JP2011196799A - Rubber product inspection method and rubber product inspection device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a rubber product inspection method and device, which uses AE waves to nondestructively inspect a rubber product.SOLUTION: In the rubber product inspection method, an AE emitted from a break in a rubber product is sensed with AE sensors and the change over time of the AE is derived. From the characteristic of the change over time, a determination is made as to whether the AE is emitted from the rubber product when a supersaturated gaseous body forms a bubble or is emitted when a crack arises with a bubble as a cause. The change over time of the AE signal is also compared with pre-measured data, the progress of the break in the rubber product is assessed, and a determination of the quality of the rubber product is made.

Description

  The present invention relates to a rubber product inspection method and a rubber product inspection device. More specifically, the present invention relates to an inspection method and a rubber product inspection device for detecting an elastic wave generated from a rubber product and determining a damaged state or quality of the rubber product from the characteristic of the elastic wave.

  Rubber seal members typified by O-rings are used in a wide range of fields, from home appliances to large machines, precision equipment to construction machinery. Rubber has excellent properties such as plasma resistance, heat resistance, cleanness, non-adhesiveness, chemical resistance, solvent resistance, oil resistance, and has an advantage that it can be easily manufactured into a desired shape. In addition, rubber has a long history of rubber production for centuries since it was extracted from natural plants and used for industrial purposes. However, especially in severe environmental conditions such as high temperature, vacuum, high pressure, etc., in environments where high airtightness is required, etc., with regard to rubber products, rubber seal materials, etc., quality control and design at the time of production, Designed and used with great effort, meticulous attention and knowledge.

  Such sealing materials must be replaced regularly or regularly inspected. For the inspection of rubber products, various methods and detection principles have been proposed and used. For example, it is observed with X-rays or the surface is observed with the naked eye or a microscope. Patent Document 1 discloses a method of observing a crack on the surface of a belt after stretching the rubber belt a plurality of times. For this observation, mechanical energy is added to the belt. However, as a method for inspecting a crack inside the rubber product, a non-destructive inspection without applying a load to the rubber product is preferable.

  One method of nondestructive inspection is a method using acoustic emission. Acoustic emission (hereinafter referred to as AE) is an elastic wave that is emitted when a material is deformed, broken, or cracked. This elastic wave can be detected by a detection element installed on the surface of the material. AE depends on the type of material and its type of deformation, fracture, crack, etc., but usually has a frequency band of several kHz to several MHz. For example, AE generated in a metal material is a signal having a frequency of mainly 100 kHz to 1 MHz.

  In the case of a rubber material, a signal having a frequency of 1 MHz or less is targeted as in the case of a metal material. As a sensor for detecting AE, a piezoelectric element is generally used, and this AE is detected by bringing the piezoelectric element into close contact with the surface of the material. As an example of this, a quality control system for laminated rubber is disclosed in which an AE sensor attached to a laminated rubber used in a seismic isolation structure detects an AE signal generated from a defect in the laminated rubber (Patent Document 2). 3). In this system, the arrival order and time difference of AE signals detected by a plurality of AE sensors are measured, and the position where a defect occurs is specified (see paragraph [0026] in the specification of Patent Document 2).

  Further, in this system, ultrasonic waves generated with the occurrence and development of microcracks in the laminated rubber are detected (see paragraph [0026] of the specification of Patent Document 2). Furthermore, Patent Document 4 discloses a method and an apparatus for estimating a damaged state of a rubber product such as a tire. Install the AE sensor inside the wheel rim of the tire, detect the AE wave, compare the degree of change in the accumulated number of AE waves and the relational data of the accumulated number of AE waves and the tire damage state in advance. Estimated damage status.

(Event method and ring-down method)
By detecting AE, it is possible to monitor the occurrence of cracks in the material and the progress of the cracks. The AE signal is composed of elastic waves having a plurality of frequencies that are continuously generated in a short period of time, and the strength and size thereof vary depending on the type of material, the size of a crack, and the like. There are the following two methods for processing a signal detected by an acoustic emission sensor (hereinafter referred to as an AE sensor) for detecting AE and outputting it as an electrical signal. The AE signals received and observed by the AE sensor can be classified into two types having different properties.

  The first method is an event method in which one AE signal is counted as one. In this event method, an AE signal to be counted is called an AE event count, and an AE event count number per unit time is called an AE event count rate. This AE event count rate is often used for evaluation of fatigue crack propagation in consideration of the fact that the AE signal generated from a crack that propagates due to repeated stress is basically discrete.

  The second method is a ring-down method that counts all amplitudes that are equal to or greater than a defined reference value. An AE signal counted by this ring-down method is called an AE ring-down count, and an AE ring-down count number per unit time is called an AE ring-down count rate. FIG. 15 illustrates the difference between the event method and the ring-down method. FIG. 15A shows one AE signal. FIGS. 15B and 15C show the difference between the event method and the ring-down method, which are two methods for counting the AE signal.

