JP5241684B2 - Seismic impact force measurement system and measurement method - Google Patents

Description

  TECHNICAL FIELD The present invention relates to a technical system of a measurement system and a measurement method of an earthquake impact force that measures an impact force received by an underground structure (underground object) such as an underground wall, an underground pile (foundation pile), and a tunnel due to an occurrence of an earthquake. It is.

When a structure is subjected to a strong impact due to the occurrence of an earthquake, it is possible to know how much impact force is applied to underground structures such as underground walls and underground piles embedded in the underground part of the structure. It is very important to judge the possibility of earthquake damage such as cracks and fractures in the city, or to determine the repair method in the event of damage.
By the way, it is difficult to know the degree of earthquake damage of underground buried objects by visual inspection, etc., and therefore, connecting a lead wire to a reinforcing bar buried as an underground pile and connecting the lead wire to an electric resistance measuring instrument The resistance value is measured in advance, and if an earthquake occurs, the electrical resistance value after the earthquake is measured and compared with the normal measurement value. If a different measurement value is obtained, the foundation pile is destroyed or damaged. By applying a vibration device to an object that is evaluated as having been received (Patent Document 1) or by applying vibration to an underground object, and comparing the state of reflected waves generated by the vibration before and after the earthquake The thing which evaluated the presence or absence and the grade of the destruction of a pile is proposed (patent document 2). However, these are for evaluating the presence or degree of destruction of the underground buried object, and do not know how much impact force the structure has received.
In addition, a stress luminescent material that emits light in proportion to the stress generated by the received external force is used, and stress measurement is performed by observing the light emission state of the stress luminescent material (Patent Document 3), or two-component reaction The luminescent precursor that emits light is enclosed in a brittle material that is destroyed by a predetermined stress and inserted into the foundation pile. When the brittle material is destroyed by the stress generated in the foundation pile by an earthquake, the two liquids react. There is known a configuration in which light is emitted and whether or not a predetermined stress is applied or not is observed by observing the presence or absence of the light emission (Patent Document 4).

Japanese Patent Laid-Open No. 10-183658 JP 10-183659 A JP 2001-215157 A JP 2003-262554 A

  However, when the thing of the said patent document 3 is going to be used for the measurement of the impact force by an earthquake, the light emission of this stress light-emitting material has the problem that followability with respect to the stress of the earthquake which fluctuates constantly is bad, and an accurate stress measurement cannot be performed. is there. Moreover, the thing of patent document 4 is one-point detection whether it exceeded the predetermined stress, Comprising: There exists a problem that it cannot measure how much stress was generated. Moreover, the former is luminescence proportional to the magnitude of stress, and the latter is chemiluminescence, so the emission time is limited. For this reason, observation in real time is necessary, but at the time of earthquake occurrence When a power failure occurs or an observation machine such as a personal computer breaks down, there is a problem that the actual observation cannot be performed until the power supply or the observation machine is restored, and there are problems to be solved by the present invention.

