the load is calculated from the obtained increase in the wheel load and the mass sensitivity (% / kg) of the dynamic load radius obtained as the initial value.

つぎに、この減少量(%)を、100%から減じることにより、タイヤ内圧が低下しているか否かの判断基準となる動荷重半径の基準値を補正する。
そして、補正された動荷重半径(%)と、実測された動荷重半径(%)とを比較することにより、タイヤ内圧が低下しているか否かを判定する。具体的には、前述した動荷重半径の質量感度(%/kg)を求める際に、併せて動荷重半径の減圧感度(内圧が1%減少することで減少する動荷重半径(%))を求めておき、実測された動荷重半径(%)と補正された動荷重半径(%)との差を、前記減圧感度(%/%)で除することで、基準内圧に対する減圧の程度(%)を求めることができる。得られた減圧の程度を閾値(例えば、30%)と比較し、当該閾値よりも減圧の程度が大きい場合には、タイヤ内圧が低下していると判断し、表示器3により減圧タイヤを表示するとともに、警報器5によりドライバーに警報を発する。
Next, by reducing this reduction amount (%) from 100%, the reference value of the dynamic load radius, which is a criterion for determining whether or not the tire internal pressure is reduced, is corrected.
Then, by comparing the corrected dynamic load radius (%) with the actually measured dynamic load radius (%), it is determined whether or not the tire internal pressure has decreased. Specifically, when determining the mass sensitivity (% / kg) of the dynamic load radius described above, the pressure reduction sensitivity of the dynamic load radius (dynamic load radius (%) that decreases when the internal pressure decreases by 1%) is also obtained. The degree of pressure reduction relative to the reference internal pressure (%) is determined by dividing the difference between the actually measured dynamic load radius (%) and the corrected dynamic load radius (%) by the pressure reduction sensitivity (% /%). ). The degree of decompression obtained is compared with a threshold value (for example, 30%). If the degree of decompression is greater than the threshold value, it is determined that the tire internal pressure has decreased, and the decompressed tire is displayed on the display 3. At the same time, the alarm 5 gives an alarm to the driver.

つぎに本発明の検出方法の実施例を説明するが、本発明はもとよりかかる実施例のみに限定されるものではない。
[実施例]
車両に装着された各タイヤの回転角速度を得るために、ABS制御に利用する回転速度情報を用いて、回転角速度に換算した。また、車両の絶対速度を得るためにVBOX(商品名。英国Race Logic社製GPS速度計)を車両に取り付けた。車両の速度は、シリアルデータとして直接PC(パーソナルコンピュータ)に出力され、この車両速度情報、前記回転速度情報及び車両のアクスルシャフトトルク情報を50msec毎にデジタルデータとして同期してPCに取り込めるようにした。そして、車両速度情報及び回転速度情報からタイヤ動荷重半径を50msec毎に計算し、1秒毎の平均値として算出した。
Next, examples of the detection method of the present invention will be described. However, the present invention is not limited to such examples.
[Example]
In order to obtain the rotational angular velocity of each tire mounted on the vehicle, the rotational angular velocity used for ABS control was converted into the rotational angular velocity. Further, in order to obtain the absolute speed of the vehicle, a VBOX (trade name, a GPS speedometer manufactured by Race Logic, UK) was attached to the vehicle. The vehicle speed is directly output to a PC (personal computer) as serial data, and the vehicle speed information, the rotation speed information, and the axle shaft torque information of the vehicle can be synchronously captured as digital data every 50 msec. . And the tire dynamic load radius was calculated every 50 msec from vehicle speed information and rotational speed information, and it calculated as an average value for every second.

[事前テスト]
フラットベルトによる台上動荷重半径測定を行い、該当タイヤの荷重及び減圧による動荷重半径の減少量を測定し、初期値として検出装置の記憶部に入力した。
基準荷重(3.5kN)及び基準内圧(210kPa)のときの動荷重半径を基準とし、質量(荷重)が1kg増加することで減少する動荷重半径、すなわち動荷重半径の質量感度(%/kg)、及び内圧が1%減少することで減少する動荷重半径、すなわち動荷重半径の減圧感度(%/%)を求めた。その結果、動荷重半径の質量感度(%/kg)は0.0029%/kgであり、減圧感度(%/%)は0.0172%/%であった。なお、分子の単位が(%)であるのは、動荷重半径の減少を、(動荷重半径の変化量/基準荷重及び基準内圧のときの動荷重半径の値)で評価しているからである。
[Pre-test]
The onboard dynamic load radius was measured using a flat belt, and the amount of decrease in the dynamic load radius due to the load of the corresponding tire and reduced pressure was measured and input as an initial value to the storage unit of the detection device.
Based on the dynamic load radius at the standard load (3.5 kN) and the standard internal pressure (210 kPa), the dynamic load radius that decreases as the mass (load) increases by 1 kg, that is, the mass sensitivity of the dynamic load radius (% / kg) ), And the dynamic load radius that decreases when the internal pressure decreases by 1%, that is, the pressure reduction sensitivity (% /%) of the dynamic load radius. As a result, the mass sensitivity (% / kg) of the dynamic load radius was 0.0029% / kg, and the reduced pressure sensitivity (% /%) was 0.0172% /%. The unit of the numerator is (%) because the decrease in the dynamic load radius is evaluated by (dynamic load radius change / value of the dynamic load radius at the reference load and reference internal pressure). is there.