  FIG. 15B shows the event method. FIG. 15C shows the ring-down method. The maximum intensity of the AE signal in FIG. 15A is equal to or greater than a set threshold value. As shown in FIG. 15B, the AE signal in FIG. 15A is counted as “1” in the event method. In the ring-down method, all of the plurality of elastic waves constituting one AE signal are counted with an intensity equal to or higher than a set threshold value. For this reason, the AE signal in FIG. 15A is counted as “4” in the ring-down method, as shown in FIG. 15C.

JP 2005-164499 A JP-A-11-64098 JP-A-11-64099 JP, 2005-337929, A

  As described above, in the method of observing the surface of a rubber product with the naked eye, a microscope, or the like, even if damage on the surface of the rubber product can be found, damage such as a crack generated inside cannot be found. A method for detecting AE waves is known as a non-destructive inspection technique for metal materials. However, the amplitude of AE waves generated from rubber products is orders of magnitude smaller than that of AE waves generated from metal. Similarly, the incidence of AE waves generated from rubber products is orders of magnitude less than that of metal.

  In Patent Documents 2 and 3 described above, an AE sensor is used for inspection of a large rubber material used for a building structure. This rubber material is supported by a large pressure from a building structure or the like. In addition, those described in Patent Documents 2 and 3 only see a change in the AE count. Under such circumstances, a technology for inspecting a minute rubber product such as a rubber seal material using an AE sensor has not yet been established.

The present invention has been made based on the technical background as described above, and achieves the following objects.
An object of the present invention is to provide a rubber product inspection method and a rubber product inspection device for inspecting a rubber product by nondestructive inspection using AE waves.
Another object of the present invention is to provide a rubber product inspection method and a rubber product inspection device for inspecting a rubber seal material by nondestructive inspection using AE waves.

〔Definition of terms〕
In the present invention, rubber products, cracks, and acoustic emission (AE) are used as defined below. Hereinafter, each term will be described.

  “Rubber products” refers to products and parts that use rubber as a material. The type of rubber is appropriately selected and used according to the application, application location, application equipment, and the like. Examples of rubber types include natural rubber, isoprene rubber, butadiene rubber, styrene butadiene rubber, butyl rubber, chloroprene rubber, nitrile rubber, ethylene propylene rubber, acrylic rubber, epichlorohydrin rubber, hypalon, urethane rubber, silicone rubber, and fluorine rubber. Perfluoro-rubber. Further, ethylene propylene rubber (EPDM), acrylonitrile butadiene rubber (NBR), water-added NBR, silicone rubber, fluorine rubber and the like can be mentioned. In order to reinforce these rubber materials, but not limited to these, those obtained by adding fillers such as carbon black and silica, anti-aging agents, oils and the like can also be used.

  "Crack" (Crack in English) is a defect such as a crack, a crack or a crack generated in a material, in the case of the present invention, in a rubber product. When a rubber member is repeatedly or statically loaded, a crack is generated from the surface or inside of the rubber product or member. The generated crack is repeatedly developed by the load, and eventually the member or the rubber product is broken. When a load is applied to a material having a crack, a stress concentration with a high load is generated in the crack, particularly in the vicinity of the tip of the crack.

  If this stress concentration exceeds the fracture toughness of the material, the crack length can be extended and crack growth occurs. About 80% of the fatigue life of the member is expended to develop until the generated crack can be observed with the naked eye. In other words, about 80% of the fatigue life of the member is spent on the development of a crack of 1 mm or less that is difficult to observe with the naked eye. Therefore, in order to prevent destruction of the member, it is necessary to detect a crack of 1 mm or less that is difficult to observe with the naked eye.

  “Acoustic Emission (AE)” is an elastic wave that is emitted as a material deforms, breaks or cracks. This elastic wave can be detected by an AE detection element installed on the surface of the material. The AE sensor is an element for converting an elastic wave into an electric signal and outputting it. The AE sensor is generally composed of a piezoelectric element, detects an AE signal in close contact with the material surface, converts the AE signal into an electrical signal, and outputs the electrical signal.

  An object of the present invention is to inspect a crack generated inside a rubber product and grasp its size and progress. As a result, the internal crack condition of the rubber product used in a severe environment such as high pressure can be detected in a slight state, and the use can be stopped before the internal crack reaches the surface. Thereby, the remarkable effect that the failure avoidance of the apparatus which uses a rubber product, the performance maintenance, and an accident can be prevented beforehand is brought about. Of course, since the internal crack condition of the rubber product can be detected in a slight state, the maintenance of the apparatus using the rubber product becomes easy.

  For example, let us consider the case of a rubber seal part used for sealing a high-pressure fluid of a machine, vibration isolation, or the like. When the crack generated inside the seal component progresses and reaches the surface, the original functions such as sealing performance and pressure resistance cannot be performed. Furthermore, if the crack advances to the surface of the seal part and ruptures, it may cause a mechanical accident. Therefore, it is desirable to be able to detect a crack generated inside the seal component as quickly as possible and to inspect its progress as needed. It is also desired to predict when the crack generated inside the seal part will progress and reach the surface.