The present invention was created in order to solve these problems in view of the above circumstances, and the invention of claim 1 visualizes the impact force that an object of an underground object receives due to an earthquake. A seismic impact force measuring system for measuring the seismic impact force, wherein the seismic impact force measuring system comprises a pressure-sensitive color forming body formed by encapsulating dyes or pigments in a plurality of types of capsules having different breaking strengths. The impact force measurement site receives the seismic impact force received by the subject according to the colored state caused by the capsule being broken and the dye or pigment being released according to the seismic impact force received by the subject. per the measurement, the sensitive pressure chromosome together with is adhered to the coloring material mounting plate which is rigid elongated member, emitting color bodies mounting plate shape to support provided in the impact force measurement site It has been a measurement system seismic impact force, characterized in that to be able to support a new sensitive pressure chromosome that mounted telescopically in the groove.
According to the invention of claim 2, the pressure-sensitive color developing body contains a color developer which reacts with the dye precursor and develops the color of the dye precursor, and is released by breaking the capsule. 2. The seismic impact force measuring system according to claim 1, wherein the seismic impact force received by the subject is measured based on the concentration of color produced by the reaction of the dye precursor with the developer.
The invention according to claim 3 is characterized in that the pressure-sensitive color developing body measures the earthquake impact force applied to the subject by the concentration of coloring of the dye or pigment developed by breaking the capsule. It is a force measurement system.
According to the invention of claim 4, the pressure-sensitive color former is arranged in such a manner that the capsule is classified according to the breaking strength, and the seismic impact force received by the subject is measured by the coloring coloration of the dye or pigment that is expressed by the breaking of the capsule. The seismic impact force measuring system according to claim 1.
According to the invention of claim 5, the pressure-sensitive color former is formed by arranging capsules encapsulating dyes or pigments having different hues according to breaking strengths according to breaking strengths, and depending on the coloring hues of the dyes or pigments developed by breaking the capsules. 2. The earthquake impact force measuring system according to claim 1, wherein the earthquake impact force received by the specimen is measured.
The invention of claim 6 is the seismic impact force measurement system according to any one of claims 1 to 5, wherein the impact force measurement site of the subject is the outer surface of the underground wall.
The invention according to claim 7 is the seismic impact force measuring system according to any one of claims 1 to 5, wherein the impact force measuring portion of the subject is an outer surface portion of the underground pile.
The invention according to claim 8 is the earthquake impact force measurement system according to any one of claims 1 to 5, wherein the impact force measurement site of the subject is the entire outer periphery of the underground pile. .
The invention according to claim 9 is a method for measuring an earthquake impact force that visualizes and measures an impact force that an object of an underground object receives due to an earthquake. Pressure sensitive color bodies formed by encapsulating in different types of capsules are arranged in a matrix form at the impact force measurement site of the subject, and the capsule is broken according to the seismic impact force received by the subject, and the dye Alternatively, when measuring the seismic impact force received by the subject depending on the color developed due to the release of the pigment , the pressure-sensitive color developing material is attached to a color developing material mounting plate, which is a long rigid member, and the color developing that the body mounting plate and to be able to carry it with a new sensitive pressure chromosome to be mounted in telescopically into a groove formed on a carrier provided in the impact force measurement site It is a method of measuring the seismic impact force to the butterfly.

