JP3997861B2 - Air pressure warning device for vehicle tires - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
  The present invention relates to an air pressure alarm device for a vehicle tire, and more particularly to an air pressure abnormality alarm for a spare tire.
[0002]
[Prior art]
  Conventionally, in a tire pressure alarm device for a vehicle tire that incorporates a battery inside the tire to supply power to the tire air pressure detection unit, in order to extend the life of the battery, the transmission cycle of the detection information to the vehicle side is set to The detection information is transmitted at a cycle according to each situation, for example, the transmission cycle is shortened compared to when the vehicle is stopped when traveling or the transmission cycle is shortened compared to normal when the air pressure is abnormal. It is known to do. (For example, see Japanese National Publication No. 10-508264)
  In addition to tires that are mounted, it is known to monitor and alarm the air pressure of spare tires installed in the trunk of a vehicle.
[0003]
  For example, in Japanese Patent No. 3061047, for five tires including spare tires, tire identification codes ID are registered together with their mounting positions, and an alarm level corresponding to the degree of decrease in air pressure is set as an initial value of tire air pressure. It is disclosed that the alarm is set to three levels: an alarm indicating a drop, an alarm indicating a tire puncture, and an alarm indicating that the tire air is completely removed and the air pressure is zero.
[0004]
  According to such a prior art, the air pressure state of the tires registered including the spare tire is monitored, and when an abnormality is detected by lowering the normal air pressure value by a predetermined amount, along with the mounted position information, An alarm corresponding to the abnormal level can be notified to the driver.
[0005]
[Problems to be solved by the invention]
  By the way, normally, since the spare tire is used frequently enough to be replaced in the event of a failure such as puncture, the life cycle used is often longer than that of a normal traveling tire.
[0006]
  Moreover, the main cause of the decrease in the air pressure of the spare tire is that air gradually escapes in the natural state, and the tendency of the air pressure to decrease is moderate compared to a traveling tire that is mounted on a vehicle and receives various disturbances.
[0007]
  In view of such a situation, it is considered that the spare tire may monitor the air pressure less frequently than the traveling tire.
[0008]
  However, the above-described prior art has not been sufficiently designed in consideration of the situation unique to the spare tire, and sufficient measures are not necessarily taken from the viewpoint of improving the battery life of the pneumatic sensor mounted on the spare tire. There wasn't.
[0009]
  Further, it is considered that the alarm for the abnormality in the air pressure of the spare tire that is not attached to the vehicle is relatively less urgent than the traveling tire in view of the risk to the driver.
[0010]
  Therefore, for a spare tire that is not mounted on the vehicle, starting the alarm from the initial drop in air pressure as in the case of the traveling tire makes the driver feel bothered.
[0011]
  The present invention has been made in consideration of the above-described problems. The object of the present invention is to improve the battery life of a pneumatic sensor attached to a spare tire and to bother the driver by an early warning of the spare tire. An object of the present invention is to provide an air pressure alarm device for a tire for a vehicle that makes it possible to suppress this problem.
[0012]
[Means for Solving the Problems]
  In order to achieve the above object, the present invention has the following method for solving it. That is, in the first configuration of the present invention, a first air pressure sensor that is attached to each traveling tire of the vehicle and detects tire air pressure information of the traveling tire;
  A second air pressure sensor that is mounted on a spare tire stored in the spare tire storage unit and detects tire air pressure information of the spare tire; and
  An alarm device for alarming abnormal air pressure of each traveling tire and spare tire of the vehicle;
  A control unit that receives tire pressure information from each of the air pressure sensors and causes the alarm device to warn of an abnormal air pressure of the vehicle tire;
  Each air pressure sensor includes a battery unit for supplying power to each unit in the sensor, a transmitter for transmitting detected tire air pressure information, and a transmission cycle setting unit for setting a transmission cycle from the transmitter. Is provided,
  The second air pressure sensor includes a vehicle mounting state determination unit that determines whether or not the spare tire is mounted on the vehicle.
  The transmission cycle setting unit of the first air pressure sensor sets the transmission cycle to the first transmission cycle when the vehicle is running, and sets the transmission cycle to the first transmission cycle when the vehicle is stopped. It is configured to set a second transmission period longer than the transmission period,
  When the transmission period setting unit of the second air pressure sensor is determined to be in a non-mounted state by the vehicle mounting state determining unitThe third transmission period is longer than the second transmission period.And when it is determined that it is in a worn state, The transmission cycleThe transmission cycle is set to the same transmission cycle as that of the first air pressure sensor.
[0013]
  According to the first configuration of the present invention, the tire air pressure information transmission cycle by the spare tire air pressure sensor is set longer than the tire air pressure information transmission cycle by the traveling tire air pressure sensor. The battery life of the air pressure sensor can be improved.
[0014]
  When a spare tire is stored in the spare tire storage section, it has a low influence on running performance, so it is possible to set a longer air pressure transmission cycle. When the tire is replaced with a spare tire and the spare tire is mounted on the vehicle as a traveling tire, it is necessary to transmit the air pressure to the control unit at a cycle as short as the traveling tire for safety.
[0015]
  According to the first configuration of the present invention, the transmission period of the tire pressure information by the spare tire pressure sensor is determined from the transmission period of the traveling tire when it is detected that the spare tire is not attached to the vehicle. Is set to a long cycle, and when it is detected that the spare tire is attached to the vehicle, the transmission cycle is set to be the same as the transmission cycle of the traveling tire. When the spare tire is attached to the vehicle, tire pressure information can be transmitted in the same short transmission cycle as the traveling tire. Therefore, safety can be ensured when the spare tire is installed.