In order to achieve the above object, the present invention employs the following means.
The rubber product inspection method of the present invention is an inspection of a rubber product for inspecting the damage of the rubber product by detecting an elastic wave (AE) generated from a crack of the rubber product by an elastic wave detecting means (AE sensor). Is the method. The method for inspecting a rubber product according to the present invention includes detecting the elastic wave (AE) generated from the rubber product after decompressing the rubber product in a high-pressure gas atmosphere environment composed of gas, and detecting the elastic wave (AE). From the characteristics of the change over time, the elastic wave is (a) the elastic wave generated when a supersaturated gas becomes a bubble from the rubber product, or (b) the bubble is a starting point. In this case, it is determined whether or not the elastic wave is generated when a crack is generated, and the state of damage of the rubber product is inspected.

  Further, the rubber product inspection method of the present invention may be presumed that the rubber product is largely damaged when the change of the crack with time indicates an indication that the crack has progressed and progressed to the surface of the rubber product. . Furthermore, in the method for inspecting a rubber product of the present invention, the determination may be made by comparing the change with time with the characteristics of the rubber product whose damage state is known in advance. The rubber product may be an O-ring.

  The rubber product inspection apparatus of the present invention is for detecting elastic waves (AE), and is an elastic wave detection means (AE sensor) fixed to or installed near a rubber product, and the elastic wave detection means (AE sensor). ), The elastic wave (AE) generated from the rubber product is analyzed, the change with time is obtained, and the rubber product comprising the analysis means for judging the damage of the rubber product is inspected. It is a device for.

  The analysis means obtains a change with time of the elastic wave (AE) detected by an elastic wave detection means (AE sensor) after decompressing the rubber product under a high-pressure gas atmosphere environment, and from the characteristics of the change with time, The elastic wave is (a) the elastic wave generated when a supersaturated gas becomes a bubble from the rubber product, or (b) the elastic wave generated when a crack is generated from the bubble. In the case of the elastic wave generated from the crack, the analysis means determines that the rubber product is damaged, and outputs a signal to that effect.

  When the time-dependent change of the crack indicates that the crack has progressed and progressed to the surface of the rubber product, the analyzing means estimates that the rubber product is damaged and outputs a signal to that effect. Good. The analysis means may include comparison means for comparing the change with time with characteristic data of the rubber product whose damage state is known in advance. The rubber product may be an O-ring.

  The rubber product inspection method and the rubber product inspection apparatus of the present invention can detect AE waves generated from the inside of the rubber products, and can evaluate the rubber products from the trends of the AE waves and perform nondestructive inspection. .

FIG. 1 is a conceptual diagram illustrating an outline of a damage detection system 1 for rubber products according to an embodiment of the present invention. FIG. 2 is a diagram illustrating an example of the O-ring of the sample 3 according to the present embodiment of the present invention. FIG. 2A is a conceptual diagram of the O-ring, and FIG. 2A is a cross-sectional view taken along line AA. FIG. 3 is a block diagram showing a structural example of the signal processing unit 5 of the rubber product damage detection system 1 according to the embodiment of the present invention. FIG. 4 is a graph showing the relationship between the AE event count generated in rubber and the AE amplitude. FIG. 5 is a graph showing the relationship between the AE event count generated in rubber and the AE frequency. FIG. 6 is a conceptual diagram showing an outline of Experiment 1 showing a method for comparing attenuation of AE signals in a metal material and a rubber material. FIG. 7 is a graph showing the results of Experiment 1, and is a graph showing the results of measuring the attenuation of AE waves generated in the metal material and the rubber material. FIG. 8 is a conceptual diagram showing the state of measurement in Experiment 2. FIG. 8 (a) is a conceptual diagram showing the dimensions of the test piece, and FIG. It is a conceptual diagram which shows a mode that it measures. FIG. 9 is a graph showing the results of Experiment 2. FIG. 9A shows the case of copper, and FIG. 9B shows the case of rubber. FIG. 10 shows the results of Experiment 3 and is a photograph showing a cross section of a rubber test piece. FIG. 10 (a) is a photograph after the test exposed to high-pressure gas is repeated three times. (B) is a photograph after the test exposed to high-pressure gas was repeated five times. FIG. 11 is a graph showing the result of the event rate obtained by signal processing the detected AE after repeated exposure tests. FIG. 12 shows an internal crack occurrence state after decompression of a cylindrical test piece exposed in high-pressure hydrogen gas. FIG. 13 is a graph showing the relationship between the AE event count and the AE amplitude generated from the test piece of FIG. 12, FIG. 13 (a) is a graph showing measurement data, and FIG. 13 (b) is a graph showing FIG. Is a logarithmic axis. FIG. 14 is a diagram stylistically showing the mechanism of occurrence of cracks and bubbles in a rubber product. FIG. 14 (a) is a state of supersaturation, FIG. 14 (b) is the generation of bubbles, and FIG. 14 (c). Fig. 2 illustrates how a crack is generated starting from a bubble. 15A and 15B are diagrams for explaining types of AEs to be measured. FIG. 15A shows one AE signal, FIG. 15B conceptually shows an event method, and FIG. 15C shows a ring-down method. It shows.

