JP6630044B2 - Degradation diagnosis method for resin piping system - Google Patents

Description

  The present invention relates to a method for diagnosing deterioration of a resin piping system. More specifically, the present invention relates to a non-destructive deterioration diagnosis method for an existing outdoor piping system.

  Various methods are known for diagnosing the deterioration state of piping.

  Japanese Patent Application Laid-Open No. 2007-108014 (Patent Literature 1) does not show a case of a resin pipe, but a measuring apparatus having an ultrasonic sensor mounted on a self-propelled bogie while adsorbing on the inner surface of the penstock is inserted into the penstock. A technique is described in which the thickness of a penstock is measured by inserting the penstock and the decrease in thickness caused by aging is confirmed from the outside.

  Japanese Patent Application Laid-Open No. 2014-62876 (Patent Literature 2) discloses measuring the outer surface hardness, the outer surface temperature, and the inner pressure of a hose to which an internal pressure acts, and calculating the estimated use time of the hose using the measured values. A technique for diagnosing deterioration of a resin hose during operation in which an internal pressure is applied in an ambient environment is described.

  On the other hand, Japanese Patent Application Laid-Open No. 2002-257819 (Patent Document 3) describes a technique for evaluating the remaining life by measuring the oxidation induction time of a resin tube.

JP 2007-108014 A JP 2014-62876 A JP-A-2002-257819

  The techniques described in JP-A-2007-108014 (Patent Document 1) and JP-A-2014-62876 (Patent Document 2) are non-destructive inspection methods. Deterioration status can be grasped. However, due to the necessity to maintain the existing piping configuration, the information available to judge the deterioration status is limited to structural features (physical quantities measurable on site), but reference to correlation data with physical property values The physical properties are estimated by

  On the other hand, sampling is required to determine the state of deterioration from a material viewpoint. Sampling of the pipe is performed by removing the pipe, that is, by removing a part of the pipe. However, since the use of the pipe must be stopped when the pipe is removed, there is a problem that the burden on the operation of the pipe system is large. In addition, as a result of the diagnosis, even if the remaining pipe has a sufficient remaining life, the removed pipe has to be discarded, so that there is a problem of waste disposal and a problem of renewal cost.

  The technique described in Japanese Patent Application Laid-Open No. 2002-257819 (Patent Document 3) measures the state of deterioration by measuring the oxidation induction time at a plurality of locations in the thickness direction of the resin tube, and is used for sampling. The piping itself must be removed. Although it has been proposed to provide a special structure for the piping system to make it easy to remove or to allow removal by uninterrupted water, it is impossible to omit the work of removing the piping. Further, since the ordinary piping system is not provided with such a special structure, the above-described problem due to the removal of the piping is practically inevitable.

  Therefore, an object of the present invention is to provide a method for judging a deterioration state of a resin pipe from a material viewpoint without removing the pipe.

  In the case of resin piping, deterioration due to external environmental factors affects the reduction in impact strength, but does not affect the reduction in tensile strength. In addition, deterioration of the pipe due to external environmental factors tends to occur in a very shallow portion near the pipe surface. Therefore, the object of the present invention is achieved by using, as a sample for diagnosing deterioration of the pipe, a sample obtained by extracting a part of the constituent resin in a very shallow portion from the pipe surface. The present inventors have completed the present invention as a result of these earnest examinations.

(1)
The method for diagnosing deterioration of a resin piping system of the present invention includes an analysis step and a diagnosis step. In the analysis step, the resin section sample is subjected to analysis to obtain analysis information. The resin section sample was obtained by cutting a part of the surface of the resin piping system while maintaining the existing configuration of the resin piping system. In the diagnosis step, the deterioration state of the resin piping system is diagnosed from the analysis information.

A resin piping system is intended to include both a resin piping and a resin joint. Therefore, the resin section sample may be collected from any of the pipe and the joint.
The resin section sample is a thin section obtained by an operation of cutting along the surface of the pipe.
The state in which the existing structure of the resin piping system is maintained means that, in the resin piping system structure installed and used in a state where a predetermined communication mode is formed by connecting pipes and joints, the communication state is changed or divided. And a state in which neither the pipe nor the joint is removed. Preferably, it refers to a state in which the internal fluid is flowing.