[0016]
  In the second configuration of the present invention, an air pressure sensor that is mounted on a spare tire stored in each traveling tire and spare tire storage portion of the vehicle and detects tire air pressure information;
  An alarm device for alarming abnormal air pressure of each traveling tire and spare tire of the vehicle;
  A control unit for causing the alarm to warn of abnormal air pressure,
  In the first air pressure sensor mounted on each of the traveling tires, a tire identification information storage unit in which tire identification information is stored,
  A transmitter for transmitting tire identification information stored in the tire identification information storage unit together with detected tire pressure information; and
  In the second air pressure sensor attached to the spare tire, a tire identification information storage unit in which tire identification information is stored,
  A vehicle mounting state determination unit for determining whether or not the spare tire is mounted on the vehicle;
  A transmitter for transmitting the spare tire mounting state determined by the vehicle state determination unit together with tire identification information stored in the tire identification information storage unit and detected tire air pressure information; and
  The control unit includes a receiver for receiving signals from the first and second air pressure sensors,
  A spare tire discriminating unit for discriminating whether or not the tire identification information included in the signal received by the receiver is tire identification information indicating a spare tire;
  An appropriate air pressure storage unit for storing the appropriate air pressure of the tire;
  Judgment that determines the tire pressure state based on the relationship between the difference between the tire air pressure detected by the first and second air pressure sensors and the appropriate air pressure stored in the appropriate air pressure memory and the determination threshold value. And
  An alarm control unit for causing the alarm to warn of an abnormal air pressure when the determination unit determines an excess or deficiency state from the appropriate air pressure;
  A determination threshold value setting unit for setting a determination threshold value in the determination unit,
  The determination threshold value setting unit sets the determination threshold value for the spare tire to be smaller than the determination threshold value for the traveling tire when the vehicle mounting state determination unit determines that the vehicle is not mounted. When the determination threshold is set to the same as the determination threshold for the traveling tire, and the air pressure of the traveling tire is reduced to the vicinity of the determination threshold, the spare tire is not attached. The determination threshold value for the spare tire in the state is corrected to be increased.
[0017]
  According to the second configuration of the present invention, since the determination threshold value for the spare tire is set lower than the determination threshold value for the traveling tire, the air pressure alarm is set until the air pressure of the spare tire is lower than that of the traveling tire. Therefore, the troublesomeness to the driver due to the early warning of the spare tire having a low impact on safety can be suppressed.
[0018]
  When a spare tire is stored in the spare tire storage section, it has a low influence on running performance, so it is possible to set a longer air pressure transmission cycle. When the tire is replaced with a spare tire and the spare tire is mounted on the vehicle as a traveling tire, it is necessary to transmit the air pressure to the control unit at a cycle as short as the traveling tire for safety.
[0019]
  According to the second configuration of the present invention, when it is determined that the spare tire is not attached to the vehicle, the spare tire determination threshold is set lower than the traveling tire determination threshold, When it is determined that the tire is mounted on the vehicle, the spare tire determination threshold value is set to be the same as the traveling tire determination threshold value, so that if the spare tire is not mounted on the vehicle, the spare tire This can reduce the annoyance caused by the early warning, and when a spare tire is mounted on the vehicle, it can detect an abnormal air pressure as early as the traveling tire, Safety can be ensured.
[0020]
  When the air pressure of the running tire decreases to near the determination threshold, the possibility that it will be replaced with a spare tire is increased.
[0021]
  At this time, a situation is considered in which the air pressure of the spare tire has already decreased, and the alarm is not issued at the determination threshold for the spare tire, but the air pressure at which the alarm is issued at the determination threshold for the traveling tire is considered.
[0022]
  In the state where the air pressure of the spare tire is also reduced as described above, if the spare tire is subsequently replaced with the spare tire, it is determined that the spare tire is attached to the vehicle as the running tire. The determination threshold value is also changed to the determination threshold value for the running tire, and an abnormality in the air pressure of the spare tire is warned immediately after replacement, which gives the user a sense of incongruity.
[0023]
  According to the second configuration of the present invention, when the air pressure of the traveling tire decreases to near the determination threshold value, correction is made in the direction of increasing the determination threshold value of the spare tire, so that the spare tire is replaced before being replaced with the spare tire. Thus, it is possible to notify the driver of the abnormal air pressure, and to prevent the driver from feeling uncomfortable.
[0024]
  In the third configuration of the present invention, the determination threshold value setting unit may set a spare in the spare tire non-mounted state according to the air pressure value of the traveling tire when the air pressure of the traveling tire is lowered to the vicinity of the determination threshold value. The tire determination threshold is corrected so as to increase.
[0025]
【The invention's effect】
  ADVANTAGE OF THE INVENTION According to this invention, while being able to improve the battery life of the air pressure sensor with which the spare tire was mounted | worn, the troublesomeness with respect to the driver | operator by the early warning of a spare tire can be suppressed.
[0026]
DETAILED DESCRIPTION OF THE INVENTION
  Hereinafter, embodiments of the present invention will be described with reference to the drawings.
[0027]
  FIG. 1 is an overall configuration diagram. In FIG. 1, the vehicle 1 is provided with running tires 2 to 5, and the spare tire storage portion 13 of the vehicle 1 is provided with a spare tire 6.
[0028]
  The tires 2 to 6 are respectively provided with air pressure sensors 7 to 11. The air pressure sensors 7 to 11 detect tire air pressure information and output the tire air pressure information to the control unit 20.
[0029]
  The control unit 20 receives information from each of the air pressure sensors 7 to 11 via the antenna 12, and outputs the information to the alarm device 30 when an abnormality in the air pressure is determined.
[0030]
  (Embodiment 1)
  FIG. 2 is a control block diagram relating to the first embodiment. In the air pressure sensors 7 to 11, battery units 7a to 11a for supplying power to each part in the sensor and tire air pressures of the tires 2 to 6 are detected. Pressure detectors 7b to 11b, temperature detectors 7c to 11c for detecting the tire temperature, and a running state detector 7d for detecting the running state of the tire (tire rotation) attached to the vehicle 1 11d, storage units 7e to 11e for storing tire identification information, transmitters 7f to 11f for wirelessly transmitting the information detected by the detection units and the tire identification information to the control unit 20, and the control unit 20 Transmission cycle setting units 7g to 11g for setting a transmission cycle for transmission and central processing units 7h to 11h are provided. A plurality of transmission cycles are prepared in the transmission cycle setting units 7f to 11f, and the transmission cycle can be changed and set according to the detection results from the pressure detection units 7b to 11b and the traveling state detection units 7d to 11d. it can. For example, when an abrupt pressure drop is detected by the pressure detectors 7b to 11b, the air pressure information that changes every moment can be sequentially transmitted by setting a short transmission cycle. Further, the running state detection units 7d to 11d may be, for example, rotation sensors that detect the rotation of the tire. When rotation is not detected, the battery is set by setting a longer transmission cycle than when the rotation state is detected. The battery life of the part can be extended.