[Overview of rubber product damage detection system]
FIG. 1 is a diagram illustrating an outline of a damage detection system 1 for rubber products. A rubber product damage detection system 1 shown in FIG. 1 is a system for confirming and verifying the damage of a rubber product through experiments. From the pressure device 2, the sample 3, the AE sensor 4, the signal processing unit 5, the computer 6, and the like. It is configured. The pressure device 2 places the sample 3 therein, and supplies gas such as hydrogen gas into the pressure device 2 with gas supply / exhaust means such as a pump 7 or exhausts the gas in the pressure device 2. It is a device that adjusts the gas pressure to a predetermined pressure.

  When a crack or macroscopic defect exists in a rubber material exposed to high-pressure gas, a crack is generated after decompression in an exposure at a pressure that does not normally generate a crack or a crack that has developed. Or the crack which has already occurred develops. The AE signal accompanying the generation and propagation of this crack is measured. In addition, as shown in FIG. 1, an AE sensor may be directly attached to an operating rubber product without measuring the rubber product in the pressure device, and the operating AE signal may be measured. In the present embodiment, the sample 3 is a rubber product. In the present embodiment, the sample 3 is a rubber O-ring that is one of seal parts.

  However, the sample 3 is not limited to a seal part, an O-ring, or the like, and may be any shape as long as it is a rubber part or product. FIG. 2 shows an example of an O-ring of sample 3 used in this embodiment. As shown in FIG. 2 (a), this O-ring has a radius R1 on the inside and a radius R2 on the outside, and is a ring made of a rubber material having a circular cross-sectional shape. FIG. 2B shows a cross-sectional view taken along the line AA in FIG. This cross section is a circle having a predetermined diameter D (= R2-R1). In the measurement described later, an O-ring having a cross-sectional diameter D of 3.23 mm and an inner radius R1 of 5.95 mm was used.

  The AE sensor 4 detects AE generated from the sample 3. The AE sensor 4 can be of any shape and operating principle, but in the present embodiment, it is made of a piezoelectric material. The AE sensor 4 converts the detected AE into an electrical signal and outputs it. This output is input to a subsequent apparatus connected to the AE sensor 4. In the example shown in FIG. 1, the output signal of the AE sensor 4 is input to the signal processing unit 5. The signal processing unit 5 is for analyzing the detection signal received from the AE sensor 4.

  FIG. 3 is a block diagram illustrating a circuit example of the signal processing unit 5. The signal processing unit 5 includes a memory 11, a CPU 10, an input interface 12, an output interface 13, and the like. The memory 11 stores a control program (not shown) for controlling the signal processing unit 5. When the signal processing unit 5 is activated, this control program is called and operates. The input interface 12 is an interface for inputting an AE signal to the signal processing unit 5. The input interface 12 is directly connected to the AE sensor 4 and receives the AE signal received by the AE sensor 4.

  The received AE signal is stored in the memory 11 and read and processed by the control program. The CPU 10 sequentially executes the instructions of the control program stored in the memory 11 to operate the signal processing unit 5. The output interface 13 is for outputting the result of processing the AE signal by the signal processing unit 5. That is, the result of processing the data that is the AE signal by the control program is output. The output AE signal data is provided to the computer 6. For example, the AE signal data is output in a format that can be confirmed by the operator in the computer 6 and displayed on a display or the like.

  It can also be provided to other electronic computers connected to the output interface 13. The system 1 according to the present embodiment includes a preamplifier 16 for amplifying a signal received by the AE sensor 4 and outputting the amplified signal to the signal processing unit 5 as indicated by a broken line in FIG. The signal processing unit 5 has a power interface 15 for supplying power. The power supply interface 15 is connected to a direct current or alternating current power source or the like. The signal processing unit 5 incorporates a power source such as a battery, and the power interface 15 is connected to the built-in power source.

  Next, the signal processing unit 5 shows an outline of processing the AE signal. Processing of the AE signal is performed by a control program. These processes can also be realized by a circuit having the same function as this control program. The signal processing unit 5 stores the AE signal in the memory 11 from the data received from the AE sensor 4. At this time, reception time data indicating the reception time is stored in association with each other. Further, other data relating to the internal pressure of the pressure device 2 is also stored. The signal processing unit 5 reads out the AE signal and reception time data stored in the memory 11 and performs data processing to calculate an AE event count and an AE amplitude.

