JP4722107B2 - Creep test apparatus and creep test method - Google Patents

Description

  The present invention relates to a creep test apparatus and a creep test method for performing a creep test on a pressure vessel (boiler piping) used in a high temperature and high pressure state.

  In order to improve the reliability of high-temperature steam piping (boiler piping) used in thermal power plants and reduce repair costs, etc., an accurate remaining piping life is diagnosed and appropriate based on this diagnosis. It is necessary to replace and replenish parts at the right time. For this reason, conventionally, a creep test apparatus for performing a creep test for boiler piping used in a thermal power plant is known.

  In a normal creep test, boiler piping (test body) used in boilers, etc. is assumed. After heating the test body to a predetermined temperature, water is injected into this test body to generate water vapor. Then, pressure is applied to the inside of the test body, then a predetermined load is applied to the center of the test body, and a bending force is applied to the test body by a predetermined load load. Diagnose the creep phenomenon targeting the region by image analysis.

  As a prior art related to this type of creep test apparatus, Patent Document 1 discloses a high temperature creep as a reliability evaluation test of creep rupture strength carried out on a pressure vessel used at a high temperature and a high pressure, for example, a pressure vessel constituting a boiler. An internal pressure burst test or the like is known (see, for example, Patent Document 1).

  In this test, a creep test is performed in a high temperature state in which an internal pressure is applied, using a pressure vessel of an almost actual size as a test body. That is, a cylindrical pressure vessel of almost actual size is subjected to internal pressure, heated by providing a heating device on the outer periphery, maintained for a long time under the test conditions of a predetermined temperature and pressure, and periodically during the test period. Non-destructive tests such as dye penetration testing, magnetic particle testing, ultrasonic testing, and surface replica collection are performed.

  Here, various external forces are applied to the pressure vessel constituting the boiler during high temperature and high pressure, and stress due to the external force is generated. Therefore, it is necessary to newly evaluate the reliability by external force. As this type of high-pressure internal bending creep test apparatus, Patent Document 2 discloses a creep test apparatus in which a bending stress condition is added in addition to temperature and pressure. In this high-pressure internal bending creep test apparatus, a test body is supported by a pair of support columns, and a load load device is disposed in the center, and a creep test is performed by three-point bending in which a load is loaded by the load load device. .

JP 2001-108589 A Japanese Patent No. 3855199

  However, according to the three-point bending creep test apparatus disclosed in Patent Document 2 as the above-described prior art, in the case of this three-point bending creep test apparatus, the two ends of the specimen are supported at the center of the specimen. Since this is a method of applying a load, there arises a problem that the data of the central part of the specimen cannot be collected.

  Specifically, since the spacer of the load loading device is arranged at the center of the test body, high stress / strain is locally generated in the load loading section, thereby causing deformation such as flatness in the test body. Therefore, there is a problem that measurement data such as a displacement and a load value necessary for the creep test cannot be collected accurately. In addition, since the load application part (spacer) is in contact with the pipe, there is a problem that the measurement data of the central part of the specimen cannot be collected over the entire circumference of the pipe. For this reason, a creep test apparatus capable of accurately performing displacement and each measurement data due to a bending load applied to the test body by the load application apparatus is desired.

  Accordingly, the present invention has been made to solve the above-described problems of the prior art, and is not affected by the angular displacement due to the bending load in the creep test for performing the reliability evaluation for the pressure vessel. An object of the present invention is to provide a creep test apparatus and a creep test method.

