JP2004291797A - Tire air pressure detection device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To prevent erroneous action caused by variation of air pressure due to lowering of external atmospheric temperature and to generate an accurate air pressure alarm in a tire air pressure detection device. <P>SOLUTION: The tire air pressure detection device is provided with a tire air pressure detection means 2 for detecting a tire air pressure of a vehicle; a transmitting means 3 for transmitting a detection pressure information; a receiving means 4 for receiving the detection pressure information; a memory means 10 for renewing and memorizing the detection pressure information; an alarm means 6 for warning lowering of the tire air pressure; a determination means 22 for determining requirement of the alarm in responsive to the former determination history; and a control means 21 for controlling so as to generate the alarm by the alarm means 6 when it is determined that the alarm is required. The determination means 22 does not determine the requirement of the alarm when an engine switch of the vehicle is off and determines the requirement of the alarm based on the detection pressure information memorized in the memory means 10 and the former determination history when the engine switch of the vehicle is on. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a tire pressure detection device that detects a decrease in tire pressure and issues a warning.
[0002]
[Prior art]
As a device for detecting the air pressure inside the tire of an automobile (hereinafter, referred to as tire pressure or simply air pressure), a tire pressure sensor provided on a wheel, a radio transmitting device for transmitting a detected pressure signal of the tire pressure sensor, There is a configuration including a receiving device that receives a detection pressure signal (for example, see Patent Literature 1 and Patent Literature 2).
[0003]
In such a device, the tire pressure sensor and the wireless transmission device are provided inside the wheel, and the detected pressure information of the tire pressure detected by the tire pressure sensor is transmitted as a signal from the wireless transmission device as needed. ing. On the other hand, the receiving device is provided on the vehicle body side so as to receive the detected pressure signal transmitted from the wireless transmitting device and monitor the tire pressure.
[0004]
By the way, in the above-mentioned technology, it is convenient if it is possible to control the timing of the detection and wireless transmission of the tire pressure from the vehicle body so that tire pressure information such as a detected pressure can be obtained when necessary. In order to control the operation of the tire pressure sensor and the wireless transmission device provided from outside the wheel, a receiving device for receiving a control signal inside the wheel is required. However, since the inside of the wheel (the inside of the tire) is narrow, it is necessary to use a receiving device that is reduced in size and weight so as to fit in the inside of the wheel, so that the cost increases and the manufacturing process becomes more complicated. Would. In addition, a method of connecting the wheel side and the vehicle body side with a wire is not realistic because a slip ring must be provided on the wheel shaft.
[0005]
For this reason, in a general tire pressure detecting device, the tire pressure sensor and the radio transmitter provided on the wheel do not require control from the vehicle body side, and periodically operate at a predetermined cycle in advance. ing. For example, the tire pressure sensor detects the tire pressure at a timing of once / hour when the vehicle is stopped and once / minute when the vehicle is running, and the wireless transmitter transmits the detected pressure signal wirelessly to the surroundings. Has become.
[0006]
In such a tire pressure detection device, it is common to set a threshold value for performing a warning determination by providing a so-called hysteresis. A threshold value of a pressure for starting a warning (a warning start threshold value) and a pressure value for ending a warning. (Warning end threshold) is set to a different value. In other words, when no warning is issued, a warning is issued when the tire pressure falls below the warning start threshold, while when a warning is issued, the warning is released even when the tire pressure exceeds the warning start threshold. Instead, the warning is canceled when the value exceeds a warning end threshold set as a threshold larger than the warning start threshold.
[0007]
If the tire pressure is determined by one warning determination threshold, the determination may not be stable in the vicinity of this threshold, but as described above, by setting a width between the threshold for issuing a warning and the threshold for canceling, The determination of the warning can be stabilized.
[0008]
[Patent Document 1]
JP-A-11-20427 (page 2, right column, lines 24 to 34, FIG. 1)
[Patent Document 2]
JP-A-11-322254 (page 47, left column, line 47 to right column, line 6, FIG. 2)
[0009]
[Problems to be solved by the invention]
By the way, since the tire pressure of a vehicle depends on the temperature of the air in the tire, the tire pressure changes along with the temperature inside the tire due to frictional heat between the tire and the road surface during traveling. It is known that during parking, the tire pressure of the vehicle is greatly affected by changes in the outside air temperature. In particular, when the vehicle is parked outdoors at night, the air temperature in the tires decreases as the outside air temperature decreases, so that, for example, the tire pressure of the vehicle may change as shown in the graph of FIG.