[実車テスト]
4WD車にタイヤ(215/45R17 SP9000)を装着して、以下の4つのケースについて住友ゴム工業株式会社の岡山テストコースにおいて実車テストを行った。
ケース1:基準内圧(前輪:230kPa、後輪:210kPa)で1名乗車。本発明に
おける、正常内圧及び基準荷重(又は基準時)に該当する。
ケース2:後輪を30%減圧(前輪:230kPa、後輪:147kPa)させ
て1名乗車。
ケース3:基準内圧(前輪:230kPa、後輪:210kPa)で1名乗車。さらに、
トランクに190kgのウェイトを搭載。
ケース4:ケース3において、後輪を30%減圧(前輪:230kPa、後輪:147kPa)させた。
[Real car test]
Tires (215 / 45R17 SP9000) were mounted on a 4WD vehicle, and the following four cases were tested in actual vehicles at the Okayama test course of Sumitomo Rubber Industries, Ltd.
Case 1: 1 person rides at standard internal pressure (front wheel: 230 kPa, rear wheel: 210 kPa). In the present invention
It corresponds to normal internal pressure and reference load (or reference time).
Case 2: Reduce the pressure of the rear wheel by 30% (front wheel: 230 kPa, rear wheel: 147 kPa)
One person rides.
Case 3: One passenger rides at a standard internal pressure (front wheel: 230 kPa, rear wheel: 210 kPa). further,
190kg weight on the trunk.
Case 4: In case 3, the rear wheel was decompressed by 30% (front wheel: 230 kPa, rear wheel: 147 kPa).

まず、後輪タイヤの回転角速度及び車両速度から後輪タイヤの動荷重半径を算出し、基準時であるケース1における算出値(動荷重半径)に対する比(%)を求めた。結果を表1に示す。例えば、ケース2において、動荷重半径の実測値は99.48%であった。
ついで、ケース1〜4のそれぞれについて、前記式(1)にしたがって推定車両質量を求めた。図4は、ケース2における車両質量を推定するためのテスト結果をプロットした図であり、横軸は(α+gsinθ)であり、縦軸は(Fx−AV)である。前記式(1)より、プロットしたデータから求められる回帰直線の傾きが推定車両質量となる。図示した例の場合、回帰直線はy=1571xとなり、推定車両質量は1571(kg)となった。同様にして、ケース1、ケース3及びケース4の推定車両質量は、それぞれ1578(kg)、1758(kg)及び1765(kg)となった。なお、表1における「車両総質量」は、実測により得られた車両質量である。
First, the dynamic load radius of the rear wheel tire was calculated from the rotational angular velocity of the rear wheel tire and the vehicle speed, and the ratio (%) to the calculated value (dynamic load radius) in case 1, which is the reference time, was obtained. The results are shown in Table 1. For example, in case 2, the measured value of the dynamic load radius was 99.48%.
Subsequently, the estimated vehicle mass was calculated | required according to said Formula (1) about each of cases 1-4. FIG. 4 is a diagram in which test results for estimating the vehicle mass in case 2 are plotted, in which the horizontal axis is (α + g sin θ) and the vertical axis is (Fx−AV 2 ). From the equation (1), the slope of the regression line obtained from the plotted data is the estimated vehicle mass. In the case of the illustrated example, the regression line is y = 1571x, and the estimated vehicle mass is 1571 (kg). Similarly, the estimated vehicle masses of Case 1, Case 3, and Case 4 were 1578 (kg), 1758 (kg), and 1765 (kg), respectively. The “total vehicle mass” in Table 1 is a vehicle mass obtained by actual measurement.