According to the invention of claim 1 or 9 , when an earthquake occurs and the object of the underground object receives an impact, capsules having a breaking strength corresponding to the impact force are destroyed and released by breaking these capsules. Since the impact force of an earthquake can be measured according to the color development state of the dye or pigment, the measurement operation can be performed with a simple operation of just visually observing the pressure-sensitive color developing body.
Moreover, since the pressure-sensitive color developing body breaks the capsule according to the maximum impact force when the impact force becomes maximum, and the dye or pigment is released, the color development state of the dye or pigment is visually observed. Thus, the maximum value of the impact force can be known, and the maximum impact force received by the structure can be easily measured.
In addition, when a large earthquake occurs, it is often difficult to measure in real time, but the pressure-sensitive color developing body has little discoloration or fading over time, and even if there is provisional discoloration or fading. Since the dye or pigment once released from the capsule exhibits a color development state clearly different from that of the unreleased one, accurate measurement data can be obtained even if measurement is performed after the occurrence of an earthquake. Therefore, even if an accident such as a power failure occurs, there is no trouble that data is lost, and the impact force can be reliably measured.
And since impact force measurement can be performed only by providing a pressure-sensitive color developing body at the impact force measurement site, installation is simple, and a system for measuring impact force due to earthquake can be simplified. In addition, since the installation is simple, the measurement points can be provided over a wide range, and the seismic impact force can be measured more accurately.
Furthermore, according to the present invention, since a plurality of pressure-sensitive color formers are arranged on the subject in a matrix, it is possible to measure on the surface how the impact force of the earthquake has acted on the subject, and measure at a single point. Compared to the above, it is possible to accurately know the state of the earthquake impact received by the subject.
In other words, when measuring the impact force of an earthquake, accurate measurement values may not be obtained depending on the conditions such as topography and strata at the measurement point, and the impact force received may vary depending on the measurement site of the subject. Therefore, when only one earthquake impact force measurement point is used, there is a possibility that a correct measurement result cannot be obtained as a measurement of the impact force received by the entire subject. However, by arranging a plurality of pressure-sensitive color formers in a matrix, it is possible to measure the impact force of an earthquake two-dimensionally and three-dimensionally as the impact force received by the surface of the subject. Accurate earthquake impact force can be measured.
In addition, when the pressure-sensitive color former is taken out from the ground, the pressure-sensitive color former carried on the carrier may be taken out of the carrier, and there is no need to dig and take out the pressure-sensitive color former from the ground. can do.
According to the invention of claim 2, the pressure-sensitive color former is developed by reacting the dye precursor with the developer by receiving the impact of an earthquake and causing the dye to react with the color developer. Since the impact force of an earthquake is measured based on the concentration of the dye, discoloration and fading of the dye can be suppressed as compared with the case where the already colored dye or pigment is encapsulated.
According to the invention of claim 3, since it is not necessary to include a developer in the pressure-sensitive color former, it is possible to contribute to the reduction in the number of materials of the pressure-sensitive color former and the number of manufacturing steps.
According to the fourth aspect of the present invention, when measuring the impact force of an earthquake, it is only necessary to examine the colored section of the pressure-sensitive color former, so that the measurement can be performed easily and accurately.
According to the invention of claim 5, the impact force of an earthquake can be measured by examining the hue of the dye or pigment encapsulated in the capsule with the maximum breaking strength among the hues developed by the pressure-sensitive color former. Can be done easily and accurately.
According to the invention of claim 6, the earthquake impact force received by the subject having the underground wall can be measured two-dimensionally and three-dimensionally, and more accurate earthquake impact force can be measured.
By making it the invention of Claim 7, the impact force of the earthquake which the test object which has an underground pile receives can be measured two-dimensionally and three-dimensionally, and a more accurate earthquake impact force can be measured.
According to the eighth aspect of the present invention, it is possible to measure the seismic impact force from all directions that the subject receives, and to know from which direction the seismic impact force has propagated.

It is the schematic of a structure and a support | carrier. (A), (B) is the perspective view which shows a mode that the pressure sensitive color body was attached to the support | carrier, respectively, and the longitudinal cross-sectional view of a color body attachment plate. (A), (B), (C) is the principal part enlarged view and top view which respectively show embodiment of a pressure-sensitive color development body. It is a figure which shows the correlation of the stress which generate | occur | produces with the relative density | concentration of a pressure sensitive color body, and the impact force of an earthquake. 1 is a perspective view showing a first embodiment of the present invention, in which a pressure-sensitive color former is disposed on an underground wall that is a subject. FIG. A second embodiment of the present invention, Ru perspective view showing how the sensitive pressure chromosomal underground pile is subject disposed.

Hereinafter, embodiments of the present invention will be described with reference to the drawings.
As shown in FIG. 1, reference numeral 1 denotes a structure that is a subject, and the structure 1 has an underground wall 2 that is an underground buried object formed vertically in an underground portion. Then, on the outer wall surface side of the underground wall 2, the carrier 3, which is a long plate material, is underground so that a plurality of (seven in the present embodiment) are substantially equally spaced in the longitudinal direction. It is buried along the wall 2. The carrier 3 is formed of a hard member such as a thermosetting plastic or a stainless plate, for example, and as shown in FIG. A groove portion 3c reaching the portion 3b is formed. Then, on both the left and right side surfaces of the groove portion 3c, concave grooves 3d and 3e extending from the upper end portion 3a to the lower end portion 3b are formed to face each other.

  On the other hand, 4 is a color body mounting plate that is a long plate material that is slidably fitted in the groove 3c formed in the carrier 3, and is formed of a hard member such as a thermosetting plastic or a stainless steel plate, like the carrier 3. Has been. On the surface of the color former mounting plate 4, there are formed sticking portions 4a to which pressure sensitive color formers 5, which are square sheet bodies to be described later, are attached at substantially equal intervals in the vertical direction. Are formed with ridges 4b and 4c which are slidably fitted into the concave grooves 3d and 3e of the carrier 3, respectively. Then, the color body mounting plate 4 is detachably attached to the carrier 3 by slidingly fitting the protrusions 4b and 4c of the color body mounting plate 4 into the concave grooves 3d and 3e of the carrier 3. . As shown in FIG. 2B, the surface of the color body mounting plate 4 to which the pressure-sensitive color body 5 is adhered is uniformly coated with a coating 4d made of a soft resin material, etc. The pressure-sensitive color developing body 5 is prevented from falling off the color developing body mounting plate 4 or being altered by moisture in the ground.

