KR101986313B1 - System and method for mornitoring condition of tire - Google Patents

Abstract

The present invention discloses a system and method for monitoring the condition of a tire. According to the present invention, there is provided a data processing apparatus including a sensing unit sensing state data relating to a state of a tire, a data converting unit receiving the state data from the sensing and converting the state data into first data having a frequency value, A data comparison unit for receiving the data and dividing the data into a predetermined frequency band, a data comparison unit comparing the reference data stored in the predetermined frequency band with the first data, And a state determination unit for determining the state of the tire.

Description

TECHNICAL FIELD [0001] The present invention relates to a system and a method for monitoring a condition of a tire,

Embodiments of the present invention relate to a system and method, and more particularly, to a system and method for monitoring the condition of a tire.

The vehicles that the users are traveling with are made up of many parts, among which the tires have a great effect on the driving of the vehicle, and can be said to be one of the key components for securing the safety of the user.

The driver must vary the speed, steering, etc. according to the driving condition of the vehicle. For example, in snowy roads, the speed should be lowered, the braking should not be suddenly applied, and the economical speed of running depends on the condition of each road surface. Therefore, it is important to accurately measure the information about the running road surface of the vehicle, and promptly transmit it to the driver.

Research is underway to apply the Internet of Things (IOT) to parts of a vehicle, to measure the status of the vehicle in real time and share it with surrounding objects. For this purpose, the driving environment of the vehicle must be accurately measured, and it is possible to obtain accurate information by monitoring the state of the tire in direct contact with the outside.

The above-described background technology is technical information that the inventor holds for the derivation of the present invention or acquired in the process of deriving the present invention, and can not necessarily be a known technology disclosed to the general public prior to the filing of the present invention.

Embodiments of the present invention provide a system and method for monitoring a condition of a tire.

According to an aspect of the present invention, there is provided a data processing apparatus including a sensing unit sensing state data on a state of a tire, a data conversion unit receiving the state data from the sensing and converting the state data into first data, A data comparator for receiving the first data and dividing the first data into a predetermined frequency band, a data comparator comparing the reference data stored in the predetermined frequency band with the first data, And a state determination unit for determining the state of the tire in consideration of the result.

The data dividing unit may further include a data calculating unit that receives the divided first data received from the data dividing unit, and sums each value according to the predetermined frequency band.

The sensing unit may measure at least one of the internal pressure, wear, vibration, noise, temperature, load, road surface condition, and rotation speed of the tire.

Also, the data division unit may divide the first data by excluding a frequency band of a part of the entire continuous frequency band of the first data.

In addition, the reference data may have a reference pattern generated by accumulating values for the preset frequency bands.

In addition, the reference data may have a reference pattern corresponding to the traveling speed of the tire.

In addition, the reference data may be generated by machine learning of the state data previously received by the sensing unit, and may have information on the state of each tire.

In addition, the sensing unit may measure the state data of the tire based on the running speed of the vehicle, and the data comparing unit may compare the reference data corresponding to the running speed of the vehicle.

In addition, the reference data may be stored in a plurality of ways according to the road surface condition or wear of the tire.

The apparatus may further include a data correction unit for correcting the values of the respective frequency bands of the first data divided into the predetermined frequency bands to values of the corresponding frequency bands of the reference data.

According to another aspect of the present invention, there is provided a method for controlling a tire, comprising the steps of: sensing state data on a state of a tire; converting the sensed state data into first data that is a value for frequency; Comparing the reference data with the first data for each of the predetermined frequency bands, and determining a running state of the tire in consideration of the comparison result.

Further, before the step of sensing the data, the step of generating the reference data by mechanically learning data on the state of the tire may further include the step of generating the reference data.

The method may further include the step of summing each value of the divided first data by the predetermined frequency band.

The step of sensing the state data may include measuring data having state information of the tire at a traveling speed of the vehicle and comparing the reference data with the first data may include comparing the reference data with the reference data corresponding to the traveling speed of the vehicle, And compare the data with the first data.

The method may further include correcting the value of each frequency band of the first data divided into the predetermined frequency band to the value of each frequency band of the corresponding reference data.

The dividing of the first data may divide the first data except for a frequency band of a certain section in the entire continuous frequency band of the first data.

Also, the reference data may have a reference pattern generated by accumulating values for the preset frequency bands.

The method may further include the step of patterning the first data by accumulating the divided values of the preset data for each of the preset frequency bands.

In addition, the reference data may have the reference pattern according to the running speed of the tire.

Another aspect of the present invention provides a computer-readable recording medium having recorded thereon a program for performing a method for monitoring a condition of a tire.