  With this configuration, the deterioration state of the resin pipe can be determined from a material viewpoint without removing the pipe. For this reason, deterioration diagnosis can be performed without destroying the resin piping system structure, so that when it is determined that the remaining life of the resin piping system is sufficient, it can be used continuously. Therefore, there is no needless waste treatment problem and no useless update cost problem. In the case of continued use, it is not necessary to repair the cut surface.

  Further, deterioration of the piping due to external environmental factors that expose the surface of the resin piping system does not adversely affect the tensile strength, and thus does not pose a problem with respect to the internal pressure of the piping. Therefore, there is no need to stop the flow of the internal fluid. Therefore, the diagnosis can be performed without imposing a burden on the operation of the piping system.

  Then, since the sampling of the resin section sample is performed while maintaining the existing structure of the resin piping system, the space arrangement may cause a location particularly exposed to external environmental factors that may cause deterioration (for example, in a ground environment, It is easy to judge a place where light, heat, etc. are hit particularly frequently), and a part suitable for deterioration diagnosis is efficiently collected.

  Furthermore, since the resin section sample is obtained by cutting the pipe, it can be handled while maintaining the fine structure of the resin composition in the pipe and the fine structure of the surface. Therefore, even if the user is not at the site where the resin piping system is installed, auxiliary information for deterioration diagnosis can be obtained by observing the surface of the section.

(2)
The resin section sample is preferably taken within a depth range of 200 μm or less from the surface of the resin piping system.

  As described above, since a very shallow portion of the resin structure is collected from the surface of the resin piping system, the piping is not damaged. In addition, since the depth range in which deterioration due to the external environment particularly occurs is often from the surface to several hundred μm, a portion suitable for deterioration diagnosis is efficiently collected.

(3)
The thickness of the resin section sample may be 10 μm or more and 200 μm or less.
By analyzing using a sample having such a thickness, deterioration information in the depth direction can be obtained.

(4)
The resin piping system is preferably made of a thermoplastic resin.
(5)
The thermoplastic resin may be selected from the group consisting of a polyvinyl chloride resin, a polyolefin resin, an acrylic resin, and a styrene copolymer resin.

  This is useful in terms of versatility. Furthermore, in the case where the constituent resin tends to change its color due to external environmental factors, it is easy to visually determine where the resin is particularly exposed to external environmental factors that may cause deterioration. Collected efficiently.

The resin piping system may be installed in either an outdoor or indoor environment.
In this case, it is possible to diagnose deterioration caused by outdoor environmental factors.

It is a typical explanatory view about a deterioration diagnosis object and sampling in one embodiment of the present invention. It is a typical sectional view about a degradation diagnosis object and sampling in one embodiment of the present invention. FIG. 3 is a schematic explanatory diagram of a deterioration diagnosis according to an embodiment of the present invention. It is an analysis result of the deterioration index obtained in the example.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. In the following description, the same elements are denoted by the same reference characters, and have the same names and functions. Therefore, detailed description thereof will not be repeated.

[Degradation diagnosis target]
FIG. 1 is a schematic explanatory view of a resin piping system to be subjected to deterioration diagnosis and sampling. FIG. 2 is a schematic cross-sectional view cut along a plane including the line XX in FIG. In the resin piping system 100, the piping 110 is connected by a joint 120, and is disposed outdoors. The piping system 100 includes a part A that is particularly exposed to external environmental factors (the external environmental factors are not limited, but in the case of the present embodiment, ultraviolet rays) and a part B other than those (indicated by hatching). There is.

  In the present embodiment, the pipe 110 and the joint 120 are commercially available and used. The constituent resin of the pipe 110 and the joint 120 is a thermoplastic resin, and examples thereof include a polyvinyl chloride resin, a polyolefin resin, an acrylic resin, and a styrene copolymer resin. Therefore, it is excellent in versatility.