[0031]
  Further, the air pressure sensor 11 of the spare tire 6 is provided with a vehicle mounting state determination unit 11i, and the vehicle mounting state determination unit 11i is constituted by, for example, an inclination sensor that detects the posture state of the spare tire 6. .
[0032]
  The control unit 20 also includes a receiver 20a for receiving various information wirelessly transmitted from the air pressure sensors 7 to 11 from the antenna 12, various information received by the receiver 20a, and other various sensors. A central processing unit 20b that performs various processes such as a process of causing the alarm 30 to warn the tire air pressure state based on the detection information from 40, and a storage unit 20c for storing tire identification information of the own vehicle and appropriate air pressure. Is provided.
[0033]
  Next, specific control contents by the transmission cycle setting units 7g to 11g and the central processing units 7h to 11h of the air pressure sensors 7 to 11 according to the first embodiment will be described based on the flowchart of FIG.
[0034]
  In step S1 of FIG. 3, various signals such as the actually measured air pressure P, the tire temperature T, and the tire running state W detected by the detection units 7b to 11b, 7c to 11c, and 7d to 11d of the air pressure sensors 7 to 11 are read.
[0035]
  In subsequent step S2, it is determined whether or not the vehicle is in the running state based on the tire running state W detected by the running state detection units 7d to 10d of the air pressure sensors 7 to 10.
[0036]
  When YES is determined in step S2, the process proceeds to step S3, and the transmission cycle T1 in the transmission cycle setting units 7g to 10g is set to the transmission cycle t1 according to the traveling state.(First transmission cycle)Set to.
[0037]
  Moreover, when it determines with NO by step S2, it progresses to step S4 and the transmission cycle t2 longer than the transmission cycle t1 according to a stop state in the transmission cycle setting part 7g-10g is set to transmission cycle T1.(Second transmission cycle)Set to.
[0038]
  Here, the reason for setting the transmission cycle t2 in the stopped state to be longer than the transmission cycle t1 in the traveling state is that, in the stopped state, the effect on safety is low even if the tire pressure drop alarm is somewhat delayed, so the transmission cycle is set to This is to increase the battery life by increasing the length.
[0039]
  In subsequent step S5, it is determined whether or not the spare tire 6 is mounted on the vehicle.
[0040]
  When it is determined YES in step S5, that is, when the spare tire 6 is removed from the spare tire storage unit 13 and mounted as a traveling tire, the process proceeds to step S6.
[0041]
  In step S6, it is determined whether or not the vehicle is in the running state based on the tire running state W detected by the running state detection unit 11d of the air pressure sensor 11.
[0042]
  When it determines with YES by step S6, it progresses to step S7 and sets the transmission period T2 in the transmission period setting part 11g to the transmission period t1 according to a driving | running | working state.
[0043]
  Here, the transmission cycle t1 in the transmission cycle setting unit 11g is the same as the transmission cycle t1 in the transmission cycle setting units 7g to 10g set in step S3.
[0044]
  Moreover, when it determines with NO by step S6, it progresses to step S8, and sets the transmission period T2 in the transmission period setting part 11g to the transmission period t2 longer than the transmission period t1 according to a stop state.
[0045]
  Here, the transmission cycle t2 in the transmission cycle setting unit 11g is the same as the transmission cycle t2 in the transmission cycle setting units 7g to 10g set in step S4.
[0046]
  That is, since the spare tire 6 is used as a running tire when mounted on the vehicle, the same transmission cycle t1 or t2 as the running tires 2 to 5 is set for the spare tire 6 as well.
[0047]
  If NO is determined in step S5, that is, if the spare tire 6 is stored in the spare tire storage unit 13 and is not mounted as a traveling tire, the process proceeds to step S9.
[0048]
  In step S9, the transmission cycle in the transmission cycle setting unit 11g is set to the longest transmission cycle t3.(Third transmission cycle)Set to.
[0049]
  Here, the reason for making the transmission cycle the longest when the spare tire 6 is stored in the spare tire storage unit 13 and not installed in the vehicle is that the air pressure drop of the spare tire is slow and is attached to the vehicle. This is because the alarm urgency level is low and there is little influence even if an alarm for abnormal air pressure is given, so the transmission cycle is lengthened to improve the battery life of the air pressure sensor 11.
[0050]
  Then, when the transmission cycle is set in each of the above steps S3, S4, S7 to S9, the process proceeds to step S10, where the transmitters 7f to 10f of the air pressure sensors 7 to 10 are based on the set cycle T1. The transmitter 11f of the air pressure sensor 11 detects the tire air pressure, the tire temperature, and the tire running state based on the set cycle T2, and also controls the detected actual air pressure Po, the tire temperature T, and the tire running state W as a control unit. 20 and return.
[0051]
  Next, the operation of the first embodiment will be described based on the time chart of FIG.
[0052]
  In FIG. 4, when the vehicle 1 is in the running state and the running state of the tire is detected by the running state detection units 7d to 10d in the running tires 2 to 5, the transmitters 7f to 10f of the running tires 2 to 5 The transmission signal is transmitted at a period t1 as shown in FIG.
[0053]
  When the vehicle is stopped, the transmission signal of the traveling tire 2 is transmitted at a transmission cycle t2 that is longer than the transmission cycle t1 in the traveling state. During this time, the spare tire 6 is in the retracted state, and the vehicle mounted state determination unit 11i detects the non-mounted state of the spare tire 6 on the vehicle. Therefore, the transmission signal of the spare tire 6 is transmitted from the transmission cycles t1 and t2. It is transmitted with a long transmission cycle t3.
[0054]
  After that, when an abnormality in air pressure occurs in any of the traveling tires 2 to 5 and the traveling tire in which the abnormality in air pressure has occurred is replaced with the spare tire 6, this replacement state is determined by the vehicle mounting state determination unit 11i. The
[0055]
  After the tire replacement, when the vehicle is stopped, the transmission signal of the spare tire 6 is transmitted at the same transmission cycle t2 as the stopped state of the traveling tires 2 to 5, and when the vehicle is in the traveling state, The transmission signal of the tire 6 is transmitted at the same transmission cycle t1 as the traveling state of the traveling tires 2 to 5.
[0056]
  As described above, according to the first embodiment, when it is determined that the spare tire 6 is not attached to the vehicle, the transmission cycle of the spare tire 6 from the transmitter 11f is the traveling tire 2-2. Since the transmitters 7f to 11f of 5 are set to t3 that is longer than the transmission cycles t1 and t2, the life of the battery part 11a of the spare tire 6 can be improved while suppressing the influence on safety.