According to another aspect of the present invention, there is provided a tread structure including a tread portion including a plurality of tread blocks divided by grooves, side walls extending from both sides of the tread portion, and status data Wherein the state data is converted into a value for frequency, divided into predetermined frequency bands, and then compared with reference data.

Other aspects, features, and advantages will become apparent from the following drawings, claims, and detailed description of the invention.

The system and method for monitoring a condition of a tire according to embodiments of the present invention can measure the condition of a tire in real time and compare the measured condition with previously stored reference data to monitor the condition of the tire quickly and accurately.

The system and method for monitoring a condition of a tire according to embodiments of the present invention utilize reference data generated and stored by machine learning, so that the actual state of a tire can be accurately predicted. Reference data can be generated by mechanically learning the environment in which the vehicle actually travels, so that the reliability of prediction can be increased.

The system and method for monitoring a condition of a tire according to embodiments of the present invention can quickly calculate the measured data by separating and patterning the measured data by frequency intervals and comparing the measured data with reference data. The state of the tire can be quickly determined by comparing the pattern of the measured data with the pattern of the reference data.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a schematic diagram of a condition monitoring system for a tire according to the present invention; FIG.
Fig. 2 is a plan view showing the state monitoring system of the tire of Fig. 1 mounted on a vehicle. Fig.
3 is a diagram showing a configuration of a condition monitoring system for a tire according to the present invention.
4 is a diagram showing the configuration of the sensing unit of FIG.
5 is a view showing a pneumatic tire equipped with the sensing part of Fig.
6 is a flowchart showing a method for monitoring the condition of a tire according to the present invention.
7 is a graph showing data measured at the sensing unit or data converted therefrom.
8 is a graph showing data generated by converting the state data of FIG.
9 is a graph showing first reference data used for comparison with the data of FIG.
10 is a diagram showing a process of processing the state data of FIG.
11 is a graph showing second reference data used for comparison with the status data.

BRIEF DESCRIPTION OF THE DRAWINGS The present invention is capable of various modifications and various embodiments, and specific embodiments are illustrated in the drawings and described in detail in the detailed description. The effects and features of the present invention and methods of achieving them will be apparent with reference to the embodiments described in detail below with reference to the drawings. However, the present invention is not limited to the embodiments described below, but may be implemented in various forms.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings, wherein like reference numerals refer to like or corresponding components throughout the drawings, and a duplicate description thereof will be omitted .

In the following embodiments, the terms first, second, and the like are used for the purpose of distinguishing one element from another element, not the limitative meaning.

In the following examples, the singular forms "a", "an" and "the" include plural referents unless the context clearly dictates otherwise.

In the following embodiments, terms such as inclusive or possessive are intended to mean that a feature, or element, described in the specification is present, and does not preclude the possibility that one or more other features or elements may be added.

In the following embodiments, when a part of a film, an area, a component or the like is on or on another part, not only the case where the part is directly on the other part but also another film, area, And the like.

In the drawings, components may be exaggerated or reduced in size for convenience of explanation. For example, the size and thickness of each component shown in the drawings are arbitrarily shown for convenience of explanation, and thus the present invention is not necessarily limited to those shown in the drawings.

Fig. 1 is a schematic view of a state monitoring system 1 of a tire according to the present invention, and Fig. 2 is a plan view showing a state in which the state monitoring system 1 of the tire of Fig. 1 is mounted on a vehicle.

Referring to FIGS. 1 and 2, a state monitoring system 1 of a tire senses a state of a vehicle, that is, a state of a tire in real time, processes it, and can promptly transmit it to a driver or a user. The tire condition monitoring system 1 can transmit information on the temperature of the tire, the pressure wear state, the road surface condition, the speed, etc. to the driver.

The tire 100 and the controller 30 are connected to each other via a communication network so that the state data measured by the tire 100 is transmitted to the controller 30. [ The controller 30 determines the running state of the vehicle based on the received data, and can transmit the running state of the vehicle to the display unit 50 via the communication network.

The tire 100 may be installed in a vehicle and a sensing unit 10 for sensing the condition of the tire 100 may be installed inside the tire 100 or adjacent to the tire 100. The controller 30 may be electrically connected to the sensing unit 10.

In one example, the controller 30 may be embedded in an ECU (electronic control unit) of the vehicle. Thus, as shown in FIG. 3, it is possible to receive and process state data in the vehicle in real time.

In another embodiment, the controller 30 may be in the form of a terminal (not shown). A terminal is connected to a sensing unit to receive data, and the terminal can process data. At this time, the controller 30 can be implemented in the terminal with software such as an application.