[0010]
When the tire pressure changes in this manner, according to the above-described conventional tire pressure detection device, even when the main power supply (IG switch) of the vehicle is off, the tire pressure is detected by the tire pressure sensor and the wireless transmission device wirelessly detects the tire pressure. Be sent. Then, the receiving device receives the wirelessly transmitted air pressure signal and determines the magnitude of the air pressure. Therefore, when the tire air pressure falls below the warning start threshold value due to a decrease in outside air temperature, no warning is actually issued, but it is determined that a warning should be issued. Thereafter, even if the tire air pressure rises to or above the warning start threshold with an increase in the outside air temperature, the warning determination is not canceled until the tire air pressure reaches the warning end threshold. Therefore, while the IG switch is off, a decrease in the tire air pressure below the warning start threshold due to a change in the outside air temperature is detected, and when the IG switch is subsequently turned on, the tire air pressure is in a substantially normal range ( A warning may be issued even when the warning is between the warning start threshold and the warning end threshold (the range in which the warning does not need to be started).
[0011]
On the other hand, if the receiver is not operated while the IG switch is off, and the operation of the receiver is started when the IG switch is turned on, such a malfunction in detecting the tire pressure can be prevented. can do. However, as described above, the tire pressure sensor and the wireless transmission device provided on the wheels are periodically operated at a fixed cycle in advance regardless of whether the IG switch is on or off. It takes time from when the operation starts to when the air pressure signal is received, and a judgment delay time (judgment lag) occurs. That is, since there is no appropriate air pressure signal to be determined from the time when the IG switch, which has been turned off, is turned on until the air pressure signal is received, the tire air pressure cannot be determined. Even if the air pressure signal for determining the tire air pressure can be stored, if the receiving device does not operate while the IG switch is off, the IG switch is turned off. Since only the air pressure signal until immediately before is stored, it is not possible to determine the change in air pressure during parking.
[0012]
In addition, since the radio transmission operation itself of the air pressure signal does not depend on the on / off of the IG switch, the time from the time when the IG switch is turned on to the time when the air pressure signal is received varies depending on the case. The length of the delay time cannot be predicted.
The present invention has been made in view of these problems, and provides a tire pressure detecting device that prevents a malfunction due to a change in air pressure due to a decrease in outside air temperature and can issue an accurate air pressure warning. Aim.
[0013]
[Means for Solving the Problems]
For this reason, the tire pressure detecting device according to the first aspect of the present invention includes a tire pressure detecting means for detecting a tire pressure of a vehicle, and a transmission for transmitting detected pressure information detected by the tire pressure detecting means at a predetermined cycle. Means, receiving means for receiving the detected pressure information transmitted by the transmitting means, storage means for updating and storing the detected pressure information received by the receiving means for each reception, abnormality of the tire air pressure Warning means for warning a warning, a determination means for determining whether or not a warning by the warning means is necessary according to a previous determination history, and a warning means when the determination means determines that a warning is required. Control means for performing a warning so that the tire pressure detection means, the transmission means, the reception means, and the storage means are connected to an on / off state of an engine switch of the vehicle. When the engine switch of the vehicle is off, the determination unit does not determine whether or not a warning is required. When the engine switch of the vehicle is on, the determination unit determines whether the detected pressure information is stored in the storage unit. It is characterized in that the necessity of warning is determined based on the warning.
[0014]
According to a second aspect of the present invention, in the tire pressure detecting device according to the present invention, when the engine switch of the vehicle is turned on, if the previous determination does not require a warning, the detected pressure information starts warning. It is determined that a warning is necessary if the value is less than the threshold, and that if the previous determination requires a warning, it is determined that no warning is required if the detected pressure information is equal to or greater than a warning end threshold that is greater than the warning start threshold. Features.
[0015]
According to a third aspect of the present invention, in the tire pressure detecting device of the present invention, the transmitting means wirelessly transmits the detected pressure information, and the receiving means wirelessly receives the detected pressure information.
According to a fourth aspect of the present invention, there is provided a tire pressure detecting device according to the present invention, wherein the tire pressure detecting means detects the tire pressure at a first detection period when the vehicle stops, and detects the tire pressure at a first detection period when the vehicle travels. The detection is performed in a second detection cycle shorter than the detection cycle.