  Then, the quality of the sample 3 is determined by comparing the relationship between the AE event count and the AE amplitude with a preset use limit line (described later). The time course of the crack in sample 3 is presumed that sample 3 is severely damaged when it shows signs that the crack has progressed and progressed to the surface of the rubber product, or when the use limit line is reached. The use limit line can be used as this indication. Moreover, this time-dependent change is compared with the characteristic of the sample 3 whose damage state is known in advance, the damage of the sample 3 is evaluated, and the quality of the sample 3 can also be determined.

  The signal processing unit 5 outputs the calculation result of the AE event count and the AE amplitude, the determination result, and / or the contents of the memory 11 from the output interface 13 as output data. It is preferable that the output format and device are graph data and tabular data to be used as data for a display device or a printing device. It can also be output in text format data for processing by other electronic computers. It is also possible to add the latest data to this graph and output it.

  If it does in this way, it will become easy for the user of a sample, an administrator, etc. to grasp progress of the damage state of sample 4. As described above, the signal processing unit 5 includes a pressure measuring device (not shown) and the like for measuring the internal pressure of the pressure device 2. The signal processing unit 5 receives data from the AE sensor 4 continuously, periodically, or at a designated time. Further, the signal processing unit 5 receives data from the AE sensor 4 at the time of an operator's reception request or a data request from a computer 6 or other electronic device connected to the signal processing unit 5.

  Further, the signal processing unit 5 outputs the calculation result continuously, periodically, or at a designated time. The AE sensor 4 is fixed so as to contact the surface of the sample 4 in the pressure device 2. As a fixing means at the time of fixing, any method may be used as long as the AE sensor 4 is brought into close contact with the surface of the sample 3 and comes into contact therewith. Although not shown, the internal pressure of the pressure device 2 is preferably measured using a pressure measuring device. The pressure measuring device may be a device included in an apparatus for filling the pressure device 2 with a fluid.

  Pressure measuring instrument, as long as obvious to those skilled in the art, may be of any type and measurement principle include known measuring means. The AE sensor 4 is preferably one that adjusts a predetermined detection sensitivity. That is, it is preferable that the AE sensor 4 can adjust the detection sensitivity for detecting the AE signal. This detection sensitivity may be set by the signal processing unit 5. The signal processing unit 5 processes a value greater than a predetermined reference value among signals received from the AE sensor 4 as an AE signal. The signal processing unit 5 can output the data received from the AE sensor 4 as it is from the output interface 13.

  The signal processing unit 5 filters the data received from the AE sensor 4 by frequency and intensity, performs elementary signal processing, and outputs the data from the output interface 13. The output raw data is processed by the computer 6 connected to the output interface 13. For example, the computer 6 performs processing such as calculation and determination of the AE event count and the AE amplitude described above, which has been processed by the signal processing unit 5. In the signal processing unit 5, an AE signal having a predetermined frequency is extracted by a filter, and the extracted AE signal is amplified by a main amplifier.

  Then, counting of the AE signal exceeding the preset AE amplitude value, calculation of the amplitude value, and Fourier transform are performed, and the AE event count, the AE amplitude, and the frequency of the AE signal are measured. The computer 6 is an electronic computer for analyzing the signal output from the signal processing unit 5. Although not shown, the computer 6 is an electronic computer including a CPU, a RAM, a ROM, an auxiliary storage device, an input / output interface, and input / output devices such as a display, a mouse, and a keyboard. The computer 6 can use any electronic computer as long as it can perform the processing described in the present embodiment.

  The computer 6 analyzes a series of AE signals detected by the AE sensor 4 and performs analysis with reference to a database (not shown). The database is a database that stores data related to the AE signal emitted from the sample 3. The database stores data relating to normal, that is, usable sample 3, data relating to sample 3 that has become unusable, and the like. Data can be updated in the database from the signal processing unit 5 or the computer 6. In addition, an administrator, a user, etc. can update the database manually.

  The database is stored in the main storage device or auxiliary storage device of the computer 6 or a connected external storage device. The database may be installed at a location accessible from the computer 6 by wireless or wired communication means. Analysis by the computer 6 is performed in the following procedure. The result of the analysis by the computer 6 is an evaluation of the quality of the sample 3. For example, when the crack in the sample 3 is not large, that is, when it is determined that the sample 3 can perform its original function, a signal indicating an inspection pass is output.

  When the crack in the sample 3 is large, that is, when it is determined that the sample 3 cannot perform its original function, a signal indicating an inspection failure is output. Of course, even if the crack is not large but the number is large, a signal indicating failure of inspection is output. The computer 6 can totalize the inspection results of the sample 3 including the past inspection data, collect them in a visually checkable graph, etc., and display them on the display or print them on a printing device.