The sensing unit 10 and the controller 30 or the controller 30 and the display unit 50 may be connected to each other through a wired / wireless communication network. For example, when implemented as a smartphone, it can be connected to the control unit 230 through a mobile communication network such as the Internet network, LTE (Long Term Evolution), or 3G (3rd generation). As another example, if the sensing unit 10, the controller, and the display unit 50 include a universal serial bus (USB) port, a short distance communication module such as an infrared ray or Bluetooth, (Not shown), and the measured state data and processed data can be transmitted to the controller 30 or the display unit 50 through a third device (not shown).

3 is a diagram showing a configuration of a state monitoring system 1 of a tire according to the present invention.

3, the running condition monitoring system 1 includes a sensing unit 10, a speed measuring unit 20, a controller 30, a storage unit 40, and a display unit 50, The data converting unit 31, the data dividing unit 32, the data calculating unit 33, the data correcting unit 34, the data comparing unit 35 and the state determining unit 36.

The sensing unit 10 is mounted on one side of the vehicle and can measure the state of the tire. The sensing unit 10 may include at least one or more sensing units 10 and may acquire status data.

4 is a diagram showing the configuration of the sensing unit 10 of Fig.

4, the sensing unit 10 may include a first sensor 11, a second sensor 12, a data transmission / reception unit 15, and a power supply unit 16.

The sensing unit 10 may include a plurality of sensors. For example, the first sensor 11 may measure the temperature of the tire, and the second sensor 12 may measure the pressure of the tire. In addition, the third sensor (not shown) can measure the acceleration of the tire. The number of sensors is not limited to this and may be a plurality of sensors for measuring tire temperature, pressure, abrasion condition, road surface condition, speed, vibration, noise, load, etc. to provide information on the running condition, As shown in FIG. The data measured at the sensing unit 10 is defined as state data.

The data transmission / reception unit 15 can transmit the status data measured by the plurality of sensors to the controller 30. The transmission method of the data transmission / reception unit 15 is not limited to the specific method. For example, the data transmitting and receiving unit 15 can transmit and receive status data using a short distance communication method using Bluetooth, infrared, or the like. The data transmitting and receiving unit 15 may be connected to the controller 30 by wire or wireless and may be connected to the controller 30 through an Internet network or a mobile communication network such as LTE (Long Term Evolution) or 3G (3rd Generation) Lt; / RTI >

The power supply unit 16 may supply power to the sensing unit 10. The power supply unit 16 may be mounted on the sensing unit with a battery. Also, the power supply unit 16 may be charged by a short-distance wireless charging method.

The sensing unit 10 can measure data having at least one of internal pressure, wear, vibration, noise, temperature, load, and rotation speed of the tire. For example, a pressure sensor installed inside a tire can measure changes in pressure inside the tire during driving, and can measure the wear of the tire through imaging or vibration, measure vibration or noise of the vehicle, measure the temperature inside the tire Or the rotational speed (rpm) of the tire can be measured.

Referring again to FIG. 3, the speed measuring unit 20 is a device for measuring the running speed of the vehicle, and a sensor for measuring the running speed of a conventional vehicle can be applied. The speed measuring unit 20 is interlocked with the sensing unit 10, and the data measured by the sensing unit 10 may include information on the traveling speed of the vehicle. For example, if the sensing unit 10 is a sensor for measuring the internal pressure of the tire, the internal pressure at a specific traveling speed can be measured in real time, reflecting the traveling speed of the vehicle.

The controller 30 can process the state data and convert the state data, and then compare the reference data with the reference data to determine the running state of the vehicle.

The data converting unit 31 may convert the state data received from the sensing unit 10 into first data having a frequency value. Thus, the first data may have a value for frequency. Referring to FIG. 7, the data conversion unit 31 may set the state data to a power value for a continuous frequency. That is, the data converting unit 31 may process the state data received from the sensing unit 10 into the first data for comparison with the reference data.

The data dividing unit 32 may receive the first data from the data converting unit 31 and may divide the first data into a predetermined frequency band. The first data having the state information of the tire has a specific value in a specific frequency interval. Therefore, in comparison with the reference data, the first data can be divided into predetermined frequency bands in order to easily search the running state of the vehicle.

The predetermined frequency band may be set differently according to the received state data. For example, in the sensing unit 10, data having tire pressure information, data having noise information, and data having wear information are different from each other in frequency bands.

The predetermined frequency band may have characteristics of each state. The frequency band which does not exhibit the characteristic of the state of the tire can be omitted. Therefore, the state of the tire can be determined by comparing each value of the frequency band with the reference data. A detailed description thereof will be given later.