[0057]
  When it is determined that the spare tire 6 is mounted on the vehicle, the transmission cycle of the spare tire 6 from the transmitter 11f is set to the same short transmission cycle t1 or t2 as the traveling tires 2 to 5. Therefore, it is possible to deal with a situation where the alarm urgency is higher than that in the non-wearing state, and it is possible to achieve both improvement in battery life and ensuring safety.
[0058]
  (Embodiment 2)
  FIG. 5 is a control block diagram relating to the second embodiment. In contrast to the first embodiment, the control unit 20 is provided with a transmitter 20d for transmitting to the air pressure sensor and is transmitted to the air pressure sensors 7-11. The difference is that receivers 7i to 11i that receive signals from the control unit 20 are provided instead of the period setting units 7g to 11g.
[0059]
  Hereinafter, the difference will be specifically described. The transmitter 20d in the control unit 20 transmits a transmission request signal for requesting transmission of air pressure information to the air pressure sensors 7 to 11, and the air pressure sensors 7 to 11 receive the transmission requests received by the receivers 7i to 11i. In response to the signal, the detected actual air pressure Po, tire temperature T, and tire running state information W are transmitted. This transmission request signal includes the tire identification information of the host vehicle stored in the storage unit 20c in the control unit 20, and is stored in the storage units 7e to 11e in the central processing units 7h to 11h of the air pressure sensor. The measured air pressure Po, the tire temperature T, and the tire running state information W are returned to the control unit 20 only when the tire identification information is matched and matched. The tire identification information included in the transmission request signal of the control unit 20 may be one or plural. Since a reply from a plurality of air pressure sensors is made to a transmission request signal including a plurality of tire identification information, it is not necessary to transmit a transmission request signal for each tire, which is efficient.
[0060]
  In the second embodiment, the transmission cycle of the transmission signal of each air pressure sensor set in the first embodiment is set by controlling the transmission timing of the transmission request signal from the control unit 20 for each tire.
[0061]
  Next, specific control contents of the transmission request signal processing by the control unit 20 according to the second embodiment will be described based on the flowchart of FIG.
[0062]
  In step S20 of FIG. 6, it is determined whether or not the ignition signal is ON.
When it is determined NO in step S20, the ignition signal is OFF and the vehicle is in a stopped state, so the transmission request process is not performed and the process ends.
[0063]
  Further, when YES is determined in the step S20, the process proceeds to a step S21 so as to read various signals such as a vehicle speed signal from the various sensors 40.
[0064]
  In subsequent step S22, it is determined whether or not the ignition signal has changed from the OFF state to the ON state.
[0065]
  When YES is determined in step S22, it is immediately before the vehicle changes from the stopped state to the traveling state, and it is necessary to grasp the latest air pressure state of all tires in the vehicle stopped state. Transmits a transmission request signal (ALL) including all stored tire identification information of the host vehicle toward all tires.
[0066]
  All the tires 2 to 6 that have received the transmission request signal transmit the traveling state detection information and the detected air pressure information to the control unit 20, and the control unit 20 performs air pressure alarm processing ( Here, although detailed description is omitted, a process of alarming an abnormality in air pressure when the deviation is large based on the deviation between the detected air pressure information and the appropriate air pressure is executed.
[0067]
  When NO is determined in step S22, that is, when the ignition signal is continuously on, the process proceeds to step S24, and the vehicle is in a running state from the vehicle state information read in step S21. It is determined whether or not.
[0068]
  When YES is determined in the step S24, the process proceeds to a step S25 so as to determine whether or not the vehicle was stopped last time.
[0069]
  When it is determined as YES in step S25, that is, immediately after changing from the stopped state to the traveling state, it is necessary to immediately check whether the tire mounted on the vehicle has changed due to the tire replacement while the vehicle is stopped. In step S26, a transmission request signal (ALL) including all the tire identification information of the host vehicle is transmitted.
[0070]
  In subsequent step S27, it is determined whether or not the spare tire 6 is mounted on the vehicle.
[0071]
  When YES is determined in step S27, that is, an abnormality in air pressure occurs in any of the traveling tires 2 to 5 (here, it is assumed that an abnormality in air pressure occurs in the traveling tire 2). When the spare tire 6 is mounted instead of the traveling tire 2 in which the occurrence of the problem occurs, the process proceeds to step S28.
[0072]
  In step S28, a transmission request is output every shortest transmission cycle t1 for the tires in the running state (here, the running tires 3, 4, 5 and the spare tire 6), and in step S29, the tires in the non-running state A transmission request is output for each transmission cycle t2 set longer than the transmission cycle t1 (here, the traveling tire 2 replaced due to an abnormal air pressure).
[0073]
  When NO is determined in step S27, that is, when there is no air pressure abnormality in any of the traveling tires 2 to 5, the process proceeds to step S30.
[0074]
  In step S30, a transmission request is output to the traveling tires 2 to 5 other than the spare tire 6 every transmission cycle t1, and in step S31, a transmission request is output to the spare tire 6 every longest transmission cycle t3. .
[0075]
  Moreover, when it determines with NO by the said step S24, it progresses to step S32 and it is determined whether the spare tire 6 is mounted | worn with the vehicle.
[0076]
  When YES is determined in step S32, that is, an abnormality in air pressure occurs in any of the traveling tires 2 to 5 (here, it is assumed that an abnormality in air pressure occurs in the traveling tire 2). When the spare tire 6 is mounted instead of the traveling tire 2 in which the occurrence of the problem occurs, the process proceeds to step S33.
[0077]
  In step S33, a transmission request is output every transmission cycle t2 to all tires including the running tires 2 to 5 and the spare tire 6.
[0078]
  When NO is determined in step S32, that is, when there is no air pressure abnormality in any of the traveling tires 2 to 5, the process proceeds to step S34.
In step S34, a transmission request is output to the traveling tires 2 to 5 other than the spare tire 6 every transmission cycle t2, and in step S35, a transmission request is output to the spare tire 6 every longest transmission cycle t3. .
[0079]
  Next, the operation of the second embodiment will be described based on the time chart of FIG.
