JP2005134162A - Method for measuring corrosive environment of mobile body, design method, method for corrosion test of material of mobile body, selection method, surface treated steel sheet, and anti-corrosion steel product - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a quantitative corrosive environment measuring method of mobile bodies in severe environmental changes and to provide a design method for the anti-corrosive structure and anti-corrosive design of the mobile bodies. <P>SOLUTION: One corrosion sensor or more which comprise two types of metal electrodes or more having different components and/or compositions and which contain one type of constituent component or more of the material of a mobile body to be measured in either of the metal electrodes and in which at least a pair of electrodes are arranged on both sides of an insulator in such a way that their interval may be between 0.1-5 mm are arranged at one part or more of the mobile body in which at least its part is constituted of metal materials. A current or a potential difference between the electrodes due to an electrical short circuit of the electrodes in corrosive environments is continuously or intermittently measured also during movements in the method for measuring corrosive environments of mobile bodies. <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

  The present invention relates to a corrosive environment measurement method and a design method of a mobile object using a corrosion sensor, and a corrosive environment in which each part using a metal material of a mobile object such as an automobile, a ship, and an aircraft is exposed in an actual use state, and The present invention relates to a corrosion test method and selection method for a mobile material, a surface-treated steel sheet and a corrosion-resistant steel material.

  Corrosion environment measurement of non-moving structures has been reported by continuous corrosion environment measurement methods based on various principles such as galvanic corrosion sensors, QCMs and AC impedance corrosion sensors, as represented by measurements in bridges and houses. Has been. Each of these methods is a method for obtaining information on the corrosive environment at a specific geographical location where the target structure is installed. Information obtained by measurement is intermittent or continuous change of current value, impedance, and the like. In these corrosive environment measurements, temperature and humidity are also measured at the same time in addition to the corrosive sensor, and the wetting time and the amount of incoming salt are determined from the corrosive and environmental sensor measurements. Furthermore, a method is known in which the exposure rate of a metal material at a specific topographical location where the amount of incoming salt is known is compared with the measurement results of a corrosion sensor and an environmental sensor to determine the corrosion rate and corrosion life.

  For example, the following is known for measuring the corrosive environment of a moving object.

  Corrosion environment measurement using a single AC impedance type corrosion sensor on the back of an oil tanker deck is shown. The configuration of the impedance type corrosion sensor uses the same two types of metal electrodes. Changes in impedance of corrosion sensors during oil tanker voyages are measured intermittently by applying an AC signal from an external power source. (For example, refer nonpatent literature 1.).

  An example is shown in which a corrosive environment of each part of an automobile is continuously measured by a thermohygrometer without stopping and moving. In this example, only the wet state is measured. (For example, refer nonpatent literature 2.).

As a corrosion test in an actual vehicle, an exposure test (On Vehicle Test) is performed in which a test piece is attached to an actual vehicle, and the vehicle is run instead of being attached to the exposure frame. These can obtain information on the corrosion resistance and corrosive environment of the material from the change in the corrosion state of the test piece before and after the test.
Materials and Environment 2002 Lecture Proceedings p101 Materials and Processes CAMP-ISIJ Vol.2 (1989) -1690

  In recent years, with the growing awareness of reducing environmental impacts such as life cycle costs, not only long-lived social capital such as bridges and houses, but also rust-proof life is optimally considered for mobile objects such as automobiles and airplanes What is done is required. However, the rust-preventing life of these moving bodies is strongly influenced by the use state and the environment (moving environment) during movement of the moving body even in the same region. Further, even in a single moving body, for example, there are various structures such as an externally exposed part and a part where steel plates overlap each other, and the corrosive environment to be exposed is different. For this reason, there is a need for a corrosive environment measuring method that continuously or intermittently measures the corrosive environment including when each part is moved, and enables optimization of material selection and structural design.

  In the conventional measurement of the corrosive environment of the structure, since there is no movement of the structure, the incoming salinity, temperature, relative humidity, etc. were all environmental factors associated with the topographic specific environment. On the other hand, when the moving body moves, the terrain environment changes, and when the environment changes extremely due to physical factors (for example, vibration, dust accumulation / dropping, water / mud splash adhesion / drying, etc.) There is. However, there is no knowledge that quantitative corrosion environment measurement has been carried out on a moving body that has a severe environmental change accompanying vibration and movement.