  FIG. 4 is a schematic diagram showing a change over time in the relationship between the AE event count of the AE signal generated from the O-ring of the sample 3 and the AE amplitude. The AE event count and the AE amplitude have a power relationship regardless of the presence or absence of cracks. In the case of the graph A in which no crack is generated, the slope m is 4, and the bubbles in the sample 3 are in a state before the crack is generated. When a crack is generated starting from a bubble, the slope m becomes 2 as shown in the graph B. At this time, the crack is a relatively minor damage. When the crack damage becomes severe, the relationship between the AE event count and the AE amplitude shifts in the upper right direction in the figure as indicated by the arrows in the figure as indicated by the arrows in the figure.

  When the sample 3 is in the state of the graph D, the sample 3 is damaged to the extent that it can no longer be used for a machine or the like. The broken line graph in the figure is a line that is set as a pass line (use limit line) by which the quality of sample 3 can be determined. Data similar to the graph of FIG. 4 is stored in the database. The computer 6 determines the sample 3 by comparing the newly measured AE signal with this data stored in the database. Therefore, the computer 6 can determine the quality of the sample 3 based on the use limit line by comparing the measurement result of the sample 3 with the data of FIG. 4 stored in the database.

  FIG. 5 is a schematic diagram of the relationship between the AE event count and the AE frequency analyzed by Fourier-transforming the AE signal. The frequency of the generated AE signal differs depending on the formation of a bubble and the generation of a crack, and it is possible to extract only the AE signal accompanying the generation of a crack using a bandpass filter. That is, in the example of FIG. 5, it can be seen that the frequency of the AE signal generated when bubbles are formed is lower than the frequency of the AE signal generated when cracks are generated. By filtering and monitoring these frequencies with a band-pass filter, it is possible to monitor whether bubbles are formed or cracks are generated.

[Experiment]
Below are some experimental measurements that support the analysis of this sample. In Experiment 1, AE signals generated by a metal material and a rubber material were measured and their attenuation rates were compared. Experiment 2 receives the AE signal generated by the metal material and the rubber material, and analyzes the difference between the constituent signals. In Experiment 3, a rubber sample is placed in a high-pressure gas, the pressure of the gas is increased, and the pressure reduction is repeated one or more times, and then AE is measured.

[Experiment 1: Comparison of attenuation of AE signal generated by metal material and rubber material]
First, Experiment 1 is described. FIG. 6 is a conceptual diagram for measuring the attenuation amount of the AE wave of each frequency component using rubber test pieces having different thicknesses. Three types of cylindrical rubber test pieces having different thicknesses were prepared, and a first AE sensor and a second AE sensor were attached to both ends of the test piece. The dimensions of the test piece were 13 mm in diameter and 2, 6 and 12 mm in thickness. The 1st AE sensor and the 2nd AE sensor are AE sensors AE-900F2 manufactured by NF Circuit Design Block Co., Ltd. (English notation: NF Corporation, location: Yokohama, Kanagawa, Japan), AE sensor for broadband of 300 kHz to 2.2 MHz. Met.

  And the electric signal of the sine wave produced | generated with the transmitter was sent to 1st AE sensor. This sine wave was in the range of 100 kHz to 3 MHz. The transmitter was a multi-function generator WF 1973 manufactured by NF Circuit Design Block Co., Ltd. (English notation: NF Corporation, location: Yokohama, Kanagawa, Japan). The first AE sensor functioned as a broadband AE signal transmitter. The sine wave transmitted from the first AE sensor and transmitted through the test piece was received by the second AE sensor. The second AE sensor functioned as a receiver for the AE signal. The AE signal received by the second AE sensor was amplified with a preamplifier (Pre-Amplifier 9913, manufactured by NF Circuit Design Block Co., Ltd.) and observed with an oscilloscope (WaveRunner 6030A manufactured by LeCroy (New York City, USA)).

Experiment 1 was conducted in the atmosphere at room temperature. In this experiment 1, the amplitude reduction of the receiving side sine wave with respect to the transmitting side sine wave was measured for each thickness of each test piece to evaluate the influence of the frequency on the AE signal attenuation of the rubber material. FIG. 7 is a graph showing the experimental results of Experiment 1. The vertical axis of the graph of FIG. 7 is the amplitude A of the receiving AE signal to the amplitude A ₀ of the sending of the AE signal and the horizontal axis is the thickness of the test piece. The attenuation of the AE signal in the rubber material is larger than the attenuation of the AE signal in the metal material. As apparent from the graph shown in FIG. 7, the attenuation amount of the AE signal having a frequency of 1 MHz or less is about 50% even when the thickness of the test piece is 10 mm. Therefore, assuming a rubber test piece having a thickness of about 10 mm, the frequency of the target AE signal should be 1 MHz or less.

[Experiment 2: Difference in AE signal generated between metal material and rubber material]
Next, Experiment 2 will be described. FIG. 8 shows a state of an experiment for measuring a difference between AE signals generated between a metal material and a rubber material. The test piece is a trouser test piece. The dimensions of the test piece are illustrated in FIG. The test piece was 100 mm in length, 15 mm in width, and 2 mm in thickness. The notch was 40 mm in the length direction from the end of the test piece. Two types of test pieces, copper and rubber, were used. In this experiment 2, an AE signal generated in each material of a metal material and a rubber material is received and analyzed, and the difference in the constituent signals of the AE signal is analyzed.