  The constituent resin may be one that has been subjected to a deterioration resistance treatment (for example, a treatment for mixing an additive for deterioration resistance into a resin composition, a chemical reaction treatment for producing a structure having deterioration resistance), or such a treatment. May not be processed. If the constituent resin has not been subjected to the deterioration resistance treatment, the portion A may be discolored due to external environmental factors. Due to such discoloration, it is possible to easily visually determine a site where a sample suitable for deterioration diagnosis should be collected.

[Sampling of deterioration diagnosis sample]
The collection of the deterioration diagnosis sample is performed by cutting the surface of the pipe 110 and / or the portion A of the joint 120. The collection of the deterioration diagnosis sample may be performed by a user of the resin piping system 100, a contractor, an inspector, an analyst, or the like. At this time, none of the piping 110 and / or the joint 120 is removed, and the resin piping system 100 is in use and in use.

  The means for collecting the deterioration diagnosis sample is not particularly limited as long as it is a jig which can cut a thin piece by sliding a blade along the surface of the pipe 110 and / or the joint 120, and a canner or the like can be used. Thereby, the resin section sample 150 is obtained from the pipe 110 and / or the joint 120 as a deterioration diagnosis sample.

  The resin section sample 150 may be a resin structure including the outermost surface of the pipe 110 and / or the joint 120, or may be a resin structure not including the outermost surface. Here, the outermost surface refers to a surface directly exposed to the external environment.

  When the resin section sample 150 has a resin structure including the outermost surface, the deterioration state can be grasped morphologically by observing the morphology of the outermost surface (described later). Therefore, auxiliary information for deterioration diagnosis can be obtained.

  In order to collect the resin section sample 150 as a resin structure not including the outermost surface, for example, the exposed surface is removed by removing the outermost surface of the joint 110 and / or the joint 120 in advance. The removal of the outermost surface may be performed by cutting using a jig such as a canner, or may be performed by cutting using a file.

  The resin section sample 150 can be cut out within a depth D (average value) within 200 μm, 100 μm, or 50 μm from the surface where deterioration due to external environmental factors is likely to occur. Therefore, the thickness t of the resin section sample 150 is, for example, 10 μm or more and 200 μm or less, 10 μm or more and 100 μm or less, or 10 μm or more and 50 μm or less. By sampling at such a thickness, the section shape of the resin section sample 150 can be stably maintained during transportation or the like, and deterioration information in the depth direction of the pipe 110 and / or the joint 120 can be obtained at the time of analysis. . In addition, when the resin section sample 150 is 50 μm or less in thickness, even if the resin section sample 150 is used for measurement without crushing the section, it is easy to obtain deterioration information inside the resin section sample 150. Is preferred in that there are cases where

The surface of the resin section sample 150 preferably has an area of, for example, 20 mm ² or more, preferably 50 mm ² or more. Ensuring a predetermined area in this manner is preferable in terms of facilitating surface observation and the like, and being able to select and measure a plurality of locations on the surface. That is, by securing a predetermined area in this way, the ease of deterioration determination and, consequently, the accuracy and the like become remarkable.

  Alternatively, assuring the predetermined area in this manner means that the analyst can observe the entire surface based on expert knowledge and / or the use of specialized equipment by examining the resin section sample 150 that has been visually determined by the extractor. By performing the above, a point suitable for analysis can be narrowed down from the entire resin section sample 150, or by measuring a plurality of points of the resin section sample 150, the fine structure of the resin composition in the piping or the fineness of the surface can be reduced. This is also preferable in that detailed information reflecting the structure can be obtained.

Therefore, assuring that the surface of the resin section sample 150 has a predetermined area, as a result, highly accurate analysis is possible. The upper limit of the surface area to be ensured by the resin section sample 150 is not particularly limited, but may be, for example, about 500 mm ² from the viewpoint of minimizing unnecessary portions during analysis.

  As described above, the resin section sample 150 can be easily collected by a method in which a blade is slid along a surface of the pipe 110 and / or the joint 120 to cut out a thin section. It is preferably an elongated shape.

  In this case, the width (average value) in the short direction is, for example, 2 mm or more, preferably 5 mm or more. In this case, as described above, highly accurate analysis can be performed, for example, in that the surface observation becomes easier.