  Furthermore, in the oil tanker shown in Non-Patent Document 1, two metal electrodes of the same type are used in the corrosion environment measurement using an AC impedance type corrosion sensor. However, since the AC impedance type corrosion sensor cannot obtain an output unless there is sufficient liquid junction between the metal electrodes, there is a possibility that a minute amount of corrosion due to minute wetting such as a dew condensation phenomenon cannot be monitored. In addition, measurement requires the installation of external input devices for impedance measurement such as potentiostats and frequency response analyzers, so the durability of the devices and the risk of noise generation for moving bodies such as automobiles There is a problem.

  In the environmental measurement of the automobile shown in Non-Patent Document 2, the change in the terrain corrosive environment accompanying the movement of the automobile and the change in the corrosive environment due to physical factors are not specified. In addition, the wetting sensor installed has an unclear structure and its output is evaluated only for ON and OFF, and the relationship between the sensor output and wetting and corrosion is completely unknown.

  On Vehicle Test is a technique that can directly measure the corrosivity of the environment in the actual use environment, but it takes a long time for the test piece to corrode sufficiently and to evaluate the superiority or inferiority of the corrosion resistance. Furthermore, since corrosion of the test piece cannot be continuously monitored, it is difficult to capture environmental factors (for example, attached salt content and wetting) that control the corrosion. Therefore, the test result is an evaluation limited to the specific area where the test was conducted.

  Therefore, an object of the present invention is to provide a design method for a rust prevention structure and a rust prevention design of a mobile body by performing a quantitative corrosion environment measurement method for a mobile body having a severe environmental change. Furthermore, another object of the present invention is to provide a corrosion test method for appropriately evaluating the corrosion resistance of a moving body material based on the measurement result of a corrosive environment by a corrosion sensor, an optimal selection method for the moving body material, and a moving body material. Another object of the present invention is to provide a surface-treated steel sheet and a corrosion-resistant steel material, which are metal materials constituting the moving body selected by the selection method.

  The features of the present invention for achieving such an object are as follows.

  (1) A mobile material that has two or more kinds of metal electrodes having different components and / or compositions at one or more sites of a mobile material, at least a part of which is made of a metal material, One or more corrosion sensors including at least one component and having a gap between at least one pair of electrodes separated by an insulator of 0.1 to 5 mm are installed, and the electrodes are electrically connected in a corrosive environment. A method for measuring a corrosive environment of a moving body, wherein a current or potential difference between electrodes due to a short circuit is measured continuously or intermittently, including when moving.

  (2) The method for measuring a corrosive environment of a moving body according to (1) above, wherein the installation position of the corrosion sensor is inside isolated from the outside of the moving body or inside a constituent part of the moving body.

  (3) A mobile material that has two or more types of metal electrodes having different components and / or compositions at one or more sites of at least a part of the mobile material that is made of a metal material, One or more corrosion sensors including at least one component and having a gap between at least one pair of electrodes separated by an insulator of 0.1 to 5 mm are installed, and the electrodes are electrically connected in a corrosive environment. A method for designing a moving body, wherein the structure of the moving body is designed so that a corrosion sensor output consisting of a current or potential difference between electrodes due to a short circuit or a numerical value calculated from the output falls within a predetermined range.

  (4) A mobile material that has two or more types of metal electrodes having different components and / or compositions at one or more sites of at least a part of the mobile material that is made of a metal material, One or more corrosion sensors including at least one component and having a gap between at least one pair of electrodes separated by an insulator of 0.1 to 5 mm are installed, and the electrodes are electrically connected in a corrosive environment. Corrosion sensor output consisting of current or potential difference between electrodes due to short circuit, or test piece attached to mobile body or mobile body by setting the mobile environment so that the numerical value calculated from the output is within a predetermined range A corrosion test method for mobile materials characterized by performing a corrosion test for evaluating the corrosion resistance of a material.