  As shown in FIG. 3A, the pressure-sensitive color former 5 is applied to a base material 6, a developer layer 7 applied on the base material 6, and an upper side of the developer layer 7. The color former layer 8 is formed into a square sheet. The substrate 6 is plate-shaped, and is formed of, for example, paper, synthetic paper, plastic film or the like having a certain degree of hardness, and an adhesive 6a is provided on the back side (anti-developer layer side). After being applied, it is attached to the color body mounting plate 4 by the adhesive 6a.

  The color former layer 8 contains a large number of microcapsules 9 (corresponding to the capsule of the present invention) in which a dye precursor before color development is encapsulated. Examples of the dye precursor include leuco dyes. Is used. Examples of the leuco dye include triphenylmethane phthalide, fluorane, phenothiazine, phenoxidine, indolylphthalide, spiropyran, rhodamine lactam, diphenylmethane, triphenylmethane, and chromenoindole compounds. Or mixtures thereof. The color former layer 8 is blended with gum arabic, gelatin, starch particles or the like as a protective material for the microcapsules 9.

The microcapsule 9 is broken by receiving pressure and causes the dye precursor encapsulated in the microcapsule 9 to flow out. However, the breaking strength of the microcapsule 9 is not uniform and depends on various pressures generated by an earthquake. Thus, the color former layer 8 is formed in a state in which various materials having different breaking strengths are mixed. For example, external force generated by earthquakes (kN / cm ²⁾ is, when was 250 kN / cm ² from 5 kN / cm ^2, the microcapsules 9, compressive stress (kN / cm ²⁾ is broken at 5 kN / cm ² From what is to be broken at 250 kN / cm ² , for example, those having any different breaking strength such as 10 kN / cm ² or 50 kN / cm ² increments. The manufacture of such microcapsules 9 having different breaking strengths is already well known and will not be described, but the breaking strength can be adjusted by making the particle size and film thickness of the microcapsules 9 different. . Incidentally, as a resin for forming such a wall film, for example, a polyurea resin, a urea-formaldehyde resin, a melanin-formaldehyde resin, a saturated polyester, a polyurethane-based resin, an epoxy-based resin, a silicone-based resin, or the like is used.

  On the other hand, the developer layer 7 is a layer containing a developer that reacts with the dye precursor that flows out when the microcapsules 9 are broken, and develops color. Examples of the developer include: Activated clay, organic acid (phenolic resin, salicylic acid derivative metal salt) and the like are used.

The pressure-sensitive color developing body 5 configured as described above breaks the microcapsule 9 by receiving pressure, and develops a color by the reaction between the dye precursor flowing out of the microcapsule 9 and the developer. In this case, as described above, since the microcapsules 9 having different breaking strengths are mixed, the breaking amount of the microcapsules 9 increases or decreases depending on the pressure, that is, the pressure is increased. Accordingly, the amount of reaction between the dye precursor and the developer increases or decreases. Accordingly, the color density changes to light and dark based on the increase or decrease of the reaction amount, whereby the magnitude of the impact force of the earthquake received by the pressure-sensitive color former 5 can be visualized and measured.
The color density may be measured by visual observation, or may be quantitatively measured using a densitometer or the like.

  Here, as shown in FIG. 4, a calibration curve is prepared in advance by experiments as to the relationship between the relative color density of the pressure-sensitive color developing body 5 and the stress acting on the subject. Thereby, the magnitude of the stress (impact force) caused by the earthquake can be measured by the color density of the pressure-sensitive color developing body 5.