[0080]
  FIG. 7 shows an ignition signal detected from various sensors 40, a vehicle state indicating whether the vehicle is in a stopped state or a traveling state, a traveling state detection signal detected in the tire pressure sensors 7 to 11, and an air pressure of each tire. A transmission signal from the sensors 7 to 11 to the control unit 20, a vehicle wearing state determination signal of the spare tire 6 detected by the air pressure sensor 11 of the spare tire 6, and a transmission request signal from the control unit 20 to each tire 2 to 6, respectively. It is shown. Furthermore, a time chart in a situation where the inner traveling tire 2 of the traveling tires 2 to 5 mounted on the vehicle is replaced with the spare tire 6 is shown.
[0081]
  First, when the ignition signal is switched from OFF to ON, the control unit 20 transmits a transmission request signal (ALL) including all stored tire identification information of the vehicle. All the tires 2 to 6 of the own vehicle transmit the traveling state detection information and the detected air pressure information to the control unit 20 in response to the transmission request signal. Here, the reason why the control unit 20 transmits the transmission request signal including all of the stored tire identification information of the own vehicle is that an abnormality in the air pressure state when the ignition signal is OFF is detected promptly and before the vehicle travels. It is for alarming.
[0082]
  Further, after that, when the vehicle starts traveling, the control unit 20 similarly transmits a transmission request signal (ALL) including all stored tire identification information of the host vehicle.
[0083]
  Here, the reason why the control unit 20 transmits the transmission request signal including all the stored tire identification information of the own vehicle is that the spare tire 6 is mounted instead of the traveling tires 2 to 5 in the stop state before traveling. This is for specifying which tire is not attached to the vehicle. Based on this identification result, the transmission cycle of the transmission request signal is changed for each tire.
[0084]
  In FIG. 7, the traveling tires 2 to 5 indicate a traveling state in response to a transmission request signal (ALL) transmitted to all tires of the host vehicle when the vehicle first starts traveling from a stopped state. The state detection information is transmitted, and the traveling tire state detection information indicating that the spare tire 6 is in the non-traveling state is transmitted. Thereafter, while the running state of the vehicle continues, a transmission request signal including tire identification information of the tire (running tire 2 to 5) in which the running state is detected is transmitted every cycle t1. On the other hand, the transmission request signal for the spare tire 6 detected to be in the non-running state is transmitted thereafter at a period t3 longer than the period t1. As a result, while the traveling state of the vehicle continues, the traveling tires 2 to 5 that are mounted on the vehicle and whose traveling state is detected are transmitted to the control unit 20 at the transmission cycle t1, and are not mounted on the vehicle. A transmission signal is transmitted to the control unit 20 at the transmission cycle t3 for the spare tire 6 in which the traveling state is detected.
[0085]
  Next, consider a case where an abnormality in air pressure occurs in the traveling tire 2 of the traveling tires 2 to 5, the vehicle is stopped, and the traveling tire 2 is replaced with a spare tire 6.
[0086]
  When the ignition signal is switched from OFF to ON after the tire has been replaced, the control unit 20 transmits a transmission request signal (ALL) including all stored tire identification information of the host vehicle in the same manner as described above. The tires 2 to 6 transmit the traveling state detection information and the detected air pressure information to the control unit 20 in response to the transmission request signal.
[0087]
  Next, when the vehicle starts traveling, similarly, the traveling state detection information and the detected air pressure information are transmitted to the control unit 20 in response to transmission of transmission request signals (ALL) to all the tires 2 to 6 of the own vehicle. . FIG. 7 shows a state in which the traveling state is detected from the spare tire 6 and the traveling tires 3 to 5 and the non-traveling state is detected from the traveling tire 2 based on the transmitted traveling state detection information. Thereafter, while the running state of the vehicle continues, a transmission request signal including tire identification information of the tires (running tires 3 to 5 and spare tire 6) in which the running state is detected is transmitted every cycle t1. On the other hand, the transmission request signal for the traveling tire 2 detected to be in the non-running state is transmitted thereafter at a period t2 longer than the period t1 and shorter than the period t3. As a result, while the traveling state of the vehicle continues, the spare tire 6 and the traveling tires 3 to 5 that are mounted on the vehicle and detected in the traveling state are transmitted to the control unit 20 at the transmission cycle t1, and are mounted on the vehicle. A transmission signal is sent to the control unit 20 at the transmission cycle t2 for the traveling tire 2 in which the non-running state is detected.
[0088]
  As described above, according to the second embodiment, when it is determined that the spare tire 6 is not attached to the vehicle while the spare tire 6 is stored in the spare tire storage unit 13, the spare tire 6 Since the transmission cycle of the transmission request signal from the control unit 20 is set to t3 which is set longer than the transmission cycles t1 and t2 of the traveling tires 2 to 5, the life of the battery unit 11a of the spare tire 6 is improved. can do.
[0089]
  Further, when the spare tire 6 is mounted on the vehicle instead of the traveling tire 2 and it is determined that the spare tire 6 is in the mounted state, the transmission cycle of the spare tire 6 is the same as the remaining traveling tires 3 to 5. Therefore, it is possible to cope with a situation where the alarm urgency is high, and to achieve both improvement in battery life and ensuring safety.
[0090]
  In the first and second embodiments, the tire identification information of the spare tire 6 is described as being stored in advance in the storage unit 20c of the control unit 20, but the tire identification information of the spare tire is registered in the storage unit 20c. A specific example will be described.
[0091]
  First, as disclosed in the above-mentioned prior art patent 3061047, at the time of vehicle production factory or service, the registration mode is set using a registration switch provided in the vehicle, and the tire identification of the spare tire is performed within a predetermined time. Registration can be performed by transmitting information or inputting the information using an input means.
[0092]
  Alternatively, as shown in FIG. 8, the transmission signal from the tire has a spare tire information area, and whether or not the tire is a spare tire is stored in advance in the storage units 7e to 11e of the air pressure sensors in each tire. Based on this information, the spare tire information area of the transmission signal may be transmitted with 1 being set for a spare tire and 0 being set for a traveling tire. In the control unit 20, the tire identification information included in the signal having the spare tire information area 1 in the received signal can be registered in the storage unit 20c as the spare tire.
[0093]
  Alternatively, the control unit 20 side may automatically determine and register it in the storage unit 20c. As shown in FIG. 9, since the transmission signal from the spare tire in the first and second embodiments includes the tire running state detection information detected from the tire running state detection unit 11d, the production factory, the service time, etc. In addition, in the registration mode set in advance, the spare tires are forcibly run in the retracted state where they are not mounted on the vehicle, and the running state detection information detected by the running state detection units 7d to 11d of the respective tires at that time is stored. The tire identification information of the tire that has been verified and detected to be in the non-running state can be registered in the storage unit 20c as that of the spare tire.