  (5) Two kinds of metal electrodes having different components and / or compositions are provided at an arbitrary part of a moving body, at least a part of which is made of a metal material, and one of them is a component of the moving body material. One type or two or more types made of the same metal different from this, and arranged such that the gap between the electrodes is 0.1 to 5 mm across the insulator A method for selecting a moving body material, comprising: installing a corrosion sensor, and comparing the output of the corrosion sensor or a numerical value calculated from the output to select a metal material at the site of the moving body.

  (6) A mobile material that has two or more kinds of metal electrodes having different components and / or compositions at one or more sites at least part of which is made of a metal material, and is measured on either of them. One or more corrosion sensors including at least one component and having a gap between at least one pair of electrodes separated by an insulator of 0.1 to 5 mm are installed, and the electrodes are electrically connected in a corrosive environment. A method of selecting a mobile material based on the measurement results of a corrosive environment by a corrosion sensor, which continuously or intermittently measures the current or potential difference between electrodes due to a short circuit, including during movement, in a plurality of regions In the corrosive environment measurement process that measures the corrosive environment at multiple parts of the moving body with a corrosion sensor in the In a new environment and / or in a new area where the moving body is used, comprising a step of measuring the amount and a step of creating a correlation diagram between the corrosion sensor output obtained from the two steps and the amount of corrosion A method for selecting a mobile body material comprising a step of comparing a result of performing a corrosive environment measurement of each part of the body with the correlation diagram and selecting a metal material at a plurality of parts of the mobile body.

  (7) A surface-treated steel sheet and a corrosion-resistant steel material, which are metal materials constituting the movable body selected by the method for selecting a movable body material according to (5) or (6), the surface-treated steel sheet and the corrosion-resistant steel material Corrosion environment measurement data is attached to the surface-treated steel sheet and corrosion-resistant steel.

  According to the present invention, it is possible to evaluate local corrosion of each part of a moving body in an actual use environment. Therefore, appropriate selection of materials for each part of the moving body, or rust prevention structure and rust prevention design of the moving body. Reflection can be expected.

  The present invention is a technique applicable to all movable bodies such as automobiles, motorcycles, railways, and other vehicles, ships, airplanes, and the like that can move by themselves. In the following, embodiments will be described in detail by taking an automobile as a representative example.

  In the present invention, the location where the corrosion sensor is installed on the moving body expected to be effective is a portion where a material is newly applied and a portion which may be exposed to corrosion different from the terrain environment. It is a part of. The corrosive environment that is different from the terrain environment includes the inside isolated from the outside of the moving body, the inside of the constituent parts of the moving body, the parts that are difficult to dry, such as the metal-matching structure, and conversely, the air permeability is good. The site | part etc. where drying is accelerated | stimulated by moving are mentioned.

  In addition, when performing a corrosive environment measurement, an environmental sensor for measuring environmental factors such as temperature, relative humidity, wetting, various gas concentrations, and vibrations can be installed around each corrosion sensor simultaneously to measure the environmental factors. desirable.

  The metal electrode of the corrosion sensor used in the present invention uses two or more kinds of electrodes having different components and / or compositions in order to measure the galvanic current. Here, the galvanic current is a current generated when a different metal forms a battery through a solution or a thin water film, and a corrosion sensor based on such a principle is called a galvanic corrosion sensor. Here, FIG. 3 is a graph showing an example of the relationship between the gap between the metal electrodes of the corrosion sensor and the output of the corrosion sensor at a relative humidity of 100%. From FIG. 3, the corrosion sensor used in the present invention was able to stably obtain an effective output by arranging the gap between at least one pair of metal electrodes to be 5 mm or less. In addition, when the gap exceeds 5 mm, conduction between the electrodes cannot be obtained even in an environment where condensation occurs, and measurement is unstable. On the other hand, when the gap is less than 0.1 mm, a short circuit phenomenon between the electrodes occurred even during drying. In addition, part or all of the gaps between the electrodes may be filled with an insulating material such as resin or ceramic so that the electrodes are electrically short-circuited due to dew condensation or wetting on the surface. Accordingly, the corrosion sensor used in the present invention is arranged so that the gap between at least one pair of electrodes is 0.1 to 5 mm across the insulator.