  In this embodiment, the pressure-sensitive color former 5 is colored by reacting with the developer when the dye precursor is encapsulated in the microcapsule 9 and the microcapsule 9 is destroyed by the impact force of the earthquake. However, the present invention is not limited to this, and as shown in FIG. 3B, a dye or pigment that has already developed color is enclosed in the microcapsule 9, and the microcapsule 9 is destroyed by the impact force of the earthquake. As a result, the dye or pigment may be expressed so that the pressure-sensitive color developing body 5 develops color. In such a configuration, the developer layer 7 is not necessary.

  Examples of the dye used in this case include xanthene, thiazine, phenylmethane, indigoid, azo, coumarin, azine, polymethine, cyanine, phthalocyanine, anthraquinone, pyrazoline, stilbene. And quinoline-based compounds and mixtures thereof, and examples of pigments include carbon black, red lead, iron oxide red, yellow lead, zinc yellow, ultramarine blue, ferrocyanide Inorganic pigments such as potash, or organic pigments such as azo, phthalocyanine, indigoid, and anthraquinone can be used.

  In this case, the wall film of the microcapsule 9 is white and opaque, so that the color of the encapsulated dye or pigment does not pass through before the microcapsule 9 is destroyed, and the microcapsule 9 before the destruction. In the state where the microcapsules 9 after destruction are mixed, the color of the dye or pigment released from the destroyed microcapsules 9 is clearly revealed. Such white opaque microcapsules 9 can be formed using, for example, polyurea resin, urea-formaldehyde resin, melanin-formaldehyde resin, saturated polyester, polyurethane-based, epoxy-based, silicone-based, or the like.

  Alternatively, as shown in FIG. 3 (C), the pressure-sensitive color developing body 5 is configured such that a microcapsule 9 in which a dye or pigment is encapsulated is provided with a capsule layer 10 that is arranged according to breaking strength. May be. With this configuration, when the pressure-sensitive color developing body 5 is subjected to an earthquake impact, only the microcapsule 9 having a breaking strength weaker than the impact force is broken, so that the microcapsule 9 is enclosed. Therefore, when measuring the impact force, it is only necessary to visually observe the expression category of the expressed dye or pigment. By configuring in this way, the impact force of an earthquake can be simplified. And it can measure accurately.

  Further, the microcapsules 9 arranged in the capsule layer 10 according to the breaking strength may be configured by encapsulating dyes or pigments having different hues depending on the breaking strength. In this case, when the pressure-sensitive color former 5 receives an impact of an earthquake, only the microcapsule 9 having a breaking strength weaker than the impact force is broken, and the dye or pigment enclosed in the microcapsule 9 appears. Since the developed dye or pigment has a different hue depending on the breaking strength of the microcapsule 9, the impact force of the earthquake can be measured by examining the hue developed in the pressure-sensitive color developing body 5.

  As shown in FIG. 5, the carrier 3 to which the pressure-sensitive color forming body 5 configured as described above is attached is arranged along the underground wall 2 that is the outer surface portion of the basement of the structure 1 so that the longitudinal direction is vertically changed. In this state, a plurality of burials are embedded at equal intervals in the horizontal direction. At this time, the pressure-sensitive color formers 5 provided on the respective carriers 3 adjacent to each other in the horizontal direction and the vertical direction are arranged at equal intervals. By arranging the carrier 3 in this way, the pressure-sensitive color formers 5 are arranged in a matrix form at equal intervals in the vertical and horizontal directions on the underground wall 2. In the present embodiment, the carrier 3 is embedded in all four surfaces of the underground wall 2 so that the impact force caused by the earthquake can be measured from any direction, but it is disposed only on one surface. Of course, it is also good. In this case, if only one surface of the underground wall 2 is observed, the vertical and horizontal states of the impact force received by the earthquake can be known two-dimensionally. In this case, the state of the impact force received by the earthquake can be known three-dimensionally, and detailed measurement of the impact force that has been difficult to observe until now, such as the direction of impact and the state of propagation, can be performed.