  Further, the width (average value) in the longitudinal direction is, for example, 10 mm or more, preferably 30 mm or more. In this case, as described above, a highly accurate analysis is possible in that the surface observation becomes easier and the number of measurement points is easily secured.

  The resin section sample 150 may be cut along the axial direction of the pipe 100 and / or the joint 120 (that is, the axial direction corresponds to the longitudinal direction). In this case, since the shape of the resin section sample 150 is flat, it is easy to handle and can be applied to various measurement methods. Furthermore, it is also preferable from the viewpoint of easy sample recovery from the installation site of the pipe 100 and / or the joint 120.

  The present invention does not exclude sampling of the resin section sample 150 by cutting along the circumferential direction of the surface of the pipe 110 and / or the joint 120 (that is, the circumferential direction corresponds to the longitudinal direction). In this case, the difference in the degree of deterioration in the circumferential direction can be inspected. More specifically, it is possible to inspect which part in the circumferential direction is particularly deteriorated.

[Analysis process]
The cut resin section sample 150 is used for analysis. Analysis includes both measurement and observation. In this case, the resin section sample 150 is prepared as it is or as a sample for analysis by performing a pretreatment process (for example, pulverization, stretching, dissolution, etc.) according to the analysis method. Therefore, the sample for analysis may be in a powder form or a flake form. Preparation of the measurement sample is performed by an analyst.
In the following, even if not particularly described, the sample was similarly collected from a place different from the place where the resin section sample 150 was collected (particularly, a place where exposure to ultraviolet rays and other elements that deteriorate the resin is as small as possible). A resin section sample may be subjected to analysis as a control sample.

  When the resin section sample 150 is pre-processed at the time of preparing the analysis sample, a process of removing a part of the resin section sample 150 may be performed. In this case, it is possible to select a portion that is more suitable for the deterioration diagnosis in consideration of the accuracy of the deterioration diagnosis.

  For example, as a result of observation of the surface morphology, when the outermost surface is partially missing, if the difference between the part where the deep part is exposed due to the chipping and the other part that escaped the chipping is severe, the deterioration is as small as possible. By selecting a part having a small difference, a part suitable for deterioration diagnosis can be selected. Specifically, the resin section sample 150 can be cut to separate a portion having a small difference in the degree of deterioration from another portion.

  Further, the outermost surface and / or the opposite surface may be removed. The removal of the outermost surface is useful when the degree of deterioration greatly varies depending on the location, or when a transfer product of an oxide film adhered to a mold during manufacturing remains. Removal of the opposite surface is useful when the progress of deterioration is small. This makes it possible to select a portion that is more suitable for the deterioration diagnosis. Specifically, the outermost surface of the resin section sample 150 and / or the surface on the opposite side can be removed with a file or the like.

  Further, the measurement can be performed on both the resin structure on the outermost surface side of the resin section sample 150 and the resin structure on the opposite surface side. In this case, the degradation information in the depth direction can be obtained more accurately. For example, if no significant deterioration is detected only in the resin structure on the opposite side, it can be diagnosed that the deterioration of the pipe 110 and / or the joint 120 has not progressed to the depth of the opposite side. Further, when significant deterioration is detected on both the outermost surface side and the opposite surface side, the difference between the degree of deterioration on the opposite surface side with respect to the uppermost surface side deterioration degree and the thickness of the resin section sample 150 indicate the piping 110 and the In some cases, an auxiliary determination may be made as to how deep the joint 120 has degraded.

  The measurement includes detecting characteristics of polymer molecules, characteristics of additives, and characteristics of discoloration of the resin structure, which change with the deterioration of the resin. Characteristics of the polymer molecules to be detected include molecular structures (eg, carbonyl group, carboxyl group, alkenylene group, polyene structure, methyl group, etc.) generated by oxidation, decomposition, and denaturation, decrease in molecular weight, and deterioration of thermophysical properties. No. Thereby, deterioration (for example, decomposition, desorption, oxidation, etc.) of the polymer molecule itself can be determined. The same thing can be mentioned as a feature of the additive. Other characteristics of the additive include the content and the functional amount of the additive. This makes it possible to determine the degree of loss of the function provided by the additive (for example, due to elution, decomposition, and the like).