The data calculator 33 may sum up the values for the respective frequency bands in the data divider 32. The values of any one of the frequency bands can be accumulated and calculated as accumulated values. Referring to FIGS. 7 and 8, if the data is divided into nine frequency bands, the data calculator 33 may sum up the values of the respective bands and calculate nine values as shown in FIG.

The first data of the data correction unit 34 can be corrected and approximated. The data correction unit 34 can remove noise from the first data and improve the reliability and accuracy of the data.

For example, the data correction unit 34 can approximate the first data type to any one of a plurality of reference data types. Referring to FIG. 7, the first data may have a specific graph form. You can find reference data that is similar to this type and remove the noise to correct the data.

The noise portion may be a large portion of difference between the two data. In addition, if the first data and the reference data are compared and there is a difference in some values, the first data and the reference data can be interpolated and corrected to the value of the reference data.

As another example, the data correcting unit 34 may compare the value calculated by the data calculating unit 33 with the value of the reference data, and correct the value summed for each frequency band of the first data to the reference data value. In detail, as shown in FIG. 8, the accumulated values for each of the nine frequency bands have a predetermined difference from the respective values of the reference data. The data corrector 34 may interpolate the difference to correct the value accumulated for each frequency band in the first data to the value of the corresponding reference data.

The reference data is generated by machine learning, and is stored in the storage unit 40. Referring to FIG. 9, the reference data is represented by a value for a frequency including information on a running state.

The reference data may be stored in a plurality of ways according to the traveling environment of the vehicle. In Fig. 9, R 1, R 2, R 3 and R 4 denote the ground state, respectively. For example, R1 may be in a dry state, R2 may be a rough state, R3 may be a wet state, and R4 may be a snow state. The reference data can be stored as respective data values according to the respective ground state.

The reference data may have a reference pattern generated by accumulating for each preset frequency band. Referring to FIG. 9, the reference pattern has a frequency component sum value for each frequency band. That is, since each frequency band has a characteristic of determining the traveling state, it is divided into respective frequency bands, and the respective frequency bands are stored by summing the values.

Also, the reference data can be stored in a plurality of ways according to the traveling speed of the vehicle. In Fig. 9, each of R1 to R4 is stored in accordance with the traveling speed. The running speed of the vehicle changes the frequency value for determining the start state. That is, the running speed of the vehicle is an element for determining the running state. Therefore, the reference data is stored for each speed. For example, reference data of 50 km / h and 60 km / h are different.

The data comparing unit 35 may compare the reference data stored in the predetermined frequency band with the first data. The data comparing unit 35 compares each sum value for each frequency band of the first data and each sum value for each frequency band of the reference data. The reference data is divided into frequency bands in advance according to the respective running states, and the reference data is summed for each divided band and stored in the storage unit 40. Therefore, the data comparison unit 35 compares the sum value of each frequency band of the first data with the sum value of each frequency band of the stored reference data, and compares the sum values with each other.

The data comparison section 35 can compare the speed of the vehicle in consideration of the traveling speed of the vehicle. The first data has information on the traveling speed of the vehicle measured by the speed measuring unit 20. [ The data comparing unit 35 compares the reference data at the speed measured by the speed measuring unit 20 with the first data. For example, if the vehicle 10 measures 50 km / h, the first data is compared with the reference data at 50 km / h among the reference data.

The state determination unit 36 can determine the state of the tire in consideration of the comparison result in the data comparison unit 35. [ If the difference between the sum of the frequency bands of the first data and the sum of the frequency bands of the stored reference data falls within the error range, the state determination unit 36 assumes that the first data is the reference data. When the reference data very similar to the first data is selected, the running state of the tire is determined as the running state of the tire of the reference data. For example, when the selected reference data has a running state called wet road surface, the state determining section 36 can determine that the vehicle is running on a wet road surface.

The storage unit 40 may store reference data. Since the reference data is generated by mechanically learning the measured state data, the processed first data can be stored as reference data.

The display unit 50 displays information on the running state of the vehicle determined by the status display unit 50, and can be confirmed by the user or the driver. The display unit 50 is not limited to a specific form, and may have, for example, the form of an instrument panel of a vehicle, so that the driver can monitor in real time. In addition, since the terminal has a display form, the user can check the running state of the vehicle through the terminal.

FIG. 5 is a view showing the pneumatic tire 100 on which the sensing unit 10 of FIG. 4 is mounted.

5, the pneumatic tire 100 includes a tread portion 110, a pair of sidewalls 120 connected to the tread portion 110, a bead portion 130 disposed at a lower portion of each of the sidewalls 120, A belt layer 140 and a carcass layer 150 located under the tread portion 110 and an inner liner 160 attached to the inner side surfaces of the carcass layer 150 and the tread portion 110 And an expansion unit 170 positioned on the inner side.