  It has also been found that when an ammeter with an internal resistance of 0.1Ω or more is connected between the electrodes for detecting the current, the detection sensitivity is remarkably reduced, particularly in the open area. Therefore, it is preferable to connect an ammeter having an internal resistance of 0.1Ω or less between the electrodes.

  According to the study by the present inventors, it was found that at least one type of metal electrode of the corrosion sensor is suitable for measurement if it is a material having the same standard as the constituent material of the actual moving body or the material to be applied. . Further, when the materials are not of the same standard, it is preferable to apply a metal material or a plating material having a component and / or composition close to that of the moving body material in consideration of the constituent components of the moving body material. Since the output of the corrosion sensor is an output based on the corrosion of the metal electrode, the corrosion sensor in which all the metal electrodes are composed of metal components that are not included in the constituent materials of the moving body or the material to be applied cannot obtain an appropriate output. . Further, as a combination of two or more types of electrodes constituting the corrosion sensor, it is desirable to combine a metal electrode whose main component is a moving body constituting material and detecting an output by corrosion, and a metal having a noble electrochemical order. .

  This corrosion sensor does not require an external input to the corrosion sensor, and is limited to a method for directly or indirectly measuring a current or potential difference generated between a plurality of electrodes. Measurement methods that require external input to the sensor, such as the AC impedance method and the quartz crystal microbalance method, are the measurement conditions unique to the moving object, such as changes in the environment, electrical disturbance, and vibration during movement. Due to this, there was a problem in the stable operation of the measuring instrument and the detection of the signal, and it was difficult to apply.

  FIG. 1 shows an example of the configuration of a corrosive environment measuring system in an automobile.

  As shown in FIG. 1, in the present invention, the output of the corrosion sensor is measured or measured / stored or measured / transferred by a measurement system wired so as not to hinder the movement of the moving body. The measurement with the corrosion sensor is carried out so that the output including the movement of the moving body can be obtained. The output of the corrosion sensor is given by the current or voltage between the metal electrodes, but the data to be analyzed needs to include at least data when the moving body moves. Recorded, stored or transferred output data is periodically collected and analyzed by a data analysis system.

  FIG. 5 is a diagram comparing corrosion sensor outputs on the outer surface of the automobile body, inside the door, and below the floor. Corrosion sensor output changes on the outer surface of the body in response to the external environment regardless of whether the vehicle is running or not. However, the inside of the door does not respond to the external environment regardless of whether the vehicle is running or not running, and the output of the corrosion sensor continues to be high even after rain. In addition, even if it is raining under the floor, the output of the corrosion sensor is small when the vehicle is not driven, but the output increases as the vehicle travels, and a relatively high output continues even after the rain stops. For mobile objects, it is shown that the measurement of the corrosive environment of each part including the inside isolated from the outside and the time of movement is particularly important.

  A method for designing a moving body or moving body part of the present invention will be described. When a structure of a moving body is newly designed or improved, a structure that is a candidate for the new design or improvement is incorporated into the moving body, and the corrosive environment of the structure is measured. Structure so that the output of the corrosion sensor at this time or the value calculated from this output (output value such as current density or converted value such as time integral of current) is within a predetermined range that can be regarded as no problem in rust prevention. By designing or improving the above, it is possible to design an appropriate rust prevention structure.

  Next, the corrosion test method for the mobile material of the present invention will be described. Here, the corrosion test of moving body materials is a corrosion test that evaluates the corrosion resistance of the moving body itself or a test piece attached to the moving body by actually using the moving body in a predetermined corrosion-promoting environment. In addition, it is required to efficiently develop corrosion in an actual use environment of the mobile body in a short period of time.