  In the present embodiment configured as described, in measuring the impact force of the earthquake received by the underground wall 2 of the structure 1, first, the color body mounting plate 4 to which the pressure-sensitive color body 5 is attached is attached to the carrier 3. After the slide fitting, the plurality of carriers 3 are embedded in parallel along the outer wall surface portion of the underground wall 2 so that the longitudinal direction is up and down. Here, the carriers 3 are provided on the carrier 3. The pressure-sensitive color formers are arranged and embedded so as to form a matrix with substantially equal intervals in the horizontal and vertical directions. After the occurrence of the earthquake, the coloring body mounting plate 4 is removed from the carrier 3, and the color density of the pressure sensitive coloring body 5 attached to the coloring body mounting plate 4 is determined visually or by a densitometer or the like to impact the earthquake. After the measurement is completed, a new pressure-sensitive color developing body 5 is again attached to the attaching portion 4a of the color developing body attaching plate 4, and then the color developing body attaching plate 4 is attached to the carrier 3. The pressure-sensitive color body 5 is buried in the basement by re-supporting the carrier 3 by sliding fitting, and the impact force of the earthquake is subsequently measured.

  Here, in the pressure-sensitive color former 5, the dye precursor before color development is encapsulated in a plurality of types of microcapsules 9 having different breaking strengths, and the microcapsules 9 are destroyed according to the impact force caused by the earthquake, thereby the dye precursor. The pressure-sensitive color former 5 develops color with a color density corresponding to the impact force caused by the earthquake, and the color density is visually or visually determined by a color densitometer. By quantifying, the impact force at the position where the pressure-sensitive color developing body is embedded can be measured.

  Therefore, in measuring the earthquake impact force, the impact force is visualized and measured, and the earthquake impact force can be easily measured. Moreover, since no special device or knowledge is required for measurement, it is possible to provide a seismic impact force measurement system with excellent versatility.

  In addition, the seismic impact force measuring system according to the present embodiment is such that the color of the dye or pigment is less faded over time, and the dye or pigment once released from the capsule even if there is provisional discoloration or fading Since the pigment is in a color state that is clearly different from that of the unreleased pigment, accurate measurement data can be obtained even in the measurement after the occurrence of an earthquake. In other words, even if an accident such as a power outage occurs, there is no trouble that data is lost. For this reason, the pressure-sensitive color developing body 5 is taken out from the ground after the earthquake or aftershock has been cured. This means that the impact force can be reliably measured and the measurement can be performed while ensuring safety.

  Moreover, since the pressure-sensitive color developing body 5 is such that when the impact force becomes maximum, the capsule is broken according to the maximum impact force, and the dye or pigment is released. The maximum impact force received by the structure can be measured.

  In addition, since the pressure-sensitive color developing body 5 is a sheet body, it can be easily attached and detached and can be easily replaced. Moreover, since the place to stick is not chosen, measurement in a wide range becomes possible, and an accurate measurement result can be obtained by increasing the number of measurement points.

  Then, by arranging the pressure-sensitive color bodies 5 embedded in this manner in at least a two-dimensional matrix, when measuring the earthquake impact force, as in the case where the measurement point is one point or several points, the topography Problems such as inaccurate measurement values cannot be obtained due to special conditions such as the geological formation, or the impact force received by the entire subject cannot be measured correctly by measuring only a specific part of the subject. Therefore, it is possible to comprehensively measure in what state the impact force applied to the subject works.

  In the first embodiment described above, the carrier 3 is embedded along the underground wall 2 of the structure 1, and the impact force from all directions in the underground wall 2 is measured. As in the second embodiment shown in FIG. 6, the subject can be implemented as the underground pile 11. In this case, the pressure-sensitive color-developing body 5 is arranged in a matrix in the circumferential direction and the vertical direction by burying the pressure-sensitive color developing body 5 along the circumference of the underground pile 11, but when there are a plurality of underground piles 11 The pressure-sensitive color bodies 5 may be arranged in a matrix along the outer peripheral surfaces 11a of all of the plurality or a plurality of selected underground piles 11.