[0094]
  (Embodiment 3)
  FIG. 10 is a control block diagram according to the third embodiment.
[0095]
  The air pressure sensors 7 to 11 detect battery temperatures 7a to 11a for supplying power to each part in the sensor, pressure detectors 7b to 11b for detecting tire air pressure of the tires 2 to 6, and tire temperature. Temperature detection units 7c to 11c for detecting the running state (tire rotation) of the tire mounted on the vehicle 1, and storage units 7e to 11e for storing tire identification information And transmitters 7f to 11f for wirelessly transmitting the information detected by the detection units and the tire identification information to the control unit 20, and transmission cycle setting units 7g to 11g for setting a transmission cycle to be transmitted to the control unit 20. And central processing units 7h to 11h. The control unit 20 includes a receiver 20a, a central processing unit 20b, and a storage unit 20c.
[0096]
  Further, the central processing unit 20b and the storage unit 20c store the appropriate air pressure storage means 20e that stores the appropriate air pressure with respect to the tire temperature, and the measured air pressure detected by the air pressure sensors 6 to 9 and the appropriate air pressure storage means 20e. The excess / deficiency amount calculating means 20f for calculating the excess / deficiency amount based on the difference from the appropriate air pressure, the tire-specific determination threshold storage means 20g for storing the determination threshold value for determining abnormality for each tire, and the excess / deficiency amount calculation means 20f. The determination means 20h for determining an abnormal state of the tire pressure based on the excess / deficiency amount calculated by the above and the determination threshold value stored in the tire-specific determination threshold value storage means 20g, and the determination means 20h determine the abnormal state of the tire pressure. The alarm control means 20i for outputting an alarm to the alarm device 30 to warn of an abnormal state, and the air of each tire detected by the air pressure sensor Determination threshold setting means 20j for setting a spare tire determination threshold value stored in the tire-specific determination threshold value storage means 20g based on the information, the driving state information, and various information from other various on-vehicle sensors 40, and the air pressure sensor 6 ˜9, identification information storage means 20k for storing the own vehicle tire identification information and spare tire discrimination means 20l for discriminating whether or not the tire is a spare tire are provided.
[0097]
  The determination threshold value setting means 20j can set the determination threshold value when the spare tire 6 is not mounted on the vehicle so as to determine abnormality in a pneumatic state lower than the determination threshold value of the traveling tires 2 to 5. In addition, when it is determined that the running tire is abnormal, it is expected that the tire is replaced with a spare tire. Therefore, the determination threshold value can be set high in order to increase the alarm urgency.
[0098]
  Next, setting of the determination threshold in the third embodiment will be described with reference to FIG.
[0099]
  FIG. 11 shows an example in which a plurality of determination threshold values are set for the tire air pressure state as the determination threshold value settings. In addition, since the appropriate air pressure value of each tire varies depending on the type of tire and the temperature in the tire, the ratio (%) with respect to the appropriate air pressure value is shown here as shown in the graph.
[0100]
  In the figure, the left side shows the setting of the determination threshold value of the running tire. Up to a threshold value X where the air pressure value of the traveling tire is 90% of the appropriate air pressure value is determined as the normal range. Between the threshold value Z that is less than 90% and 80%, it is determined to be in the initial abnormal range. If it is below 80%, it is determined that the abnormal range is close to a puncture state. According to the determination result, an abnormality is alarmed from the alarm control means 20i to the alarm device 30.
[0101]
  Next, in the figure, the right side is the setting of the determination threshold value of the spare tire in the non-running state.
[0102]
  Here, the threshold value for determining the initial abnormal range is different from the threshold value for determining the spare tire. That is, the initial abnormal range threshold value Y of the spare tire in the non-driving state is set to 85% lower than the initial abnormal range threshold value X of the traveling tire, and is not determined as an initial abnormality until it falls below 85%. It is like that. Here, the reason why the spare tire determination threshold is set smaller than the traveling tire determination threshold is that even if there is an abnormality in air pressure, the alarm is delayed for the spare tire in a non-traveling state with a low alarm urgency. However, since the influence is low, the annoyance caused by the early warning of the spare tire is suppressed.
[0103]
  Here, the threshold value Y and the threshold value Z are set as the determination threshold values, but only the threshold value Z may be used.
[0104]
  Next, when it is determined whether the running tire is in the initial abnormal range or the abnormal range close to the puncture state, the determination threshold value of the spare tire is 90% or less with respect to the appropriate air pressure value as in the running tire. If the initial abnormal range is further below 80%, the determination threshold is changed so that the abnormal range is determined to be close to the puncture state.
[0105]
  Here, the reason for setting the spare tire determination threshold to be the same as that of the traveling tire is that when the traveling tire is in one of the abnormal ranges, there is a high possibility that the spare tire will be replaced. This is because it is considered to be almost the same as the traveling tire.
[0106]
  As described above, the determination threshold value may be a ratio (%) to an appropriate air pressure value or an air pressure value (KPa).
[0107]
  Next, FIG. 12 illustrates a display example of an alarm according to the third embodiment.
[0108]
  FIG. 12 shows an example in which only one threshold value X is set as a threshold value for determining abnormality of the running tire, and only one threshold value Y is set as a threshold value for determining abnormality of the spare tire.
[0109]
  The threshold value X is set to 90% of the appropriate air pressure value, and the threshold value Y is set to 80% of the appropriate air pressure value.
[0110]
  As for the running tire, when the air pressure falls below 90% of the appropriate air pressure value, it is determined that it is in the abnormal range, and in addition to displaying a warning of the shortage state, the shortage amount of air pressure is simultaneously displayed.
[0111]
  As for the spare tire in the non-running state, if the spare tire air pressure falls below 80% of the appropriate air pressure, an insufficient state is alarmed and an insufficient amount is displayed as described above. On the other hand, when the air pressure of the traveling tire is determined to be in the abnormal range, the determination threshold for the spare tire in the non-traveling state is changed from 80% to 90%, which is the same as that of the traveling tire, and an insufficient state is alarmed in the same manner as above And display the shortage.