X-ray photoelectron spectroscopy, visible ultraviolet absorption spectroscopy, infrared absorption spectroscopy (eg, Fourier transform infrared spectroscopy, dispersive infrared spectroscopy), and Raman spectroscopy include detection of features related to molecular structure. Nuclear magnetic resonance spectroscopy (for example, ¹ H-NMR, ¹³ C-NMR) and the like are used. Detection of characteristics related to molecular weight uses size exclusion chromatography (eg, gel permeation chromatography), mass spectrometry, and the like. Thermal analysis methods (for example, differential thermal analysis, differential scanning calorimetry, thermogravimetry, thermomechanical analysis, dynamic viscoelasticity measurement) and the like are used to detect characteristics related to thermophysical properties. In order to detect the characteristics of additives, X-ray fluorescence analysis, gas chromatography, pyrolysis gas chromatography, liquid chromatography, infrared absorption spectroscopy, Raman spectroscopy, thermal analysis, oxidation induction time measurement, etc. Used. In order to detect the characteristics of discoloration, color difference measurement or the like is used.
Note that the above-described binding measurement system is appropriately used depending on the target to be detected.

  When X-ray photoelectron spectroscopy is used, for example, the state of deterioration of polymer molecules due to oxidation can be measured. When the polymer molecule is polyvinyl chloride, deterioration of polyvinyl chloride due to dehydrochlorination can be measured. Specifically, the degradation state can be detected by detecting a decrease in the peak intensity of the methylene monochloride group based on the peak intensity of the methylene group. Further, oxidation can be detected by detecting a functional group represented by -CO-, -C = O, -COO-, or the like. Then, from the peak intensities including chlorine, carbon, and oxygen, quantitative analysis of the amount of hydrochloric acid and the amount of oxidation based on the amount of carbon can be performed. X-ray electron spectroscopy is very preferable in that surface degradation is quantitatively captured.

  When the infrared absorption spectrum method is used, the deterioration state of the polymer molecule due to oxidation can be measured. In this case, a peak indicating the absorption of the carbonyl group based on the peak indicating the absorption of the polymer molecule can be detected as an index of deterioration. Regarding the infrared absorption spectrum method, any of a reflection method and a transmission method may be used. Further, the respective advantages can be utilized by combining the reflection method and the transmission method.

  In the reflection method, information up to a depth of several μm near the surface of the sample can be obtained. Since the resin section sample 150 can be actually collected in various thicknesses, the resin section sample 150 can be applied to any thickness of the resin section sample 150 and preparation of a sample for analysis (for example, thinning or grinding). Since it is not necessary to perform the above, it is preferable in that the analysis efficiency is good. Further, since the deterioration information on the front side and the deterioration information on the back side of the resin section sample 150 can be separately obtained, the deterioration information in the depth direction can be more accurately determined. Further, in the reflection method, when the deterioration is progressing, the degree of the deterioration tends to be easily discriminated, so that the advanced deterioration can be more accurately determined.

  In the transmission method, not only deterioration information near the surface of the sample but also deterioration information over the entire thickness of the sample is obtained. For this reason, for example, even if the resin structure with a lower degree of deterioration is exposed at the surface portion due to the progress of deterioration and the resin structure with a smaller degree of deterioration is exposed in the deep portion, the effect (that is, the rate of progress of the deterioration) is reduced. (The effect of measuring the resin structure in a low-deteriorated state). Therefore, deterioration diagnosis can be stably performed for both a sample having a small degree of deterioration and a sample having a large degree of deterioration (that is, a sample having been deteriorated to such a degree that the surface is lost).

Furthermore, in the case of using the transmission method, a method for directly measuring (for example, a thin film method) can be used as long as the sample for measurement is 50 μm or less, preferably 10 μm or less in the form of a slice.
In addition, a tableting method, a plate method, or the like can be used for a measurement sample in a powder form obtained by pulverizing the resin section sample 150. Considering the possibility of obtaining the resin section sample 150 with various thicknesses, it is preferable to use these methods from the viewpoint of versatility.