The tread portion 110 is located on the outermost side of the tire and is formed of a thick rubber layer to transmit the driving force and the braking force of the vehicle to the ground. The surface of the tread portion 110 has a tread pattern for steering stability, traction, and braking performance. The tread portion 110 may have a tread block 116 which is divided by a groove 114 and a groove 114 in the running direction or the transverse direction.

The tread patterns may include grooves 114 for drainage on running on wet roads and sipes for improving traction and braking forces. The groove 114 may include a transverse groove between the circumferential groove and the circumferential groove that coincides with the running direction of the vehicle. The sipes are formed in the tread block 116 and may be grooves having a smaller size than the grooves. The siphon absorbs moisture at the time of traveling on a wet road surface and breaks the water film, so that the driving force and the braking force of the pneumatic tire 100 can be increased.

The tread block 116 is an area occupying most of the tread portion 110 and directly contacts the ground to transmit the driving force and the braking force of the vehicle to the ground.

The sidewall 120 is disposed to extend downward from the end of the tread portion 110. The sidewall 120 is a side portion of the pneumatic tire 100 to protect the carcass layer 150, to provide lateral stability of the pneumatic tire 100, and to enhance ride comfort by performing a bending motion. The sidewall 120 serves to transmit the torque of the engine received through the drive shaft to the tread portion 110.

The bead portion 130 is provided at the end of the sidewall 120 and serves to mount the pneumatic tire 100 on the rim. The bead portion 130 may include a bead core 132 and a bead filler 134. The bead core 132 may be formed by twisting a plurality of rubber-coated steel wires, and the bead filler 134 may be rubber adhered to the bead core.

The belt layer 140 is disposed beneath the tread portion 110 to reduce the impact of the road surface while the vehicle is running and to protect the carcass layer 150. The belt layer 140 serves to secure the stability of travel by keeping the ground surface of the tread wide. Further, the belt layer 140 may be formed by rolling a plurality of belt cords made of steel or organic fiber material with rubber.

In one embodiment, the belt layer 140 includes a first belt layer 141 and a second belt layer 143 superimposed on each other. The first belt layer 141 is located on the second belt layer 143 and the width of the first belt layer 141 may be less than the width of the second belt layer 143.

The cap ply 145 may further be interposed between the tread portion 110 and the belt layer 140. The cap ply 145 can improve performance when traveling with a special cord fabric that is deposited on the belt layer 140. The cap ply 145 may comprise, for example, polyester synthetic fibers.

The carcass layer 150 is disposed below the belt layer 140 and forms the skeleton of the pneumatic tire 100. The carcass layer 150 is a pneumatic tire that can withstand the load, . Specifically, the carcass layer 150 includes at least one rubber component selected from the group consisting of synthetic rubber and natural rubber, and may include at least one tire cord. As the tire cord, various natural fibers or rayon, nylon, polyester and Kevlar can be used, and a steel cord formed by twisting a plurality of thin wires can also be used.

 In one embodiment, the carcass layer 150 may comprise a first carcass layer 151 and a second carcass layer 153 superimposed on each other. The first carcass layer 151 is turned up at the bead portion 130 and extends toward the tread portion 110. One end of the turn-up first carcass layer 151 may extend to cover the inside of the sidewall 120 to improve the rigidity of the sidewall 120. The second carcass layer 153 is located on the first carcass layer 151 and extends toward the tread portion 110 by turning up at the bead portion 130 and the second carcass layer 153 turned- One end of the first carcass layer 151 may be shorter than the one end of the first carcass layer 151 to cover the inside of the bead portion 130. In the present embodiment, the structure in which the carcass layer 150 is formed of two carcass layers is described, but the present invention is not limited thereto. As another example, the carcass layer 150 may be formed as a single layer.

The inner liner 160 may be a layer for preventing air leakage of the pneumatic tire 100 in place of the tube, and may be formed of a rubber layer having excellent airtightness. For example, the inner liner 160 may be made of butyl rubber or the like having a high density and can maintain the air pressure in the pneumatic tire 100.

The sensing unit 10 may be mounted inside the pneumatic tire 100. It can be mounted under the tread as shown in Fig. 5 to sense the state of the tire. In another embodiment, it may be mounted on a wheel of a tire. The sensing unit 10 is connected to the controller 30 and can transmit the measured state data of the pneumatic tire.

6 is a flowchart showing a method for monitoring a condition of a tire according to the present invention.