In order to solve the above-described problems and achieve the object, the present invention horizontally supports both end portions of a test body arranged in a longitudinal direction by a pair of support pillars, In a creep test apparatus that performs a creep test of a test specimen by applying a predetermined load by a load application apparatus in a high temperature state, the load application apparatus is arranged on the first side in the longitudinal direction of the test specimen. A load load device, a second load load device disposed on the other side in the longitudinal direction of the specimen, and a first measuring means for measuring a first load applied by the first load load device; A second measuring means for measuring a second load applied by the second load load device, and a first intermediate member for each of the first load load device and the second load device. Arc-shaped concave surface connected in a fixed manner A second displacement block member having an arc-shaped convex surface portion fixedly connected via a second intermediate member to each of one side and the other side in the longitudinal direction of the test body. A displacement block member, the first displacement block member and the second displacement block member are assembled so as to be in sliding contact with each other, and the first load load device and the second load load device A slide support device for supporting an equilibrium state with respect to the test body; and a recording device for recording displacement, strain and test conditions of the test body; and the second displacement block member of the slide support device includes the test body. In accordance with the inclination, the first displacement block member is inclined while sliding .

Further, the present invention horizontally supports both ends of a test body arranged in the longitudinal direction by a pair of support pillars, and applies a predetermined load to the test body by a load load device during a predetermined high temperature state. A creep test method applied to a creep test apparatus that applies a load and performs a creep test of the test body, and applies a predetermined load by a first load load device disposed on one side in the longitudinal direction of the test body. A first load loading step, a second load loading step of applying a predetermined load by a second load loading device arranged on the other side in the longitudinal direction of the specimen, and a load by the first load loading device. A first measurement step for measuring the first load to be performed; a second measurement step for measuring a second load applied by the second load load device; the first load load device; For each of the second load devices A first displacement block member having an arcuate concave surface portion fixedly connected via one intermediate member, and a second intermediate member on each of one side and the other side in the longitudinal direction of the specimen. A second displacement block member having an arc-shaped convex surface portion fixedly connected to each other via the first displacement block member and the second displacement block member so as to be in sliding contact with each other. In the slide support device which is assembled and supports an equilibrium state with respect to the test body by the first load load device and the second load load device, the second displacement block member is moved along the inclination of the test body. And a displacement step that inclines while slidingly contacting one displacement block member .

  According to the present invention, the test body is horizontally supported at both ends by a pair of support pillars, and the creep test apparatus includes a load load device that applies a predetermined load to the test body. Since the first load application device disposed on one side in the longitudinal direction of the test body and the second load load device disposed on the other side in the longitudinal direction of the test body are provided, the test body is supported from both sides. A creep test by four-point bending using a pair of support pillars and a pair of load application devices can be performed. There is an effect that the test data can be collected over the entire piping of the test body.

Further, according to the present invention, the creep test apparatus includes a load load apparatus that applies a predetermined load to the test body, and the load load apparatus is a first load load apparatus disposed on one side of the test body. A second load applying device disposed on the other side of the test body, a first measuring means for measuring a first load applied by the first load applying device, and a second load applying device. Since it comprises a second measuring means for measuring the second load to be applied and a recording device for recording the displacement, strain and test conditions of the specimen, a creep test by four-point bending using a pair of load-loading devices As a result, measurement data for the periphery of the central part of the specimen can be accurately collected.

Further, according to the present invention, the creep test apparatus includes a pair of load load devices disposed on both ends in the longitudinal direction of the test body and a slide support device, so that four points using the pair of load load devices are provided. A creep test by bending can be performed, and thus measurement data for the periphery of the central portion of the specimen can be accurately collected. In addition, the slide support device is configured by assembling the second displacement block member that tilts following the displacement of the specimen and the first displacement block member that follows the second displacement block member. The angular displacement due to the bending load can be absorbed, whereby the equilibrium state by the load application device can always be maintained.

According to the present invention, the first displacement block member constituting the slide support device has an arc-shaped concave surface portion, and the second displacement member has an arc-shaped convex surface portion, Since the concave surface portion provided on the first displacement block member and the convex surface portion provided on the second displacement block member are assembled so as to be in sliding contact with each other according to the transition direction of the test body, The angular displacement generated by the bending load can be effectively absorbed.

Further, according to the present invention, a predetermined load is applied to one side in the longitudinal direction of the specimen by the first load application process, and a predetermined load is applied to the other side of the specimen by the second load application process. The first load applied by the first load application device is measured in the first measurement process, the second load applied by the second load application device is measured in the second measurement process, The second displacement block member constituting the slide support device is tilted following the displacement of the test body by the first displacement step, and the first displacement block member is displaced by the second displacement step by the second displacement step. Therefore, the angular displacement due to the bending load can be absorbed by the first displacement step and the second displacement step by the slide bearing device, and thereby the equilibrium state by the load loading device can always be maintained. .