  As shown in FIG. 8B, the AE sensor was placed in close contact with the test piece. And as shown by the arrow, the test piece was pulled and torn. The elastic waves generated along with the cracks propagating from the notch during tearing were measured. Experiment 2 was performed in air at room temperature. The measurement results are shown in the graph of FIG. The graph shown in FIG. 9A is for copper, and the graph shown in FIG. 9B is for rubber. The horizontal axis of this graph shows the elapsed time at the time of measurement. The right vertical axis represents the AE hit count.

  The left vertical axis indicates the tearing force when tearing the test piece. As can be seen from the graph of FIG. 9, the crack propagates in the region where the stress becomes flat. As can be seen from these graphs, in the case of rubber and copper, AE is generated as the crack progresses. However, in the case of rubber, the AE event count rate generated is smaller than that of steel.

[Experiment 3: Repeated exposure of rubber material to high pressure gas]
Experiment 3 is described. In Experiment 3, a cylindrical rubber test piece was placed in a chamber for high-pressure hydrogen gas, and the pressure of the high-pressure hydrogen gas was repeatedly applied to generate a crack inside the test piece. The test piece had a cylindrical shape with a diameter of 29 mm and a thickness of 12.5 mm. The material of the test piece was unfilled peroxide-crosslinked ethylene propylene rubber.

  The specimen is transparent. The specimen was placed in the chamber and exposed for 24 hours in an environment of high pressure hydrogen gas at a pressure of 0.7 MPa and a temperature of 25 ° C. Thereafter, the inside of the chamber was decompressed to generate a crack in the test piece. The specimen was removed from the chamber after decompression. Then, the occurrence of internal cracks in the test piece was observed with a microscope, and an AE sensor was mounted on the surface of the test piece, and the generated AE signal was measured. FIG. 10 is a photograph when the rubber test piece is observed after being repeatedly exposed to gas. FIG. 10 (a) is a photograph after the test exposed to high-pressure gas was repeated three times.

  FIG. 10 (b) is a photograph after the test exposed to high-pressure gas was repeated 5 times. In the figure, the generated crack can be clearly observed. As can be seen from this photograph, the crack is larger and the number of cracks is larger in the case of five times than in the case of three times. FIG. 11 is a graph showing the result of obtaining the event rate by performing signal processing on the detected AE. The vertical axis of this graph indicates the AE event count rate, and the horizontal axis indicates the elapsed time. From this graph, as the number of repeated exposure tests increases, the AE event count rate also increases with crack damage.

  FIG. 12 shows a rubber test piece exposed to hydrogen gas for 24 hours and then left in the atmosphere at room temperature. This rubber test piece was a cylindrical type made from unfilled sulfur vulcanized ethylene propylene rubber, and had a diameter of 29 mm and a thickness of 12.5 mm. The conditions for the hydrogen gas were a pressure of 0.7, 10, 30 MPa, and a temperature of 30 ° C. The test piece was obtained by observing the cross section of the test piece with an optical microscope after cutting the cross section of the test piece with a cutter three days after decompression. When the pressure of hydrogen gas was 0.7 MPa, no crack was generated on the test piece. When the hydrogen gas pressure was 10 MPa and 30 MPa, cracks were observed in the test piece.

  The higher the hydrogen gas exposure pressure, the more severe the cracks in the specimen. An AE sensor was attached to the surface of the test piece in FIG. 12 (a), and an AE signal generated after decompression was measured. FIG. 13 is a graph showing the relationship between the AE event count of the AE signal measured after decompression and the AE amplitude. The AE event count and the AE amplitude have a power relationship. The slope at a pressure of 0.7 MPa at which no crack was generated was m = 4. On the other hand, m = 2 at pressures of 10 MPa and 30 MPa at which cracks were observed. In addition, as the crack damage was more severe, the relationship between the AE event count and the AE amplitude shifted to the upper right in the figure.

[Summary of experimental data]
From these series of tests, it can be inferred that the following behavior was present in rubber products. When the rubber sample 3 is placed in the pressure device 2 and the pressure is increased, the hydrogen gas in the pressure device 2 becomes supersaturated. FIG. 14A illustrates this state in a stylized manner. When the internal gas is extracted from the pressure device 2 to reduce the pressure, supersaturated hydrogen in the rubber is bubbled into the rubber. FIG. 14B illustrates this state in a stylized manner, and bubbles are indicated by arrows. When the pressure is further reduced, a crack is generated starting from this bubble.