[0016]
According to a fifth aspect of the present invention, there is provided a tire pressure detecting device according to the present invention, wherein the determination as to whether the vehicle is stopped or running is made based on a radial acceleration generated as the tire rotates.
[0017]
BEST MODE FOR CARRYING OUT THE INVENTION
Hereinafter, embodiments of the present invention will be described with reference to the drawings.
1 to 3 show a tire air pressure detecting device as one embodiment of the present invention. FIG. 1 is an overall configuration diagram showing a configuration of the device, and FIG. 2 is a control flow showing a control operation of the device. FIG. 3 and FIG. 3 are graphs illustrating the relationship between a change in tire air pressure and a warning operation in a vehicle equipped with the present device.
[0018]
As shown in FIG. 1A, the tire pressure detecting device 1 according to the present embodiment has a tire pressure detector (tire pressure detecting means) 2 for detecting tire pressure as a main configuration, as shown in FIG. ) As a signal (pneumatic signal), a wireless transmitter (transmitting means), a receiving antenna (receiving means) for receiving a wirelessly transmitted air pressure signal, and a tire tire based on the received air pressure signal. CPU 8 for determining and controlling the air pressure state, memory (storage means) 10 for storing tire pressure information received by the receiving antenna 5, and a display (warning means) for displaying the determined tire pressure state ) 6 is provided in the vehicle 20.
[0019]
As shown in FIG. 1B, a tire pressure detector 2, a radio transmitter 3 and a centrifugal force switch 7 are provided inside the wheel 11 of the vehicle 20, and a battery (not shown) provided inside the wheel 11 is also provided. It operates as a power source. These devices do not require control from the vehicle body and operate independently of various vehicle-mounted devices provided on the vehicle body.
[0020]
That is, the tire pressure detector 2 detects the tire pressure at a predetermined period, and the wireless transmitter 3 wirelessly transmits the detected pressure to the surroundings as a pressure signal. The centrifugal force switch 7 is turned on when the wheel 11 rotates and centrifugal force (acceleration in the radial direction of the tire) acts, and is turned off when the wheel 11 is stopped. When the centrifugal force switch 7 is turned off, the tire pressure detector 2 performs the first detection cycle (here, once every hour). When the centrifugal force switch 7 is turned on, the tire pressure detector 2 performs the first detection cycle. The tire pressure is detected in a short second detection cycle (here, once a minute). As described above, when the detection is performed by the tire pressure detector 2, the radio transmitter 3 transmits the pneumatic signal by radio each time.
In the present embodiment, the vehicle has four wheels 11, and each wheel 11 has the above-described configuration.
[0021]
As shown in FIG. 1 (c), a receiving antenna 5, a display 6, a CPU 8, a memory 10, and an IG switch 12 are provided on the vehicle body side so as to operate from a vehicle battery (not shown) as a power source. Has become. The receiving antenna 5 is arranged at a position where it can receive the air pressure signal wirelessly transmitted from the radio transmitter 3, and is located near each tire so as to correspond to the radio transmitter 3 provided for each tire. Are provided one by one. In this embodiment, the receiving antenna 5 receives a pneumatic signal transmitted from the wireless transmitter 3, converts the pneumatic signal into a signal that can be processed by the CPU 8, and transmits the signal to the CPU 8. It has functions.
[0022]
The CPU 8 connected to each of the receiving antennas 5 and the IG switch 12 includes a control unit (control unit) 21 and a determination unit (determination unit) 22. The determination unit 22 performs an arithmetic process based on the air pressure signal received from each receiving antenna 5 and the ON / OFF information (IG switch information) of the IG switch 12 to determine whether a warning of the tire pressure is necessary. It has become. In particular, as described later, the determination unit 22 sets the warning start threshold and the warning end threshold to different values, and performs the current determination according to the previous determination history.
[0023]
The signal received by the CPU 8 from each of the receiving antennas 5 is temporarily stored in the memory 10, and the determination unit 22 performs an arithmetic process based on the air pressure signal stored in the memory 10 and the IG switch information. Can be done. Then, in accordance with the results of these arithmetic processings, the control unit 21 controls the display 6 to display a warning. Note that the display 6 is disposed at a position that is easy to see from the driver's seat, such as an instrument panel, and the control unit 21 can display on the display 6 whether the tire pressure state is a warning state or not. ing.