  Exemplary embodiments of a creep test apparatus 1 according to the present invention will be described below in detail with reference to the accompanying drawings. Here, FIG. 1 is a front view illustrating the entire configuration of the creep test apparatus 1 according to the first embodiment, and FIG. 2 is a side view illustrating the entire configuration of the creep test apparatus 1. FIG. 3 is a diagram showing a state of execution of a creep test by the creep test apparatus 1 shown in FIGS. 1 and 2. 1 and 2 show only the creep test apparatus 1, the creep test apparatus 1 includes an electric furnace for heating the test specimen P, and water supply for injecting water into the test specimen P. The control apparatus which controls the operation | movement of the apparatus and the creep test apparatus 1 whole will be attached. Further, the present invention is not limited to the first embodiment shown below.

[Overview and configuration of creep test apparatus 1]
As shown in FIG. 1 and FIG. 2, the creep test apparatus 1 includes a pair of support columns 2 and 3 erected in the vertical direction, and a fixed beam 4 fixed to the upper ends of the pair of support columns 2 and 3. It is configured as a structure made of steel or the like. In addition, a joining column portion 5 is provided at a substantially central portion of the pair of support columns 2 and 3, and a pair of support frames for supporting the lower end surface of the test body P is provided between the pair of support columns 2 and 3. 6 is disposed. The support frame 6 is formed in a rectangular shape (FIG. 2), and a support 7 for mounting the test body P is fixedly provided at substantially the center of the upper surface of the support frame 6.

  The support 7 is formed in a conical column shape having a smaller diameter toward the tip side, and an inner end surface 8 of the support 7 is formed in an arc shape in accordance with the shape (cylindrical shape) of the test body P. A cylindrical seat 9 that is also formed in an arc shape and that can freely come into contact with the outer peripheral surface of the test body P is fixed to the end surface 8. As shown in the figure, the test body P is placed with the outer peripheral surface of the test body P in contact with the arc surface of the cylindrical seat 9. A water supply pipe for a water supply device (not shown) for injecting water into the test body P is connected to one end of the test body P.

  As shown in the figure, the specimen P used in the creep test apparatus 1 configured as described above is a cylindrical pressure vessel (long) provided with an appropriate welded joint (not shown) for testing. Shaped cylindrical member). In addition, this test body P shall have the shape and dimension (size, for example, diameter of 500 mm or more) substantially the same as an actual boiler piping in order to simulate the high-heat steam piping for boilers of a thermal power plant.

  In addition, a pair of load application devices 10 for applying a predetermined load to the test body P are provided at predetermined positions (two locations in FIGS. 1 and 2) of the fixed beam 4. These load loading devices 10 are configured by assembling a connecting beam 40 having a screw jack 20, a load cell 30, and a guide roller 41, an intermediate spacer 50, and a spacer 70 from the top of FIG. A slide support device 60 is fitted between the intermediate spacer 50 and the spacer 70.

  FIG. 3 is a diagram illustrating a state in which a creep test is performed by the creep test apparatus 1. Specifically, FIG. 3 is a diagram showing a state in which a load is applied to two positions of the test specimen P by a pair of load application devices 10 constituting the creep test device 1. As will be described later, even when the central portion of the test specimen P is bent and the entire test specimen P is inclined, the intermediate spacer 50 can maintain the horizontal state.

  Here, in the creep test apparatus 1 according to the first embodiment, the load loading devices 10 are respectively arranged on one side and the other side in the longitudinal direction of the test body P supported horizontally by the pair of columns 2 and 3. The pair of load load devices 10 is characterized in that a creep test is performed by applying a predetermined load to the test specimen P.