[0112]
  By changing the determination threshold in this way, it is possible to avoid a situation in which an abnormal air pressure alarm is issued again when the traveling tire is replaced with a spare tire.
[0113]
  That is, when the tire pressure abnormality occurs and the spare tire is mounted instead of the traveling tire, the air pressure of the spare tire itself may be reduced. % And a running tire determination threshold value of 90% is considered.
[0114]
  In such a situation, although an abnormality in the air pressure of the spare tire is not alarmed, if the traveling state of the spare tire is detected by subsequent tire replacement, an abnormality in the air pressure is also alarmed for the spare tire based on the same determination threshold 90% as that of the traveling tire. Therefore, when the travel after the replacement is started, the abnormality in the air pressure is warned again, so that the driver feels uncomfortable.
[0115]
  In the third embodiment, when the abnormality of the traveling tire is determined, the determination threshold value of the spare tire in the non-traveling state is changed to the same value as the determination threshold value of the traveling tire. Therefore, it is possible to prevent the driver from feeling uncomfortable.
[0116]
  Next, the change of the determination threshold value of the determination threshold value setting unit 20j in the third embodiment will be specifically described based on the flowchart of FIG.
[0117]
  In step S40 of FIG. 13, it is determined whether or not the ignition signal is ON. If it is determined NO in step S40, the ignition signal is OFF and the vehicle is in a stopped state. Return without returning.
[0118]
  If YES is determined in the step S40, the process proceeds to a step S41 so that the vehicle state information indicating stopping or running of the vehicle detected from the vehicle speed signals of the various sensors 40 and the actually measured air pressure detected by the air pressure sensors 7-11. P, tire temperature T, tire running state (for example, tire rotating state) W, etc. are read.
[0119]
  In subsequent step S42, it is determined from the vehicle speed signals of the various sensors 40 whether or not the vehicle is running.
[0120]
  When it is determined NO in step S42, that is, when the vehicle is in a stopped state, the necessity of changing the spare tire determination threshold is low, and therefore the process returns without performing the determination threshold changing process for the spare tire 6.
[0121]
  When YES is determined in the step S42 and the vehicle is in a traveling state, the process proceeds to a step S43 to determine whether or not the spare tire 6 is in a non-mounted state.
[0122]
  If it is determined as YES in step S43 and it is determined that the vehicle is not in the mounted state, the process proceeds to step S44, and it is determined whether or not the pneumatic state of the traveling tires 2 to 5 is normal.
[0123]
  When YES is determined in step S44 and it is determined that the air pressure state of the traveling tires 2 to 5 is normal, the process proceeds to step S45, and the determination threshold value Y of the spare tire 6 is set to be higher than the determination threshold value X of the traveling tires 2 to 5. Change to a value lower by the predetermined value α and return.
[0124]
  Further, when NO is determined in step S43 and the spare tire 6 is in the mounted state and when NO is determined in step S44 and the air pressure of the traveling tire is abnormal, the process proceeds to step S46 to determine a spare tire determination threshold value. Set Y to the determination threshold value X of the running tire and return.
[0125]
  As described above, according to the third embodiment, when the spare tire 6 is not attached to the vehicle and the traveling tires 2 to 5 have no air pressure abnormality, the determination threshold value Y of the spare tire 6 is set to the traveling tires 2 to 5. Since the predetermined threshold value α is set lower than the determination threshold value X, it is possible to suppress annoyance to the driver due to the early warning of the spare tire 6 having a low warning urgency level.
[0126]
  When the spare tire 6 is not attached to the vehicle and the running tires 2 to 5 are abnormal in air pressure, the determination threshold Y of the spare tire 6 is set to the same value as the determination threshold X of the traveling tires 2 to 5. Since it is set, the abnormality of the spare tire 6 is warned before the tire replacement, so that the driver can be prevented from feeling uncomfortable.
[0127]
  (Embodiment 4)
  In the third embodiment, when the spare tire 6 is in a non-running state and the air pressure of the running tire is abnormal, the spare tire determination threshold Y is set to the running tire determination threshold X. An example in which the determination threshold value of the spare tire is set lower than the threshold value X according to the air pressure value of the traveling tire will be shown.
[0128]
  Hereinafter, specific processing of the fourth embodiment will be described based on the flowchart of FIG.
[0129]
  The process from step S50 to S55 in FIG. 14 is the same as step S40 to S45 in FIG.
[0130]
  When it is determined NO in step S54, that is, when a spare tire is mounted and the traveling tire has an air pressure abnormality, the process proceeds to step S56.
[0131]
  In step S56, the spare tire determination threshold Y is set to be lower than the traveling tire determination threshold X by f (P).
[0132]
  f (P) is a function that depends on the air pressure P of the running tire. For example, when the air pressure P of the running tire is a predetermined value X as shown in the correction pattern (1) in FIG. As the air pressure P of the running tire decreases, f (P) also decreases, and f (P) is set to 0 at the determination threshold Z.
[0133]
  According to such setting of f (P), when the air pressure P of the traveling tire is set to a determination threshold value that is lower than the determination threshold value X by a predetermined amount α, and the air pressure P of the traveling tire falls below the determination threshold value X, the spare tire The determination threshold Y is set so as to gradually approach the determination threshold X according to the air pressure P of the traveling tire. When the air pressure P of the traveling tire eventually reaches the determination threshold Z, the determination threshold Y is the same value as the determination threshold X. Will be set to.
[0134]
  It should be noted that f (P) gradually decreases from the vicinity of the determination threshold value X according to the air pressure P of the traveling tire as shown in the correction patterns (2) and (3) corresponding to the value of the air pressure P of the traveling tire. It may be.
[0135]
  Further, in the example of f (P) shown in FIG. 15, the linear characteristic is shown with respect to the air pressure P of the traveling tire, but it may be set as a curved characteristic.
[0136]
  As described above, according to the fourth embodiment, when the spare tire 6 is not attached to the vehicle and the traveling tires 2 to 5 have no air pressure abnormality, the determination threshold value Y of the spare tire 6 is set to the traveling tires 2 to 5. Since it is set lower than the determination threshold value X by f (P), it is possible to suppress annoyance to the driver due to the early warning of the spare tire 6 having a low warning urgency.