  When the Raman spectrum is used, it is possible to measure, for example, the state of deterioration due to the formation of a polyene structure (conjugated double bond) accompanying the dehydrochlorination of polyvinyl chloride. Specifically, the polysalt structure can be detected by detecting peaks belonging to -C = C-stretching vibration and = CC = stretching vibration. In addition, dehydrochlorination can be detected by a decrease in the peak intensity of the C-Cl stretching vibration based on the peak intensity of the CH stretching vibration.

  When detecting features related to molecular weight, such as size exclusion chromatography and mass spectrometry, it is possible to measure, for example, the state of degradation of polymer molecules due to decomposition. Specifically, the state of deterioration can be measured from the molecular weight and / or amount of the fragments generated by the decomposition of the polymer molecules.

  When the oxidation induction measurement method is used, for example, the function of an antioxidant as an additive can be evaluated. Specifically, it can be based on the fact that the shorter the oxidation induction time, the lower the antioxidant power and the deterioration of the resin. In this case, as a control sample, a resin section sample similarly collected from a place different from the place where the resin section sample 150 was collected (particularly, a place where exposure to ultraviolet rays and other elements that deteriorate the resin is as small as possible) is performed. The degree of deterioration may be determined by comparing with the oxidation induction time. Furthermore, in some cases, a specific degree of deterioration can be determined to some extent based on the relationship between the oxidation induction time and the degree of deterioration obtained empirically.

  When color difference measurement is used, the degree of deterioration of the resin structure can be measured by the relative amount of the color difference index. Specifically, the degree of change can be determined based on the degree of change (ΔE) of the color difference index increases as the deterioration proceeds. For example, the occurrence of surface roughness causes whitening due to irregular reflection of light due to fine irregularities, and the generation of polyene causes blackening due to the formation of chromophores. In this case, as a control sample, a resin section sample similarly collected from a place different from the place where the resin section sample 150 was collected (particularly, a place where exposure to ultraviolet rays and other elements that deteriorate the resin is as small as possible) is performed. The degree of deterioration may be determined by comparing with the color difference index. Furthermore, in some cases, a specific degree of deterioration can be determined to some extent based on the relationship between the color difference index and the degree of deterioration acquired empirically.

  When observing the morphology of the surface of the resin section sample 150, the morphology to be observed includes surface roughness (for example, microvoids). Such surface roughness is caused by removal of additives, exposure of the interior due to falling off of surface portions, exposure of primary particles of the resin, decomposition of the resin, and the like.

  As a means for observing the morphology of the surface of the resin section sample 150, a means capable of magnifying observation, such as an optical microscope or an electron microscope, can be used. Examples of an electron microscope that enables morphological observation at a higher magnification include a transmission electron microscope (TEM) and a scanning electron microscope (SEM).

[Diagnosis process]
The analysis information obtained in the analysis step is used for diagnosing the state of deterioration.
For example, in the diagnosis of the deterioration state, the physical properties of the pipe 110 and / or the joint 120 can be estimated by determining the degree of deterioration. Based on the estimated physical properties, the necessity of updating, the necessity of re-diagnosis, and the recommended update time can be determined for the pipe 110 and / or the joint 120. Specifically, (i) no update is required, (ii) no update is required, but re-diagnosis is recommended before the specified period elapses, (iii) update is recommended before the specified period elapses, (iv) early update is required Either of them can be presented as a diagnostic result.

  The degree of deterioration is determined using the results of detecting characteristics of polymer molecules, characteristics of additives, and characteristics of discoloration of the resin structure (hereinafter referred to as deterioration characteristics) that change with the deterioration. For example, it is preferable that a relative value of the detection intensity indicating such a deterioration characteristic is used as an index (hereinafter, referred to as a deterioration index), and the deterioration index is configured to have a positive correlation with the degree of progress of deterioration. . In this case, it can be determined that the higher the deterioration index is, the more the deterioration is advanced.