  FIG. 14C illustrates this state in a stylized manner, and a crack generated from the enlarged bubble is indicated by an arrow. The amount of hydrogen leaking from the sample increases as the crack progresses. And, it is expected that a significant crack can be generated by this hydrogen penetrating the sample. AE occurs both when bubbles are formed and when cracks occur. However, the characteristics of the generated AE are different between the formation of bubbles and the generation of cracks. This can be generally done as shown in the graph of FIG. The vertical axis of the graph in FIG. 13B indicates the AE event count.

  The horizontal axis indicates the amplitude of AE. Also, the graph when bubbles are formed is more gradual than the graph when cracks are generated. Therefore, attention is paid to the relationship between the AE count rate and the amplitude. The relationship between the AE count rate and the amplitude by repetition according to FIG. 13A is shifted to a graph in the upper right direction in the drawing when the pressure increases. The last graph is a graph when there is severe damage. According to the occurrence of cracks and their progress, the slope of the graph is gentler than that during bubble formation. The amplitude of AE at the time of bubble formation is smaller than that at the time of crack occurrence, and the count rate is also small.

  Therefore, in the case of rubber products, a use limit line is provided before the point of severe damage, and it is confirmed whether the relationship between the AE count rate and the amplitude has reached this use limit line. Can be judged. Thereby, it can also be determined whether or not there is a crack that causes damage to the surface of the rubber product. Therefore, from the viewpoint of utilization in industry, the use of rubber products that exceed this use limit line should be stopped for the purpose of ensuring safety. This is very useful in the field of machine inspection and the like.

  Thus, due to the change in AE over time with respect to the crack, the crack generated from the inside of the rubber product, for example, the O-ring, stops using before it penetrates the surface. This system can detect damage to rubber products before the internal crack reaches the surface. In Experiments 1 to 3 described above, hydrogen was used for the pressure device 2, but any gas that does not interfere with the rubber product, for example, an inert gas such as helium or nitrogen can be used.

  The present invention may be used in industrial fields that use rubber products. The present invention is preferably used in a field where a rubber seal material is used. Especially this invention is good to be utilized for the product which needs to detect and prevent the damage by a crack like rubber packing in advance.

1 ... Rubber product damage detection system 2 ... Pressure device 3 ... Sample (rubber product)
4 ... AE sensor 5 ... Signal processing unit 6 ... Computer 16 ... Preamplifier

Claims (8)

A method for inspecting a rubber product to detect damage to the rubber product by detecting an elastic wave (AE) generated from a crack in the rubber product with an elastic wave detecting means (AE sensor),
After depressurizing the rubber product in a high-pressure gas atmosphere environment consisting of gas, the elastic wave (AE) generated from the rubber product is detected, and the time-dependent change of the elastic wave (AE) is obtained.
From the characteristics of the change over time, the elastic wave is (a) the elastic wave generated when a supersaturated gas becomes a bubble from the rubber product, or (b) a crack is generated from the bubble. A method for inspecting a rubber product, comprising: determining whether or not the elastic wave is sometimes generated and inspecting the state of damage to the rubber product. In the rubber product inspection method according to claim 1,
The method for inspecting a rubber product, wherein the rubber product is presumed to be damaged when the change with time of the crack shows an indication that the crack has progressed to the surface of the rubber product. In the inspection method of the rubber product according to claim 1 or 2,
The determination is made by comparing the time-dependent change with the characteristic of the rubber product whose damage state is known in advance. The method for inspecting a rubber product according to claim 1 selected from claims 1 to 3.
The rubber product is an O-ring. A method for estimating a damage state of a rubber product. Elastic wave detection means (AE sensor) for detecting elastic waves (AE), fixed to rubber products or installed nearby
An analysis means which is detected by the elastic wave detection means (AE sensor), analyzes the elastic wave (AE) generated from the rubber product, obtains a change with time, and determines damage of the rubber product; A rubber product inspection device for inspecting damage to a rubber product comprising:
The analysis means includes
After depressurizing the rubber product in a high-pressure gas atmosphere environment, obtain the time-dependent change of the elastic wave (AE) detected by the elastic wave detection means (AE sensor),
From the characteristics of the change over time, the elastic wave is (a) the elastic wave generated when a supersaturated gas becomes a bubble from the rubber product, or (b) a crack is generated from the bubble. Determine whether the elastic wave is sometimes generated,
The analysis means includes
In the case of the elastic wave generated from the crack, it is determined that the rubber product is damaged, and a signal to that effect is output. In the rubber product inspection device according to claim 5,
When the time-dependent change of the crack indicates that the crack has progressed and progressed to the surface of the rubber product, the analyzing means estimates that the rubber product is damaged and outputs a signal to that effect. A rubber product inspection device. In the rubber product inspection device for rubber products according to claim 5 or 6,
The said analysis means has a comparison means which compares the said time-dependent change with the characteristic data of the said rubber product whose damage state is known beforehand. The rubber product inspection apparatus characterized by the above-mentioned. The rubber product inspection device according to claim 1, wherein the rubber product inspection device is selected from claims 5 to 7.
The rubber product inspection device according to claim 1, wherein the rubber product is an O-ring.