[0024]
Hereinafter, the arithmetic processing performed by the CPU 8 will be specifically described with reference to the control flowcharts shown in FIGS. 2 (a) and 2 (b).
The control flow of FIG. 2A is a flow for constantly monitoring and updating the change in the tire pressure. A predetermined flow is always maintained inside the CPU 8 as long as the power supply of the vehicle-mounted battery is connected regardless of the state of the engine switch. Processed periodically. Note that these processes are performed by the control unit 21 and the control unit 22 inside the CPU 8.
[0025]
In step S10, it is determined whether or not the receiving antenna 5 has received the detected pressure information P of the tire pressure. When the detected pressure information P is received, the detected pressure information P is stored in the memory 10 in step S20, and the flow is terminated. At this time, the detected pressure information P previously stored in the memory 10 is overwritten and updated. If the detected pressure information P has not been received, the flow is terminated.
[0026]
The control flow of FIG. 2B is a flow for comparing and determining the tire pressure and the warning threshold value, and is processed at a predetermined cycle.
First, in step S30, the state of the engine switch is determined from the on / off information of the IG switch 12. When the IG switch 12 is on, the process proceeds to a flow of comparing and determining the tire pressure and the warning threshold after step S40. However, when the IG switch 12 is off, the comparison between the air pressure signal and the warning threshold is not performed. This flow ends.
[0027]
Next, in step S40, it is determined whether the flag Fc indicating the state of the tire pressure is on or off. Fc is a flag indicating whether or not a warning of the tire pressure is required. When the tire pressure is in a warning state (a state requiring a warning), Fc = 1, and in a non-warning state (a state in which a warning is not required). At some point, Fc = 0 is set. This flag is set in a step described later, and Fc = 0 is given as an initial value.
[0028]
Here, when Fc = 0, that is, when the tire air pressure is in the non-warning state, the flow proceeds to the warning start determination flow of step S50 and the following steps. Proceed to.
If Fc = 0, it is determined in step S50 whether the detected pressure information P stored in the memory 10 is less than a first warning threshold (warning start threshold) P1. P1 represents a threshold value at which a warning is to be started. When it is determined that P <P1, the process proceeds to step S60, where Fc = 1 is set. In step S70, control is performed to cause the display 6 to display a warning. After that, this flow ends. When it is determined that P ≧ P1, the flow is terminated without changing Fc (that is, while maintaining Fc = 0).
[0029]
On the other hand, when Fc = 1 in step S40, that is, when the tire pressure is in the warning state, it is determined in step 110 whether the detected pressure information P stored in the memory 10 is equal to or greater than a second warning threshold (warning end threshold). You. P2 represents a threshold value at which the warning should be terminated. When it is determined that P ≧ P2, the process proceeds to step 120, where Fc = 0 is set. At step 130, control for canceling the warning display on the display 6 is performed. Then, this flow ends. When it is determined that P <P2, the warning is continued without changing Fc (that is, with Fc = 1), and this flow ends.
[0030]
With the configuration as described above, according to the tire pressure detecting device of the present embodiment, the following operation and effect can be obtained. Hereinafter, a specific description will be given with reference to FIG.
First, referring to FIG. 3 (a), while the vehicle is running, the centrifugal force switch 7 in the wheel 11 detects the rotation of the wheel, and the tire pressure detector 2 operates in the second predetermined cycle, that is, one minute. The tire pressure is detected in one cycle. The tire pressure detected here is wirelessly transmitted from the wireless transmitter 3 as an air pressure signal, and is always received by the antenna 5 and processed by the CPU 8.
[0031]
If the vehicle stops at time t0 in a state where the tire pressure is normal, that is, not in a warning state, the centrifugal force switch 7 is turned off by stopping the rotation of the wheels, so that the tire pressure detector 2 is in the first predetermined state. The tire pressure is detected in a cycle, that is, once a hour. Therefore, the transmission cycle of the air pressure signal wirelessly transmitted from the wireless transmitter 3 is once per hour.
[0032]
Even if the driver turns off the IG switch (engine switch) at time t1 and enters the parking state, the tire pressure detector 2 and the wireless transmitter 3 in the wheels 11 do not require control from the vehicle body. Since the operation is performed, the tire pressure is detected once an hour and the air pressure signal is transmitted wirelessly.