[0137]
  Also, when the spare tire 6 is not attached to the vehicle and an abnormality in air pressure occurs in the traveling tire, the determination threshold Y of the spare tire 6 decreases to the determination threshold X of the traveling tires 2 to 5 and the air pressure of the traveling tire decreases. Accordingly, it is possible to prevent the driver from feeling uncomfortable by alerting the spare tire 6 before replacing the tire.
[0138]
  In the present embodiment, an example of a rotation sensor that detects the rotation of the tire is shown as the running state detection unit. However, a G sensor that detects an inertial force generated by the rotation of the tire may be used.
[0139]
  In the present embodiment, an example is shown in which each detection and transmission is executed simultaneously in synchronization with the air pressure sensor. However, both the executions are made asynchronous or the detection cycle is set shorter than the transmission cycle. In addition, the reliability accuracy of the detection information may be improved.
[Brief description of the drawings]
FIG. 1 is an overall configuration diagram related to first to fourth embodiments.
FIG. 2 is a control block diagram according to the first embodiment.
FIG. 3 is a flowchart showing control contents according to the first embodiment.
FIG. 4 is a time chart showing control contents according to the first embodiment.
FIG. 5 is a control block diagram according to the second embodiment.
FIG. 6 is a flowchart showing control contents according to the second embodiment.
FIG. 7 is a time chart showing control contents according to the second embodiment.
FIG. 8 is a diagram showing signal contents from an air pressure sensor.
FIG. 9 is a diagram showing signal contents from an air pressure sensor.
FIG. 10 is a control block diagram according to the third embodiment.
FIG. 11 is a diagram showing air pressure determination threshold values according to the third embodiment.
FIG. 12 is a diagram showing an example of an alarm related to the third embodiment.
FIG. 13 is a flowchart showing control details according to the third embodiment.
FIG. 14 is a flowchart showing control contents according to the fourth embodiment.
FIG. 15 is a diagram showing a determination threshold value correction pattern according to the fourth embodiment.
[Explanation of symbols]
2-5: Traveling tire
6: Spare tire
7 to 10: Air pressure sensor (first air pressure sensor)
11: Air pressure sensor (second air pressure sensor)
7a-11a: Battery part
7e to 11e: Storage unit (tire identification information storage unit)
7f-11f: Transmitter
7g to 11g: Transmission cycle setting unit
11i: Vehicle wearing state determination unit
13: Spare tire storage
20: Control unit
20e: Appropriate air pressure storage means (appropriate air pressure storage unit)
20h: determination means (determination unit)
20i: Alarm control means (alarm control unit)
20l: Spare tire discrimination means (spare tire discrimination part)
20j: Determination threshold setting means (determination threshold setting unit)
30: Alarm

Claims (3)

A first air pressure sensor that is mounted on each traveling tire of the vehicle and detects tire pressure information of the traveling tire;
A second air pressure sensor that is mounted on a spare tire stored in the spare tire storage unit and detects tire air pressure information of the spare tire; and
An alarm device for alarming abnormal air pressure of each traveling tire and spare tire of the vehicle;
A control unit that receives tire pressure information from each of the air pressure sensors and causes the alarm device to warn of an abnormal air pressure of the vehicle tire;
Each air pressure sensor includes a battery unit for supplying power to each unit in the sensor, a transmitter for transmitting detected tire air pressure information, and a transmission cycle setting unit for setting a transmission cycle from the transmitter. Is provided,
The second air pressure sensor includes a vehicle mounting state determination unit that determines whether or not the spare tire is mounted on the vehicle.
The transmission cycle setting unit of the first air pressure sensor sets the transmission cycle to the first transmission cycle when the vehicle is running, and sets the transmission cycle to the first transmission cycle when the vehicle is stopped. It is configured to set a second transmission period longer than the transmission period,
The transmission cycle setting unit of the second air pressure sensor has a third transmission cycle longer than the second transmission cycle when the vehicle mounting state determining unit determines that the transmission cycle setting unit is in the non-mounted state. The vehicle tire is configured to set the transmission cycle to the same transmission cycle as that of the first air pressure sensor when it is determined that the vehicle is in the mounted state. Air pressure alarm device. An air pressure sensor that is mounted on a spare tire stored in each traveling tire and spare tire storage unit of the vehicle and detects tire air pressure information;
An alarm device for alarming abnormal air pressure of each traveling tire and spare tire of the vehicle;
A control unit for causing the alarm to warn of abnormal air pressure,
In the first air pressure sensor mounted on each of the traveling tires, a tire identification information storage unit in which tire identification information is stored,
A transmitter for transmitting tire identification information stored in the tire identification information storage unit together with detected tire pressure information; and
In the second air pressure sensor attached to the spare tire, a tire identification information storage unit in which tire identification information is stored,
A vehicle mounting state determination unit for determining whether or not the spare tire is mounted on the vehicle;
A transmitter that transmits the tire identification information stored in the tire identification information storage unit and the detected tire air pressure information together with the tire tire information detected by the vehicle state determination unit, and the control unit. A receiver for receiving signals from the first and second air pressure sensors;
A spare tire discriminating unit for discriminating whether or not the tire identification information included in the signal received at the receiver is tire identification information indicating a spare tire;
An appropriate air pressure storage unit for storing the appropriate air pressure of the tire;
Judgment that determines the tire pressure state based on the relationship between the difference between the tire pressure detected by the first and second air pressure sensors and the appropriate air pressure stored in the appropriate air pressure memory and the determination threshold And
An alarm control unit for causing the alarm to warn of an abnormal air pressure when the determination unit determines an excess or deficiency state from the appropriate air pressure;
A determination threshold value setting unit for setting a determination threshold value in the determination unit,
The determination threshold value setting unit sets the determination threshold value for the spare tire to be smaller than the determination threshold value for the traveling tire when the vehicle mounting state determination unit determines that the vehicle is not in the mounting state, and the mounting state When the determination threshold is set to the same as the determination threshold for the traveling tire, and the air pressure of the traveling tire is lowered to the vicinity of the determination threshold, the spare tire is not mounted. A tire pressure alarm device for a vehicle tire, which is configured to correct a determination threshold value for a spare tire in a state to increase.   The determination threshold value setting unit increases the determination threshold value for the spare tire in the spare tire non-attached state according to the air pressure value of the traveling tire when the air pressure of the traveling tire is lowered to the vicinity of the determination threshold value. The tire pressure alarm device for a vehicle tire according to claim 2, wherein the air pressure alarm device is configured to correct to

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