  In order to determine the corrosion-promoting environment, first, the corrosive environment of the moving object is measured in the actual use environment. Among the measurement results, the output of the corrosion sensor or the external environment where the numerical value calculated from the output falls within a certain range (for example, running on rainy weather, snowmelt salt spreading roads) and the corrosion environment factors that govern the corrosion (for example, rainfall) And wetting due to water splashing, snowmelt salt adhesion, relative humidity, etc.). There may be a plurality of such external environment or corrosion environment factors. Next, the moving environment of the moving body is artificially set so that the corrosion is accelerated by an external environment or a corrosive environment factor that controls the assumed corrosion. For example, it is possible to set a snow melting salt spraying road that simulates the melting of snow melting salt in winter, and a road that sprays showers and warm water that simulates raining. If there are a plurality of external environments or corrosive environmental factors that control corrosion, different mobile environments may be set in combination. By using the moving body in the corrosion promotion environment set as described above, the corrosion resistance of the moving body can be efficiently evaluated. Once the mobile environment has been set, measure the corrosive environment and readjust the mobile environment so that the output from the corrosion sensor installed at the reference site where the mobile object is located or the value calculated from the output is within a certain range. May be.

  Next, a method for selecting an optimum metal material by measuring the corrosive environment of the moving body of the present invention will be described. There are two types of metal electrodes having different components and / or compositions at the same measurement site, one of which is a metal material to be selected as a component of the mobile material, and the other one is different from this. Install one or more corrosion sensors of the same metal. The output of the installed corrosion sensor or a numerical value calculated from this output is compared, and a metal material of an electrode that gives a smaller output or a metal material having a similar component and / or composition is applied as a constituent material of the moving body. This is because a metal electrode having a smaller output of the corrosion sensor is considered to have higher rust prevention performance in that environment. A material having the most excellent corrosion resistance can be selected from materials satisfying conditions other than corrosion resistance, for example, conditions such as cost.

  A method for selecting an appropriate material for the moving body with higher accuracy will be described below. Corrosion environment measurement is performed for several parts of a moving body in a certain area (corrosion environment measurement process), and the corrosion amount of each part where the above environmental measurement is performed for a moving body whose use period is known in the same area is quantified. (Step of measuring the corrosion amount), and the correlation between the measurement output and the corrosion amount is obtained from this (step of creating a correlation diagram between the corrosion sensor output and the corrosion amount). A database that collects these correlations is constructed. Here, the moving body for measuring the corrosive environment and the moving body for quantifying the amount of corrosion do not have to be the same, but it is desirable that they have a similar structure. Examples of the corrosion amount of the moving body include corrosion reduction of metal materials, corrosion hole depth, coating film swelling width, and rust generation area. It is desirable that the correlation between the measurement output and the amount of corrosion be organized for each type of material, and that the accuracy should be increased by increasing the number of corrosion sensor survey areas and the number of mobile units surveyed.

  Then, the corrosive environment measurement is performed in a new environment and / or a new area where the mobile body is expected to be used. The measurement result is compared with the correlation between the measurement output for each material of the movable body obtained in advance and the amount of corrosion or a database, and a material satisfying the corrosion resistance for the output can be selected accurately and appropriately. In this method, not only the type of steel plate and plating, but also the chemical conversion treatment, the type of coating, and the thickness can be selected appropriately.

  Next, a method for adding value and improving the reliability of the mobile body and the mobile body constituent material of the present invention will be described. Estimated from the corrosive environment measurement results for the surface-treated steel plates and corrosion-resistant steel materials that are the constituent metal materials of the moving body selected based on this corrosive environment measurement method, the correlation between the corrosion sensor output used for selection and the corrosion amount, or its database Attach quantitative corrosion data. In addition, the corrosion resistance evaluation result by the moving body corrosion test set based on this corrosion environment measurement method is attached to the moving body or moving body parts. These attached data may be sent by electronic information, or materials, parts, moving bodies, and structures that can be regarded as the same may be presented as representatives in the form of catalogs or specifications. The attached or presented information can provide a metal material with added value and reliability with respect to the antirust quality.

  FIG. 1 shows an example of the configuration of a corrosive environment measurement system in an automobile. In this example, 1. Fender, 2. Inside the door, 3. Floor bottom, 4. Vehicle interior, 5. Wheel arch are shown. In addition, measurement using a temperature and relative humidity sensor, which is an environmental sensor, is also performed in the vicinity of the corrosion sensor.