  That is, as shown in the figure, the fixed shaft 21 fixed to the upper end portion of the screw jack 20 (FIG. 2) is fixed in a state of being fitted into the through hole 4 a of the fixed beam 4. Further, the lower end portion of the screw jack 20 is fixed to both end portions of the upper surface of the load cell 30. A predetermined load can be applied to the test specimen P by the screw jack 20. Here, the load controlled by the control device (not shown) is selected as the load amount by the screw jack 20. The load applied by the screw jack 20 transmits a driving force from a driving motor (not shown) through a gear box according to a control instruction from the control device.

  The load cell 30 (load transducer) has a cylindrical cylindrical shape, and is configured by attaching and fixing a strain gauge to an elastic member such as a strain generating body (for example, an aluminum alloy). The screw jack 20 which comprises the load application apparatus 10 is respectively attached and fixed to the both ends part side of a part. When the load loading device 10 arranged on both sides of the test body P is operated, a predetermined load is applied to both ends of the test body P, and the loaded load value is measured by the load cell 30.

  The load cell 30 functions as a transducer that converts a load applied by the screw jack 20 into an electrical signal. Load data (numerical values) measured by the load cell 30 are input to a control device (not shown). When the load cell 30 measures that the predetermined load has been reached, the control device transmits a stop signal from the screw jack 20 to the load loading device 10. The load cell 30 is fixedly attached to the connecting beam 40 by a load cell mounting plate (not shown).

  The connecting beam 40 is provided for connecting the two load devices 10. The connecting beam 40 includes a plurality of (two in FIG. 2) guide rollers 41 disposed at positions spaced from each other, and the connecting beam 40 includes a plurality of so-called super-heavy moving plural rollers. It functions as a chill roller having an endless roller (caterpillar roller). Specifically, the load by the screw jack 20 is supported by surface contact by the two guide rollers 41 (the pair of guide rollers 41 rotates), and the load loading device 10 is prevented from being inclined, so that A function for adjusting the load acting on the spacer 50 side to be always vertical is provided. Specifically, the movement of the intermediate spacer 50 can always be in the vertical direction.

  In addition, by inhibiting the load loading device 10 from being tilted by the connecting beam 40, an uneven load on the load cell 30 can be prevented, and thereby the measurement by the load cell 30 can be performed accurately. That is, even when the test body P is inclined, the horizontal positions of the load application device 10 and the intermediate spacer 50 can be maintained.

  In addition, a long guide roller support member 43 is attached and fixed to the outer surface portion of the connecting beam 40, and the end portions 42 of these guide roller support members 43 are fixedly attached to the pair of columns 2 and 3. ing. Thereby, even when an angular displacement occurs due to a bending load, the horizontal position of the intermediate spacer 50 can be maintained.

  The intermediate spacer 50 is composed of a substantially rectangular box member, a function of adjusting the distance from the center of the connection beam 40 to the spacer 70, an electric furnace (not shown) installed on the connection beam 40 and the test body P, and the like. It has the function to secure the distance. Further, the intermediate spacer 50 is provided with a cooling air port of a cooling device (not shown) for cooling the load application device 10.

  The slide support device 60 is fitted between the intermediate spacer 50 and the spacer 70, and is a load-loading device even when the specimen 70 mainly moves due to thermal expansion and the spacer 70 moves and when angular displacement due to bending load occurs. 10 is capable of transmitting a vertical force to 10, and thus has a function of constantly maintaining the equilibrium state of the load device 10. Since the slide support device 60 is a characteristic part of the first embodiment, details will be described later.

  The spacer 70 has a substantially circular arc surface (convex surface seat: for example, “SUS304” is used as the material) on the lower side of the main body portion. Here, since the test body P is heated to about 650 ° C. to 700 ° C., the spacer 70 is attached to the test body P with a stopper and a mounting bolt (not shown) in order to prevent displacement. It is fixed. Here, the positions of the cores of the spacer 70 and the load loading device 10 are shifted during the thermal expansion of the test specimen P. In order to prevent this, the spacer 70 and the load loading apparatus 10 are previously cooled when the test specimen P is cold. The positions of the cores are adjusted to a slightly shifted position (when the test body P is thermally expanded, the positions of the cores of the spacer 70 and the load application device 10 are matched).