A method for monitoring a state of a tire includes a step (S5) of generating and storing reference data by machine learning state data, a step (S10) of sensing state data on the state of the tire, a step (S30) of dividing the first data by a predetermined frequency band, adding each value of the first data to each of the preset frequency bands (S40), converting the frequency of the first data (S50) of comparing the reference data with the first data (S60) for each predetermined frequency band, and determining the state of the tire (S70 ).

The step S5 of generating and storing the reference data by machine learning of the state data generates the reference data by machine learning the result of processing the state data described below and stores the generated data in the storage unit 40. [ The result of processing the state data may have information about the speed of the vehicle, a value corresponding to the frequency, or a value per frequency band. In addition, the state data can be converted and stored in a reference pattern.

The step S10 of sensing the state data on the state of the tire enables the sensing unit 10 to measure the running state of the tire. The condition of the tire may be related to the temperature, pressure, abrasion, road surface condition, speed, etc. of the tire. Hereinafter, for convenience of explanation, the road surface condition will be mainly described.

The step S20 of converting the state data into the first data, which is a value for the frequency, may convert the state data to have a frequency-dependent value in the data conversion unit 31 in order to compare the data according to the frequency.

7 is a graph showing data measured at the sensing unit or data converted therefrom. Referring to FIG. 7, the data converting unit 31 may convert the state data into first data having a power value according to a frequency. However, if the measured state data is represented by a function having a frequency as a variable, the step of converting data may be omitted.

The step of dividing the first data by predetermined frequency bands (S30) may divide the converted first data by preset frequency bands. The predetermined frequency band has a different value depending on the state of the tire. Therefore, the predetermined frequency band serves as an element for determining the state of the tire. Referring to FIG. 7, the frequency band is divided into nine sections. Each of the sections A to I is a section capable of indicating the running state of the tire.

The predetermined frequency band may exclude a frequency band of some interval in the continuous whole frequency band of the first data. The preset frequency band can be set except for the frequency band where some driving characteristics can not be displayed. This is to eliminate the unnecessary operation factors to improve the operation speed and accurately determine the running state of the tire. In FIG. 9, the frequency band between the section A and the section B is excluded because it is not a frequency band for determining the running state.

The step S40 of summing the respective values of the first data by the preset frequency bands may add up the values for each of the divided frequency bands. Each divided frequency band can have an error every time it is measured. However, since the overall average in each frequency band is kept constant, the values in the respective frequency bands can be summed up to improve the accuracy of the calculation. That is, the calculation error can be reduced by summing the values of the respective frequency bands.

8 is a graph showing data generated by converting the state data of FIG.

Referring to FIG. 8, a frequency component sum is obtained for each frequency interval. The summed value for each frequency section is a value having traveling information of the measured state data. Since each frequency has a specific value, it can be quickly compared with the reference data in the data comparison unit.

The step of correcting the value of the frequency band of the first data to the value of the frequency band of the data corresponding to the reference data (step S50) includes the step of removing the noise from the first data by the data correcting unit 34 to improve the reliability and accuracy of the data .

The step of correcting may be performed before dividing the first data by the preset frequency bands. For example, the data correction unit 34 can approximate the first data type to any one of a plurality of reference data types. Referring to FIG. 7, the first data may have a specific graph form. You can find reference data that is similar to this type and remove the noise to correct the data. The noise portion may be a large portion of difference between the two data. In addition, if the first data and the reference data are compared and there is a difference in some values, the first data and the reference data can be interpolated and corrected to the value of the reference data.

The step of correcting may be performed after the first data is added for each frequency band. For example, the data correction unit 34 may compare the value calculated by the data calculation unit 33 with the value of the reference data, and correct the summed data value to the reference data value. As shown in FIG. 8, the accumulated value for each of the nine frequency bands has a predetermined difference from the respective values of the reference data. The data corrector 34 may interpolate the difference to correct the value accumulated for each frequency band in the first data to the value of the corresponding reference data.

The step S60 of comparing the reference data with the first data for each of the preset frequency bands may be performed by the data comparator 35 so that the respective sum values for the respective frequency bands of the first data and the respective sum values for the respective frequency bands of the reference data With the summed value of. The reference data is divided into frequency bands in advance according to the respective states, and the reference data is summed for each divided band and stored in the storage unit 40. Therefore, the data comparator 35 compares the sum value of each frequency band of the first data with the sum value of each frequency band of the stored reference data, and compares the sum values with each other.

The step S60 of comparing the reference data with the first data for each of the predetermined frequency bands may be performed in consideration of the traveling speed of the vehicle. The first data has information on the traveling speed of the vehicle measured by the speed measuring unit 20. [ The data comparing unit 35 compares the reference data at the speed measured by the speed measuring unit 20 with the first data.