  FIG. 2 shows an example of the configuration of the corrosion sensor used in the present invention. The corrosion sensor shown in 1 and 2 of FIG. 2 is a two-electrode type corrosion sensor using two kinds of metals. The corrosion sensors shown in 3 and 4 of Fig. 2 are 4-electrode type corrosion sensors using three kinds of metals. In 3 and 4, the outputs between metal A and metal B, between metal B and metal C, and between metal C and metal B are measured. The output result varies depending on the surrounding environment, the wet state of the sensor, and the type of electrode metal. When using a surface-treated steel sheet in step 4, cover the end face and non-plated surface with tar resin or the like.

Table 1 is a table for determining whether or not an effective output can be obtained in the measurement for the corrosion sensor shown in FIG. Table 1 shows the number of the corrosion sensor shown in FIG. 2, the measurement method, the number of electrodes, the components of electrodes A, B, and C, and the determination of whether or not measurement is possible. Whether the measurement is possible or not is judged as ○ when the output of 0.01 μA or more is obtained with the relative humidity of 90% or more in the present inventions 1 to 9 and 11 when the attached salt amount to the sensor is 100 mg / m ² . The case where an output of 0.01 μA or more was obtained at a relative humidity of 80% or more was marked with “◎”.

  Fe was carbon steel, Zn was 97% pure, Al, Mg, and Ni were 99% pure, and Pt, Au, and Ag were 99.9% pure.

  According to the present invention and Comparative Example 3, the corrosion sensor requires two or more metal electrodes. According to the present invention and Comparative Examples 1 and 4, the corrosion sensor needs to be composed of two or more kinds of metal electrodes having different components and / or compositions. From the present invention and Comparative Example 2, the detection method of the corrosion sensor is superior to the galvanic type in which no external signal is input to the sensor.

  FIG. 5 shows a result of the corrosion environment measurement for the parts 1 and 2 of the moving body using a plurality of corrosion sensors having pairs of different metal electrodes. In the moving body part 1, the output of the corrosion sensor using each metal electrode is Zn> Fe >> Al> Cr, and it is desirable in terms of rust prevention to apply Al or Cr having a small output as the moving body constituting material. It can be judged. On the other hand, if the output of a sensor using any metal electrode as in the part 2 is sufficiently small, it is determined that any material has sufficient corrosion resistance, and the material is selected according to conditions other than the corrosion resistance.

  FIG. 6 is an example in which a correlation diagram between the corrosion sensor output and the corrosion amount is created from the measurement of the corrosion environment of the automobile and the actual corrosion survey of the automobile in 10 years of use in each of the areas a to c.

  FIG. 7 is a diagram summarizing the correlation between the corrosion sensor output and the corrosion amount of automobiles for 10 years in use for each material, together with the data of the respective areas a to c shown in FIG.

  FIG. 8 is a diagram showing the corrosion sensor output (dotted line in the figure) of each part of the vehicle obtained from the corrosion environment measurement in the area d in the correlation diagram created in FIG. From this figure, for example, in the region d, when the material A is applied to the inside of the door, it is predicted that corrosion will be perforated after 10 years of use. On the other hand, when the material B is applied, it is predicted that the depth of the corrosion hole is sufficiently small with respect to the plate thickness. Therefore, in the material B, the corrosion inside the door is slightly red rust, and can be applied if the usage period is 10 years. Moreover, since the corrosion hole depth is small on both the materials A and B on the back side of the hood, both materials A and B can be applied if the usage period is 10 years. In this example, the applicability of the material is determined only from the viewpoint of corrosion, and other conditions such as cost are not considered.