Figure 2009040080
Figure 2009040080

ついで、ケース1で得られた推定車両質量を基準として、ケース2〜4のそれぞれについて、後輪タイヤの輪荷重の増減に対応させて当該後輪タイヤの動荷重半径の基準値の補正を行った。例えば、ケース2の場合、計算上、後輪タイヤの輪荷重が(1578−1571)/2=3.5(kg)減少していることから、動荷重半径の補正後の基準値は、3.5(kg)×0.0029(%/kg)≒0.01(%)大きくなり、100.01(%)となる。また、ケース3の場合、後輪タイヤの輪荷重が(1758−1578)/2=90(kg)増加していることから、動荷重半径の補正後の基準値は、90(kg)×0.0029(%/kg)≒0.26(%)小さくなり、99.74(%)となる。   Next, with respect to the estimated vehicle mass obtained in case 1, for each of cases 2 to 4, the reference value of the dynamic load radius of the rear wheel tire is corrected in accordance with the increase or decrease of the wheel load of the rear wheel tire. It was. For example, in case 2, since the wheel load of the rear tire is reduced by (1578-1571) /2=3.5 (kg) in calculation, the reference value after correcting the dynamic load radius is 3 .5 (kg) × 0.0029 (% / kg) ≈0.01 (%) is increased to 100.01 (%). In the case 3, since the wheel load of the rear tire is increased by (1758-1578) / 2 = 90 (kg), the reference value after correcting the dynamic load radius is 90 (kg) × 0. .0029 (% / kg) ≈0.26 (%) is reduced to 99.74 (%).

こうして求めた補正後の動荷重半径の基準値と、実測された動荷重半径との差を算出し、ついで、この差と、事前テストで求めておいた動荷重半径の減圧感度(%/%)とから各ケースの後輪タイヤの減圧値(%)を求める。例えば、ケース2の場合、測定された動荷重半径(99.48%)は、補正後の動荷重半径の基準値(100.01%)よりも0.53%小さい。したがって、減圧値は、0.53(%)÷0.0172(%/%)≒31(%)となる。また、ケース3の場合、測定された動荷重半径(99.72%)は、補正後の動荷重半径の基準値(99.74%)よりも0.02%小さい。したがって、減圧値は、0.02(%)÷0.0172(%/%)≒1(%)となる。他の場合についても同様にして後輪タイヤの減圧推定値を算出した。結果を表1に示す。   The difference between the corrected dynamic load radius reference value obtained in this way and the actually measured dynamic load radius is calculated, and then this difference and the reduced pressure sensitivity (% /%) of the dynamic load radius obtained in the preliminary test are calculated. ) And the decompression value (%) of the rear tire of each case. For example, in case 2, the measured dynamic load radius (99.48%) is 0.53% smaller than the corrected dynamic load radius reference value (100.01%). Therefore, the reduced pressure value is 0.53 (%) ÷ 0.0172 (% /%) ≈31 (%). In case 3, the measured dynamic load radius (99.72%) is 0.02% smaller than the corrected dynamic load radius reference value (99.74%). Accordingly, the reduced pressure value is 0.02 (%) ÷ 0.0172 (% /%) ≈1 (%). In the other cases, the estimated reduced pressure value of the rear tire was calculated in the same manner. The results are shown in Table 1.

実際の減圧値(ケース1及びケース3については0%であり、ケース2及び4については30%である)と、算出された減圧推定値との差が5%未満の場合を「良(OK)」とすると、ケース1〜4のすべての後輪タイヤについて「良(OK)」であった。   When the difference between the actual reduced pressure value (0% for cases 1 and 3 and 30% for cases 2 and 4) and the calculated estimated reduced pressure value is less than 5%, “good (OK) ) ", It was" OK "for all the rear wheel tires of cases 1-4.

[比較例]
タイヤ内圧を判定する際の動荷重半径の基準値について、荷重による減少分を考慮(補正)しなかった以外は、実施例と同様にして、推定減圧値を算出した。結果を表1に示す。
実際の減圧値(ケース1及びケース3については0%であり、ケース2及び4については30%である)と、算出された減圧推定値との差が5%未満の場合を「良(OK)」とすると、トランクに荷重を搭載したケース3及び4について、それぞれ実際よりも16%多く減圧したと推定され、「不良(NG)」であった。
以上より、荷重搭載による減圧減少分を考慮した、動荷重半径の基準値の補正を行うことにより、タイヤの内圧低下を正確に判定できることがわかる。
[Comparative example]
The estimated reduced pressure value was calculated in the same manner as in the example except that the decrease due to the load was not taken into account (corrected) for the reference value of the dynamic load radius when determining the tire internal pressure. The results are shown in Table 1.
When the difference between the actual reduced pressure value (0% for cases 1 and 3 and 30% for cases 2 and 4) and the calculated estimated reduced pressure value is less than 5%, “good (OK) ”), It was estimated that the cases 3 and 4 in which the load was loaded on the trunk were respectively decompressed by 16% more than the actual, and were“ bad ”(NG).
From the above, it can be seen that the decrease in the internal pressure of the tire can be accurately determined by correcting the reference value of the dynamic load radius in consideration of the reduced pressure reduction due to the load mounting.