When the outside air temperature decreases during parking and the air temperature in the tires decreases accordingly, the tire air pressure also decreases. The CPU 8 continues to receive the air pressure signal transmitted from the wireless transmitter 3, and the air pressure signal is updated and stored in the memory 10 as needed. However, since the engine switch is off, the comparison between the air pressure signal and the warning start threshold is not performed. Therefore, even when the tire air pressure falls below the warning start threshold value due to the decrease in the outside air temperature, the air pressure signal is stored, but it is not determined that the state is the warning state.
[0033]
Eventually, as the outside air temperature rises, the tire air pressure enters a substantially normal range, that is, a range equal to or higher than the warning start threshold. When the driver turns on the engine switch at time t2 after the air pressure information stored in the memory 10 becomes equal to or greater than the warning start threshold, a comparison between the stored air pressure signal and the warning start threshold is made. Done. Since the air pressure information stored in the memory 10 is updated and stored as needed, if the air pressure signal is equal to or higher than the warning start threshold, it is not determined that a warning state has occurred, and no warning display is performed. Such a determination is made immediately when the engine switch is turned on, so that no determination lag occurs. Also, the air pressure signal used for this determination was updated even when the engine switch was off, and is the latest air pressure signal, so it is appropriate as a determination of tire pressure at the time of making this determination, Become reliable.
[0034]
Further, as shown in FIG. 3 (b), when the tire air pressure decreases not only due to a decrease in the outside air temperature but also due to a defective tire or the like, it is considered that the air pressure signal does not increase above the warning start threshold. Therefore, when the engine switch is turned on, it is immediately determined that a warning state is present, and a warning is displayed. Even in this case, no determination lag occurs, and an appropriate determination is made.
[0035]
In addition, when the tire pressure is lower than the warning start threshold, that is, in a warning state, when the engine switch is turned off by the driver and the vehicle is parked, a warning signal is issued when the engine switch is turned on. If it is not equal to or greater than the release threshold, the warning display is not released. Such conventional control can be performed, and the determination of a warning can be performed stably.
[0036]
As described above, one embodiment of the present invention has been described, but the present invention is not limited to such an embodiment, and can be variously modified and implemented without departing from the gist of the present invention.
For example, in the above-described embodiment, only the latest air pressure information is updated and stored in the memory 10, but a plurality of air pressure information is stored, and a warning state is issued for each of the air pressure information. A determination may be made as to whether or not a warning state is determined based on information (for example, an average value) representative of the air pressure information. In this case, an accurate determination can be made by leveling out detection errors and variations of the tire pressure detection device.
[0037]
Further, in the above-described embodiment, one receiving antenna 5 is provided near each tire so as to correspond to the wireless transmitter 3 provided inside the four wheels 11. When the radio signal transmitted from the receiver is sufficiently large, or when the reception sensitivity of the reception antenna 5 is high, the configuration may be such that one reception antenna 5 receives the radio signals from all the radio transmitters. . In this case, each of the wireless transmitters 3 provided inside each wheel 11 transmits the air pressure signal and the tire position information by radio, and the receiver 4 determines the respective air pressure information and tire position information. With such a configuration, the same effect as that of the present embodiment can be obtained while reducing the number of receiving antennas 5 provided in the vehicle 20.
[0038]
In the above embodiment, the receiving antenna 5 receives the air pressure signal transmitted from the wireless transmitter 3, converts the air pressure signal into a signal that can be processed by the CPU 8, and transmits the signal to the CPU 8. However, the receiving antenna 5 may be configured to simply receive a radio signal, and the CPU 8 may be configured to have a function as a receiver instead.
[0039]
【The invention's effect】
As described in detail above, according to the tire pressure detecting device of the present invention described in claim 1, the detected pressure information is updated regardless of the state of the engine switch, and the determination of the warning state is made by the engine switch. Since the determination is performed only when the engine is turned on, it is possible to perform appropriate air pressure determination even immediately after the engine switch is turned on, and it is possible to prevent a malfunction due to a change in air pressure due to a decrease in outside air temperature or the like. Further, it is possible to prevent the occurrence of the judgment delay time (judgment lag).