Explanatory drawing showing an example of the configuration of a corrosive environment measurement system in an automobile Explanatory drawing which shows an example of a structure of the various corrosion sensors used for this invention The graph which shows an example of the relationship between the gap | interval between the electrodes of the corrosion sensor used for this invention, and the corrosion sensor output in relative humidity 100% Comparison of corrosion sensor output on the exterior of the automobile body, inside the door, and under the floor The graph which shows the result of having carried out the corrosion environment measurement about the site | part 1 and 2 of a moving body using the corrosion sensor which has a different metal electrode Example of correlation diagram between corrosion sensor output and corrosion amount from the results of automobile corrosion environment measurement and corrosion actual condition survey in each area ac An example of a correlation diagram between the corrosion sensor output and the amount of corrosion for each material in an automobile with a certain service life, together with the data of each area a to c shown in FIG. In the correlation diagram shown in FIG. 7, an explanatory diagram showing the corrosion sensor output (dotted line in the figure) of each part of the automobile obtained from the corrosion environment measurement in the region d

Claims (7)

  At least one part of a moving body, at least part of which is made of a metal material, has two or more kinds of metal electrodes having different components and / or compositions, and a component of the moving body material to be measured is measured on either of them. Install one or more corrosion sensors that contain one or more types and have at least one pair of electrodes spaced 0.1 to 5 mm apart from the insulator, and the electrodes are electrically short-circuited in a corrosive environment. A method for measuring a corrosive environment of a moving body, wherein the current or potential difference between the electrodes due to is measured continuously or intermittently, including when moving.   2. The method for measuring a corrosive environment of a moving body according to claim 1, wherein the installation position of the corrosion sensor is set to the inside isolated from the outside of the moving body or the inside of a constituent part of the moving body.   At least one part of a moving body, at least part of which is made of a metal material, has two or more kinds of metal electrodes having different components and / or compositions, and a component of the moving body material to be measured is measured on either of them. Install one or more corrosion sensors that contain one or more types and have at least one pair of electrodes spaced 0.1 to 5 mm apart from the insulator, and the electrodes are electrically short-circuited in a corrosive environment. The structure of the moving body is designed so that the corrosion sensor output consisting of the current or potential difference between the electrodes due to or the numerical value calculated from the output falls within a predetermined range.   At least one part of a moving body, at least part of which is made of a metal material, has two or more kinds of metal electrodes having different components and / or compositions, and a component of the moving body material to be measured is measured on either of them. Install one or more corrosion sensors that contain one or more types and have at least one pair of electrodes spaced 0.1 to 5 mm apart from the insulator, and the electrodes are electrically short-circuited in a corrosive environment. Corrosion resistance of the test piece material attached to the moving body or the moving body by setting the moving environment so that the corrosion sensor output consisting of the current or potential difference between the electrodes due to or the numerical value calculated from the output is within a predetermined range A corrosion test method for a mobile material characterized by performing a corrosion test for evaluating   There are two kinds of metal electrodes having different components and / or compositions at any part of the moving body, at least a part of which is made of a metal material, and one of them is a target for selecting a constituent of the moving body material. One type or two or more types of corrosion sensors made of a metal material, the other one being made of the same metal different from this, and arranged such that the gap between the electrodes is 0.1 to 5 mm across the insulator And selecting a metal material at the corresponding part of the moving body by comparing the output of the corrosion sensor or the numerical value calculated from the output.   At least one part of a moving body, at least part of which is made of a metal material, has two or more kinds of metal electrodes having different components and / or compositions, and a component of the moving body material to be measured is measured on either of them. Install one or more corrosion sensors that contain one or more types and have at least one pair of electrodes spaced 0.1 to 5 mm apart from the insulator, and the electrodes are electrically short-circuited in a corrosive environment. A method for selecting a mobile material based on the measurement results of a corrosive environment by a corrosion sensor, which continuously or intermittently measures the current or potential difference between electrodes including the time of movement. Corrosion environment measurement process that measures the corrosive environment at multiple parts of the site with a corrosion sensor, and the amount of corrosion at the same multiple parts for a moving body that has been used for a certain number of years in multiple measured areas Each of the mobile objects in a new environment and / or a new area where the mobile object is used. A method for selecting a mobile body material comprising a step of comparing a result of measuring a corrosive environment of a site with the correlation diagram and selecting a metal material at a plurality of sites of the mobile body.   A surface-treated steel plate and a corrosion-resistant steel material, which are metal materials constituting the moving body selected by the method for selecting a mobile material according to claim 5 or 6, wherein the surface-treated steel plate and the corrosion-resistant steel material include corrosion environment measurement data. A surface-treated steel sheet and a corrosion-resistant steel material, characterized in that

Images