本発明の検出装置の一実施の形態を示すブロック図である。It is a block diagram which shows one Embodiment of the detection apparatus of this invention. 図1に示される検出装置の電気的構成を示すブロック図である。It is a block diagram which shows the electrical structure of the detection apparatus shown by FIG. 傾斜角αの路面を走行する車両に作用する力を示す図である。It is a figure which shows the force which acts on the vehicle which drive | works the road surface of the inclination angle (alpha). 車両質量を推定するためのテスト結果をプロットした図である。It is the figure which plotted the test result for estimating vehicle mass.

符号の説明Explanation of symbols

1 車輪速度検出手段
2 制御ユニット
2a インターフェース
2b CPU
2c ROM
2d RAM
3 表示器
4 初期化ボタン
5 警報器
6 GPS装置
6a GPSアンテナ
1 Wheel speed detection means 2 Control unit 2a Interface 2b CPU
2c ROM
2d RAM
3 Display 4 Initialization Button 5 Alarm 6 GPS Device 6a GPS Antenna

Claims (4)

走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出する方法であって、
前記車両の各タイヤの車輪回転情報を検出する工程と、
検出した車輪回転情報から車輪速度を算出する工程と、
車両速度を求める工程と、
前記車輪速度及び車両速度から各タイヤの動荷重半径を求める工程と、
前記車両の質量を求める工程と、
得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する工程と、
得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する工程と
を含んでおり、
前記車両質量を求める工程において、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めることを特徴とするタイヤ内圧低下検出方法。
This is a method of calculating the tire dynamic load radius of a running vehicle and detecting the decrease in tire internal pressure based on the magnitude of change of the obtained dynamic load radius from the standard value of the dynamic load radius at normal internal pressure. And
Detecting wheel rotation information of each tire of the vehicle;
Calculating the wheel speed from the detected wheel rotation information;
Determining vehicle speed;
Obtaining a dynamic load radius of each tire from the wheel speed and vehicle speed;
Determining the mass of the vehicle;
A wheel load change amount of a predetermined tire is obtained by comparing the obtained vehicle mass with a normal internal pressure and a vehicle mass when no load is mounted, and based on the wheel load change amount, a reference for a dynamic load radius of the predetermined tire is obtained. Correcting the value;
Determining the decrease in internal pressure of the tire when the magnitude of change in the tire dynamic load radius obtained from the corrected reference value exceeds a predetermined threshold,
In the step of determining the vehicle mass, it is assumed that the vehicle is traveling on a road surface with an inclination angle θ, the vehicle mass is m, the vehicle speed is V, the vehicle acceleration is α, the axle shaft of the vehicle is T, and the longitudinal force is When Fx, tire load radius is R, road inclination angle is θ, aerodynamic resistance is A, and gravitational acceleration is g, m (α + gsin (θ)) + AV 2 = Fx = T / R
A method for detecting a decrease in tire internal pressure, characterized in that the vehicle mass is obtained by:
前記基準値を補正する工程において、予め求めておいたタイヤの輪荷重と動荷重半径との関係から得られる、動荷重半径の変化に対する輪荷重の寄与度を示す動荷重半径の荷重感度を用いて、基準値の補正が行われる請求項1に記載のタイヤ内圧低下検出方法。   In the step of correcting the reference value, the load sensitivity of the dynamic load radius indicating the contribution of the wheel load to the change of the dynamic load radius obtained from the relationship between the wheel load and the dynamic load radius of the tire obtained in advance is used. The method for detecting a decrease in tire internal pressure according to claim 1, wherein the reference value is corrected. 走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出する装置であって、
前記車両の各タイヤの車輪回転情報を検出する車輪回転情報検出手段と、
検出した車輪回転情報から車輪速度を算出する車輪速度算出手段と、
車両速度を求める車両速度算出手段と、
前記車輪速度及び車両速度から各タイヤの動荷重半径を求める動荷重半径算出手段と、
前記車両の質量を求める車両質量算出手段と、
得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する基準値補正手段と、
得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する判定手段と
を含んでおり、
前記車両質量算出手段は、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めるように構成されていることを特徴とするタイヤ内圧低下検出装置。
This is a device that calculates the tire dynamic load radius of a running vehicle and detects the decrease in tire internal pressure based on the magnitude of the change of the obtained dynamic load radius from the reference value of the dynamic load radius at normal internal pressure. And