  The degradation index is, specifically, the intensity of a signal derived from a polymer molecule or an additive that is not affected by degradation, or the detection intensity that indicates the above-mentioned degradation characteristics with respect to the detection intensity derived from a polymer molecule or an additive of a control sample. May be constituted by the relative value of Further, the deterioration index is preferably a composite index based on a plurality of analysis methods for the degree of deterioration from the viewpoint of reliability. For example, the relative values of the detection intensities indicating the deterioration characteristics obtained by at least two of a plurality of analysis methods can be combined with each other to derive one deterioration index.

  If a calibration curve indicating the correlation between the deterioration index and the physical properties is created, the deterioration diagnosis can be easily performed based on the calibration curve. FIG. 3 shows an example of the calibration curve. In FIG. 3, the abscissa indicates the deterioration index (the case of a new product is assumed to be 0), and the ordinate indicates the strength retention as an example of physical properties (the case of a new product, ie, the strength retention indicating initial performance is assumed to be 100). Is shown. As the strength, tensile strength (i), impact strength (ii), and flat strength (iii) are shown. As shown in the figure, even if the surface of the pipe 110 and / or the joint 120 becomes hard and brittle due to the progress of deterioration, in the short term, the tensile strength (i) does not show a significant decrease, but rather tends to increase. is there. Therefore, there is basically no problem from the viewpoint of the internal pressure strength. On the other hand, those which become problematic as the deterioration proceeds are the impact strength (ii) and the flat strength (iii). Therefore, due to the progress of deterioration on the surface, resistance to deformation and impact from the outside is reduced, and the risk of destruction due to sudden impact or stress from the outside is increased.

According to the calibration curve of FIG. 3, for example, when the deterioration index is derived as 6, it can be estimated that the retention rate of the impact strength is reduced to be less than 40% of that of a new article. Further, when it is determined that the intensity is less than 40%, which is not suitable for use, it is possible to present to the user a diagnosis result that there is a concern that the intensity is remarkably reduced or that it is necessary to update the intensity early.
Further, for example, when the deterioration index is derived as 0.06, it can be estimated that the retention rate of the impact strength is maintained at more than 80% of that of a new article. Furthermore, if it is determined that the intensity exceeds 80%, the intensity is suitable for use for the time being, it is possible to present to the user a diagnosis result indicating that no remarkable decrease in intensity is estimated or no update is necessary.
Further, when the holding ratio of the impact strength is 40% or more and 80% or less, it is possible to present to the user a diagnosis result that a remarkable decrease in strength is estimated or that a retest is required before a predetermined period elapses. .

  The above-described three-level evaluation is an example, and the threshold value of the holding ratio of the impact strength and the number of evaluation stages, which are the respective evaluation criteria, can be set as appropriate.

  Hereinafter, the present invention will be described in more detail by way of examples, but the present invention is not limited to these examples.

[Example 1]
A new hard polyvinyl chloride resin pipe ("Eslon VP pipe" manufactured by Sekisui Chemical Co., Ltd., diameter 50A) was prepared. Ultraviolet light was applied to the outer peripheral surface of the new product. Irradiation with ultraviolet rays was performed under accelerated weathering test conditions using Metal Weather ^(R) (manufactured by Daipla Wintes Co., Ltd.).
During the ultraviolet irradiation, the deterioration state of the pipe and the mechanical properties of the pipe were monitored every predetermined time.

Monitoring of the deterioration state of the pipe was performed as follows.
First, a canner was slid in the axial direction on the outer peripheral surface of the pipe that had been irradiated with ultraviolet rays for a predetermined time, and the surface portion was cut to obtain a resin section sample having a thickness of 50 μm, a length of 80 mm, and a width of 5 mm. By performing this every predetermined time, resin section samples with different integrated UV irradiation doses were obtained.