9 is a graph showing first reference data used for comparison with the data of FIG.

Referring to FIG. 9, in step S60, the first reference data and the first data are compared with each other in a predetermined frequency band. The sum of the first data in FIG. 8 and the first reference data in FIG. 9 are compared .

If the sensing unit 10 measures driving at a speed of 50 km / h, the first data is compared with the reference data at 50 km / h among the first reference data of R1, R2, and R3.

The first reference data is patterned and stored. That is, as shown in Fig. 9, the first reference data has a pattern specified according to each running state and traveling speed. Since the first data is patterned for each frequency band, it can be quickly compared with the first reference data.

The step of determining the running state of the tire (S70) can determine the traveling state of the tire in consideration of the comparison result in the data comparing section (35) in the state determining section (36). If the difference between the sum of the frequency bands of the first data and the sum of the frequency bands of the stored first reference data falls within the error range, the state determination unit 36 determines that the first data is the first reference data I suppose.

If the first reference data very similar to the first data is selected, the running state of the tire is determined as the running state of the tire of the first reference data. For example, if the first data is compared with the first data at a speed of 50 km / h among the reference data of R1, R2, and R3, and if the pattern of the first data is similar to the pattern of R2, 36) can determine that the vehicle is traveling in the R2 state (wet road surface).

Thereafter, the display unit 50 displays information regarding the running state of the vehicle determined by the status display unit 50, and can be confirmed by the user or the driver.

10 is a diagram showing a process of processing the state data of FIG.

Referring to FIG. 10, it is possible to perform the intermediate processing of the state data and to calculate it with accuracy and speed. When the data having the respective characteristics are input to the controller 30 (input layer), the input data is corrected (hidden layer), and then compared with the first reference data based on the corrected data (Output layer).

Since the present invention pre-processes the input data in the correction step, the data can be processed quickly. For example, the data correction unit 34 may correct the nine characteristic values so as to converge on the values of the reference data. As another example, the nine characteristic values may be divided into four groups, and the values of the four groups may be summed and compared with the reference data.

11 is a graph showing second reference data used for comparison with the status data.

Referring to FIG. 11, the second reference data has information about wear of the tire. 11 shows the case where the second reference data is R5 where the wear degree of the tire is 0%, R7 is 40% and R6 is 80%, but the present invention is not limited to this and may be reference data for a plurality of abrasions.

The second reference data may be stored in the machine learning like the above-described first reference data. The sensing unit measures state data relating to wear of the tire, and the controller converts the state data into first data relating to the frequency. Thereafter, the first data may be divided into a predetermined frequency and generated and stored as second reference data.

The state monitoring system of the tire can monitor the wear of the tire by comparing it with the second reference data based on the state data on the tire wear measured at the sensing part. That is, if the pattern of the state data measured at the sensing unit is similar to or coincident with any one of the second reference data, the state of the tire is determined to have the selected wear degree.

The state monitoring system of the tire may be determined using the learning model as shown in FIG.

The state monitoring system of the tire and the state monitoring method of the tire of the present invention can measure the state of the tire in real time and monitor the state of the tire quickly and accurately by comparing with the previously stored reference data.

The state monitoring system of the tire and the state monitoring method of the tire of the present invention utilize the reference data generated and stored by machine learning, so that the state of the tire can be accurately predicted. Reference data can be generated by mechanically learning the environment in which the vehicle actually travels, so that the reliability of prediction can be increased.

The tire condition monitoring system and the tire condition monitoring method of the present invention can quickly calculate the measured data by separating and patterning the measured data by frequency section and comparing it with the reference data. The traveling state can be determined by comparing the pattern of the measured data with the pattern of the reference data, so that the calculation can be performed quickly.

The tire condition monitoring system and the tire condition monitoring method of the present invention can pre-process the measured data to predict the running condition of the vehicle quickly. Further, since the reference data and the measured data are compared with each other based on the speed of the vehicle, the running state can be quickly determined.

Meanwhile, the present invention can be embodied in computer readable code on a computer readable recording medium. A computer-readable recording medium includes all kinds of recording apparatuses in which data that can be read by a computer system is stored. Examples of the computer-readable recording medium include ROM, RAM, CD-ROM, magnetic tape, floppy disk, optical data storage, and the like.

In addition, the computer-readable recording medium may be distributed over network-connected computer systems so that computer readable codes can be stored and executed in a distributed manner. In addition, functional programs, codes, and code segments for implementing the present invention can be easily deduced by programmers skilled in the art to which the present invention belongs.