[0040]
In particular, according to the tire pressure detection device of the present invention, when the engine switch is turned on, if the previous determination does not require a warning, a warning is required if the detected pressure information falls below the warning start threshold. If the previous determination required a warning, if the detected pressure information is equal to or greater than a warning end threshold value that is greater than the warning start threshold, it is determined that no warning is required. When a decrease in the tire pressure below the warning start threshold due to a decrease in the outside air temperature is detected, and then when the engine switch is turned on, the tire pressure becomes almost a normal value (between the warning start threshold and the warning end threshold, When the vehicle returns to the range where the warning does not need to be started), the warning is not issued and the warning of the tire pressure can be accurately determined.
[0041]
Further, according to the tire pressure detecting device of the present invention, since the transmitting means and the receiving means perform wireless communication, the device can be reduced in size and weight, and the manufacturing cost can be reduced. Can be reduced. Further, it is not necessary to connect the transmitting device and the receiving device by wire.
Further, according to the tire pressure detecting device of the present invention, when the vehicle is stopped, the tire pressure is detected in the first detection cycle, and when the vehicle is running, the tire pressure is shorter than the first detection cycle. Since the detection is performed in two detection cycles, the operation of the transmitting device and the receiving device can be suppressed to an appropriate period, and the amount of energy consumption such as power can be suppressed.
[0042]
According to the tire pressure detecting device of the present invention, since the determination of the stop or the running of the vehicle is performed based on the radial acceleration of the tire, which is generated with the rotation of the tire, it is easy and accurate. Determination can be performed.
[Brief description of the drawings]
FIG. 1 is a diagram showing a tire air pressure detection device as one embodiment of the present invention, in which (a) is an overall configuration diagram of a vehicle provided with the device, and (b) is provided with a main part of the device. FIG. 3 is a vertical cross-sectional view showing the configuration inside the wheel, and FIG.
FIG. 2 is a control flow chart showing a control operation of a tire pressure detection device as one embodiment of the present invention, where (a) is a control flow chart for detecting and updating and storing detected pressure information, and (b). FIG. 4 is a control flowchart for determining detected pressure information.
FIG. 3 is a graph illustrating a relationship between a change in tire air pressure and a warning operation in a vehicle equipped with a tire air pressure detecting device according to an embodiment of the present invention, and FIG. And (b) is a graph showing a decrease in tire air pressure due to a tire failure.
[Explanation of symbols]
1 tire pressure detecting device 2 tire pressure detector (tire pressure detecting means)
3 wireless transmitter (transmission means)
4 Judgment control device 5 Receiving antenna (receiving means)
6 display (warning means)
7 Centrifugal switch 8 CPU
10 memory (storage means)
11 Wheel 12 IG switch 21 Control unit (control means)
22 Judgment unit (judgment means)

Claims (5)

Tire pressure detecting means for detecting the tire pressure of the vehicle,
Transmitting means for transmitting the detected pressure information detected by the tire pressure detecting means at a predetermined cycle;
Receiving means for receiving the detected pressure information transmitted by the transmitting means;
Storage means for updating and storing the detected pressure information received by the receiving means for each reception,
Warning means for warning an abnormality of the tire pressure;
Determining means for determining whether or not warning by the warning means is necessary according to the previous determination history;
Control means for controlling the warning means to issue a warning when the determination means determines that a warning is necessary,
The tire pressure detection means, the transmission means, the reception means and the storage means operate regardless of whether the engine switch of the vehicle is on or off,
The determination means does not determine whether or not a warning is required when the engine switch of the vehicle is off. When the engine switch of the vehicle is on, a warning is required based on the detected pressure information stored in the storage means. A tire pressure detection device for determining whether or not the tire pressure is high. The determination means determines that a warning is necessary when the detected pressure information falls below a warning start threshold when the previous determination does not require a warning when the engine switch of the vehicle is on, and when the previous determination is a warning. 2. The tire pressure detecting device according to claim 1, wherein if necessary, if the detected pressure information is equal to or greater than a warning end threshold value that is greater than a warning start threshold value, it is determined that warning is unnecessary. The tire pressure detecting device according to claim 1, wherein the transmitting unit wirelessly transmits the detected pressure information, and the receiving unit wirelessly receives the detected pressure information. The tire pressure detecting means detects the tire pressure at a first detection cycle when the vehicle is stopped, and detects the tire pressure at a second detection cycle shorter than the first detection cycle when the vehicle is running. The tire pressure detecting device according to any one of claims 1 to 3, characterized in that: The tire pressure detecting device according to any one of claims 1 to 4, wherein the determination of whether the vehicle is stopped or running is performed based on a radial acceleration generated as the tire rotates.

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