Each resin section sample was subjected to FT-IR measurement by a reflection method (using Spectrum One (manufactured by PerkinElmer)). One of the obtained FT-IR spectra is shown in FIG. 4B in comparison with the case of a new product (FIG. 4A). In FIG. 4, the horizontal axis represents the wave number (cm ⁻¹ ), and the vertical axis represents the relative transmittance. The degree of degradation, the relative intensity of the peak around 1700 cm ^-1 indicating the absorption of the carbonyl groups generated by oxidation of the resin (e.g., 1600 cm ^-1 or 1800 cm ^-1 or less) (in FIG. 4 (b), the circle surrounding peaks) Was observed by detecting

  Further, in the monitoring of the mechanical properties of the pipe, a tensile test, a falling weight impact test, and a flat test were performed on the pipe at predetermined time intervals.

  As a result, a positive correlation was confirmed between the ultraviolet irradiation time and the degree of deterioration obtained by IR measurement. Further, as shown in FIG. 3, with the progress of the degree of deterioration obtained by the IR measurement, the tensile strength did not show a significant decrease, but rather showed a tendency to increase, while the impact strength and the flat strength were reduced. , A sharp drop was observed in the short term.

  In addition, it was also confirmed that the tensile strength, the impact strength, and the flatness before and after collection of the resin section sample were substantially the same before and after collection of any of the resin section samples.

[Example 2]
A hard polyvinyl chloride resin pipe (Eslon VP pipe manufactured by Sekisui Chemical Co., Ltd., caliber 50A) was exposed to ultraviolet light outdoors (actually exposed product).
In the same manner as in Example 1, the canner was slid in the axial direction on the outer peripheral surface of the actual exposed product, and the surface portion was cut to obtain a resin section sample, which was subjected to FT-IR measurement by a reflection method.

As a result, as in FIG. 4 (ii), an IR spectrum having a peak at 1711 cm ⁻¹ indicating absorption of a carbonyl group generated by oxidation of the resin was obtained.
In addition, it was also confirmed that the tensile strength, the impact strength, and the flat strength did not substantially change before and after the sampling of the resin section sample.

  Although the preferred embodiments of the present invention have been described above, the present invention is not limited thereto, and various other embodiments may be made without departing from the spirit and scope of the present invention. Furthermore, the functions and effects described in the present embodiment are merely examples, and do not limit the present invention.

  In this specification, the resin piping system 100 corresponds to the “resin piping system” in the claims, the resin section sample 150 corresponds to the “resin section sample”, and the depth D is a pipe from which the resin section sample is to be collected. The thickness t corresponds to the “thickness” of the resin section sample from the system surface.

100 Resin piping system 150 Resin section sample D Depth t Thickness

Claims (8)

A step of cutting a part of the surface of the pipe or the joint and collecting a resin section sample containing the hard polyvinyl chloride while maintaining the existing structure of the resin piping system including the pipe or the joint made of the rigid polyvinyl chloride; ,
An analysis step of subjecting the resin section sample to analysis to obtain analysis information,
Look including a diagnostic process for diagnosing a deterioration state of the resin pipe system from the analysis information,
The diagnostic step, by using a calibration curve which indicates a correlation between index and impact strength and / or retention of the flat intensity of the analysis information, the impact strength and / or including the step of estimating the retention of flat intensity , A method for diagnosing deterioration of resin piping systems.   The deterioration diagnosis method according to claim 1, wherein the resin section sample is collected within a depth range of 200 µm or less from the surface of the resin piping system.   The method for diagnosing deterioration according to claim 2, wherein the thickness of the resin section sample is 10 µm or more and 200 µm or less.   The method for diagnosing deterioration according to claim 1, wherein the resin section sample is collected while the internal fluid is flowing through the resin piping system.   The method for diagnosing deterioration according to claim 1, wherein the resin section sample is collected by cutting along the axial direction.   The deterioration diagnosis method according to claim 1, wherein in the analysis step, a deterioration state due to oxidation is measured.   The degradation diagnosis method according to claim 1, wherein in the analysis step, analysis information is obtained from the resin section sample using X-ray photoelectron spectroscopy, visible ultraviolet absorption spectrum, infrared absorption spectrum, or Raman spectrum. The deterioration diagnosis method according to claim 1, wherein an infrared absorption spectrum method of a transmission method is used in the analysis step.