Unless there is explicitly stated or contrary to the description of the steps constituting the method according to the invention, the steps may be carried out in any suitable order. The present invention is not necessarily limited to the order of description of the above steps.

The use of all examples or exemplary language (e.g., etc.) in this invention is for the purpose of describing the present invention only in detail and is not intended to be limited by the scope of the claims, But is not limited thereto. It will also be appreciated by those skilled in the art that various modifications, combinations, and alterations may be made depending on design criteria and factors within the scope of the appended claims or equivalents thereof.

While the present invention has been particularly shown and described with reference to exemplary embodiments thereof, it is to be understood that the invention is not limited to the disclosed embodiments, but, on the contrary, is intended to cover various modifications and equivalent arrangements included within the spirit and scope of the appended claims. Accordingly, the true scope of the present invention should be determined by the technical idea of the appended claims.

1: Tire condition monitoring system
10: sensing unit
20: speed measuring unit
30: Controller
31: Data conversion unit
32:
33: Data calculation unit
34: Data correction unit
35:
36:
40:
50:
100: Tire

Claims (21)

A sensing unit for sensing state data relating to the state of the tire;
A data conversion unit that receives the state data from the sensing and converts the state data into first data having a frequency value;
A data divider that receives the first data from the data converter and divides the first data into a predetermined frequency band;
A data comparing unit comparing the reference data stored in the predetermined frequency band with the first data;
A state determining unit for determining a state of the tire in consideration of a comparison result in the data comparing unit; And
And a data calculator for receiving the divided first data transmitted from the data divider and for summing each value for each of the predetermined frequency bands. delete The method according to claim 1,
The sensing unit
Wherein the information about at least one of an internal pressure, an abrasion, a vibration, a noise, a temperature, a load, a road surface state, and a rotation speed of the tire is measured. The method according to claim 1,
The data divider
And divides the first data by excluding a frequency band of a certain section in a continuous whole frequency band of the first data. A sensing unit for sensing state data relating to the state of the tire;
A data conversion unit that receives the state data from the sensing and converts the state data into first data having a frequency value;
A data divider that receives the first data from the data converter and divides the first data into a predetermined frequency band;
A data comparing unit comparing the reference data stored in the predetermined frequency band with the first data; And
And a state determination unit for determining a state of the tire in consideration of a comparison result in the data comparison unit,
The reference data
And a reference pattern generated by accumulating values for each of the preset frequency bands. 6. The method of claim 5,
The reference data
And a reference pattern corresponding to the running speed of the tire. 6. The method of claim 5,
The reference data
Wherein the sensing unit is generated by mechanically learning state data previously received from the sensing unit and has information on the state of each tire. 6. The method of claim 5,
The sensing unit measures the state data of the tire based on the traveling speed of the vehicle,
Wherein the data comparison unit compares the reference data corresponding to the running speed of the vehicle. 6. The method of claim 5,
Wherein the reference data is stored in plurality according to a road surface condition or wear of the tire. 6. The method of claim 5,
And a data correction unit for correcting the value of each frequency band of the first data divided into the predetermined frequency band to the value of each frequency band of the corresponding reference data. Sensing state data relating to the state of the tire;
Converting the sensed state data into first data that is a value for a frequency;
Dividing the first data by a predetermined frequency band;
Summing the first data by each divided frequency band;
Comparing the reference data with the first data for each of the preset frequency bands; And
And determining a running condition of the tire in consideration of the comparison result. 12. The method of claim 11,
Further comprising: mechanically learning data about a state of the tire prior to sensing the data to generate the reference data. delete 12. The method of claim 11,
The step of sensing the state data comprises:
Measuring data having state information of the tire at a running speed of the vehicle,
Wherein the step of comparing the reference data with the first data comprises:
And compares the first data with the reference data corresponding to the running speed of the vehicle. 15. The method of claim 14,
And correcting a value of each frequency band of the first data divided into the predetermined frequency band to a value of each frequency band of the reference data corresponding to the frequency band of the first data. 12. The method of claim 11,
The step of dividing the first data
Wherein the first data is divided by excluding a frequency band of a certain section in a continuous whole frequency band of the first data. 12. The method of claim 11,
The reference data
And a reference pattern generated by accumulating values for each of the preset frequency bands. 18. The method of claim 17,
And accumulating the divided first data values for each of the preset frequency bands to pattern the first data. 18. The method of claim 17,
Wherein the reference data has the reference pattern according to the traveling speed of the tire. A computer-readable recording medium on which a program for performing the method according to any one of claims 11, 12, 14 to 19 is recorded. delete

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