  By embedding the carrier 3 as a whole around the underground pile 11 in this way, when measuring the impact force of the earthquake, not only the impact force received in the vertical direction in the underground object is measured, but also the circumferential direction It is possible to measure the impact force received in the three-dimensional matrix form. Furthermore, it is possible to perform a three-dimensional matrix measurement for each of the plurality of underground piles 11, and as a result, the direction, magnitude, distribution, and propagation of the seismic impact force in a state where the measurement area is three-dimensionally widened. It is possible to know the state and the like in more detail.

When embedding the pressure-sensitive color developing body 5 in the ground, only the color body mounting plate 4 may be embedded in the ground, and the color body mounting plate 4 may be pulled out from the ground at the time of measurement. and, chromogenic mounting plate 4 but it may also be attached to the carrier 3 directly basement walls 2 or underground pile 11 fitted slide.

  INDUSTRIAL APPLICABILITY The present invention can be used in the field of impact force measurement by an earthquake that measures the impact force received by underground buried objects such as underground walls and underground piles due to the occurrence of an earthquake.

DESCRIPTION OF SYMBOLS 1 Structure 2 Basement wall 5 Pressure sensitive color body 9 Microcapsule 11 Underground pile

Claims (9)

An earthquake impact force measurement system that visualizes and measures the impact force that an object in an underground object is subjected to by an earthquake, wherein the earthquake impact force measurement system is used for a plurality of types of capsules in which dyes or pigments have different fracture strengths. A plurality of pressure-sensitive color bodies formed by being enclosed are arranged in a matrix form at the impact force measurement site of the subject, and the capsule is broken and the dye or pigment is released according to the seismic impact force received by the subject. In measuring the seismic impact force received by the subject depending on the state of color development, the pressure-sensitive color former is attached to a color body attachment plate which is a long rigid member, and the color body attachment plate is it is characterized in that as that mounted telescopically in a groove formed on a carrier provided in the impact force measurement site a new sensitive pressure chromosome can be supported Measurement system of earthquake shock force.   The pressure-sensitive color former contains a color developer that reacts with the dye precursor to cause the dye precursor to develop color, and the dye precursor that is released when the capsule is broken is the color developer. The seismic impact force measuring system according to claim 1, wherein the seismic impact force received by the subject is measured based on the density of the color developed by reacting with.   2. The seismic impact force measuring system according to claim 1, wherein the pressure-sensitive color former measures the seismic impact force received by the subject according to the color density of the dye or pigment developed by breaking the capsule.   The pressure-sensitive color former is characterized in that the capsule is divided and arranged according to the breaking strength, and the seismic impact force received by the subject is measured according to the coloring coloration of the dye or pigment expressed by the breaking of the capsule. The measuring system of seismic impact force according to 1.   The pressure-sensitive color former consists of capsules filled with dyes or pigments with different hues according to the breaking strength, arranged according to the breaking strength, and the seismic impact force received by the subject due to the coloring hues of the dyes or pigments that develop due to the breaking of the capsules. The earthquake impact force measuring system according to claim 1, wherein:   The seismic impact force measuring system according to any one of claims 1 to 5, wherein the impact force measuring portion of the subject is an outer surface portion of the underground wall.   The earthquake impact force measurement system according to any one of claims 1 to 5, wherein the impact force measurement site of the subject is an outer surface portion of an underground pile.   The earthquake impact force measurement system according to any one of claims 1 to 5, wherein the impact force measurement site of the subject is the entire outer surface of the underground pile. An earthquake impact force measurement method for visualizing and measuring an impact force that an object of an underground object receives due to an earthquake, the method for measuring an earthquake impact force comprising dyes or pigments in a plurality of types of capsules having different fracture strengths A plurality of pressure-sensitive color bodies formed by encapsulating are arranged in a matrix form at the impact force measurement site of the subject, and the capsule is broken and the dye or pigment is released according to the seismic impact force received by the subject. In measuring the seismic impact force received by the subject according to the color development state, the pressure-sensitive color former is attached to a color body attachment plate that is a long rigid member, and the color former attachment plate is attached to the impact force. earthquake shock, characterized in that the by the attachment to telescopically into a groove formed on a carrier provided in the measurement site new sensitive pressure chromosome to be able to be supported Method of measurement.

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