Wheel rotation information detecting means for detecting wheel rotation information of each tire of the vehicle;
Wheel speed calculation means for calculating wheel speed from the detected wheel rotation information;
Vehicle speed calculation means for determining the vehicle speed;
A dynamic load radius calculating means for determining a dynamic load radius of each tire from the wheel speed and the vehicle speed;
Vehicle mass calculating means for determining the mass of the vehicle;
A wheel load change amount of a predetermined tire is obtained by comparing the obtained vehicle mass with a normal internal pressure and a vehicle mass when no load is mounted, and based on the wheel load change amount, a reference for a dynamic load radius of the predetermined tire is obtained. A reference value correcting means for correcting the value;
Determination means for determining a decrease in the internal pressure of the tire when the magnitude of a change in the tire dynamic load radius obtained from the corrected reference value exceeds a predetermined threshold,
The vehicle mass calculation means assumes that the vehicle is traveling on a road surface with an inclination angle θ, the vehicle mass is m, the vehicle speed is V, the vehicle acceleration is α, the axle shaft of the vehicle is T, and the longitudinal force is Fx. M (α + gsin (θ)) + AV 2 = Fx = T / R where R is the tire load radius, θ is the slope of the road surface, A is the aerodynamic resistance, and g is the acceleration of gravity.
A tire internal pressure drop detecting device, characterized in that the vehicle mass is obtained by the following.
走行中の車両のタイヤ動荷重半径を算出し、得られた動荷重半径の、正常内圧時における動荷重半径の基準値からの変化の大きさに基づいてタイヤの内圧低下を検出するためにコンピュータを、車両の各タイヤの車輪回転情報から車輪速度を算出する車輪速度算出手段、前記車輪速度及び車両速度から各タイヤの動荷重半径を求める動荷重半径算出手段、前記車両の質量を求める車両質量算出手段、得られた車両質量と、正常内圧であり且つ荷重非搭載時における車両質量との比較により所定タイヤの輪荷重変化量を求め、この輪荷重変化量に基づいて当該所定タイヤの動荷重半径の基準値を補正する基準値補正手段、得られたタイヤ動荷重半径の、前記補正された基準値からの変化の大きさが所定の閾値を超えた場合にタイヤの内圧低下を判定する判定手段として機能させ、且つ、前記車両質量算出手段が、車両が傾斜角θの路面を走行しているものとし、当該車両の質量をm、車両速度をV、車両加速度をα、車両のアクスルシャフトをT、前後力をFx、タイヤ負荷半径をR、路面の傾斜角をθ、空力抵抗をA、重力加速度をgとしたときに
m(α+gsin(θ))+AV=Fx=T/R
により車両質量を求めるようにしたことを特徴とするタイヤ内圧低下検出プログラム。
A computer for calculating a tire dynamic load radius of a running vehicle and detecting a decrease in the internal pressure of the tire based on a magnitude of a change of the obtained dynamic load radius from a reference value of the dynamic load radius at a normal internal pressure. A wheel speed calculating means for calculating a wheel speed from wheel rotation information of each tire of the vehicle, a dynamic load radius calculating means for calculating a dynamic load radius of each tire from the wheel speed and the vehicle speed, and a vehicle mass for determining the mass of the vehicle. The calculation means calculates the wheel load change amount of the predetermined tire by comparing the obtained vehicle mass with the normal internal pressure and the vehicle mass when the load is not mounted, and based on the wheel load change amount, the dynamic load of the predetermined tire is obtained. Reference value correction means for correcting the reference value of the radius, and when the magnitude of change of the obtained tire dynamic load radius from the corrected reference value exceeds a predetermined threshold, the internal pressure of the tire is reduced. The vehicle mass calculation means is assumed to be traveling on a road surface with an inclination angle θ, the vehicle mass is m, the vehicle speed is V, the vehicle acceleration is α, the vehicle M (α + gsin (θ)) + AV 2 = Fx = T where T is the axle shaft, Fx is the longitudinal force, R is the tire load radius, θ is the slope of the road, A is the aerodynamic resistance, and g is the gravitational acceleration. / R
A vehicle internal pressure drop detection program characterized in that the vehicle mass is determined by
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