[Configuration of Slide Bearing Device 60]
Next, details of the configuration of the slide support device 60 will be described with reference to FIGS. Here, FIG. 4 is an enlarged view of part A of FIG. 1 and shows the overall configuration of the slide support device 60. FIG. 5 is a diagram showing a front view, a top view, and a side view of the slide support block 61 constituting the slide support device 60. FIG. 6 is a view showing a front view, a top view, and a side view of a cylindrical block 63 that also constitutes the slide support device 60.

  As shown in FIGS. 4 to 6, the slide support device 60 includes an arc concave surface 62 formed in an arc shape and a flat portion 62 a, and a slide support block 61 in which a main body portion 61 a is formed in a substantially rectangular shape. The main body portion 63a includes a cylindrical block 63 that has an arc convex surface 64 and a flat portion 65 (FIG. 6) that are also formed in an arc shape. The cylindrical block 63 and the spacer 70 are fixed by fitting the flat portion 65 of the cylindrical block 63 to the spacer 70 and welding.

  In Example 1, the radius of curvature of the arc concave surface 62 is set to a predetermined dimension (for example, about 300R). Actually, the radius of curvature of the arc concave surface 62 depends on the dimension (cylindrical diameter) of the specimen P. At the appropriate time, the dimensions are selected.

  As shown in the figure, the arc concave surface 62 of the slide support block 61 and the arc convex surface 64 of the cylindrical block 63 are abuttable with each other and are formed so as to be assembled. 62 and the arcuate convex surface 64 of the cylindrical block 63 are assembled together to constitute the slide support device 60.

[Operational effect of slide support device 60]
Next, with reference to FIG. 3, FIG. 7-1, and FIG. 7-2, the effect with respect to the load application apparatus 10 by the slide support apparatus 60 is demonstrated. FIG. 7A is an enlarged view of a portion A in FIG. 3, and FIG. 7-2 is an enlarged view of the portion B in FIG.

  First, A part (left end part of the test body P) of FIG. 3 is demonstrated. That is, when the center part of the test body P is bent by the operation of the pair of load devices 10, the left side of the test body P is inclined toward the center part side (inside) as shown in FIG. The cylindrical block 63 fixed to the spacer 70 constituting the support device 60 is also inclined in the clockwise direction (arrow α side) as the test body P is inclined. The arc-shaped concave surface 62 of the slide support block 61 positioned is inclined in the counterclockwise direction (arrow β side) while being in sliding contact with the arc-shaped convex surface 64 of the cylindrical block 63. Thereby, the angular displacement of the test body P is canceled by the sliding contact of the slide support block 61 and the cylindrical block 63 in the opposite directions, and at the same time, the flat surface 62a of the cylindrical block 63 slides, thereby causing the slide support. The left intermediate spacer 50 located at the top of the device 60 can maintain an equilibrium state without tilting.

  Next, the B part (right end part of the test body P) of FIG. 3 is demonstrated. That is, when the center part of the test body P is bent by the operation of the pair of load devices 10, the right side of the test body P is inclined toward the center part side (inside) as shown in FIG. The cylindrical block 63 fixed to the spacer 70 constituting the support device 60 is also inclined in the counterclockwise direction (arrow β side) as the test body P is inclined. The arcuate concave surface 62 of the slide support block 61 located at the position tilts in the clockwise direction (arrow α side) while being in sliding contact with the arcuate convex surface 64 of the cylindrical block 63. Thereby, the angular displacement of the test body P is canceled by the sliding contact of the slide support block 61 and the cylindrical block 63 in the opposite directions, and at the same time, the flat surface 62a of the cylindrical block 63 slides, thereby causing the slide support. The right intermediate spacer 50 located at the top of the device 60 can maintain an equilibrium state without tilting. As described above, since the pair of intermediate spacers 50 can maintain an equilibrium without being tilted by the slide support device 60, it is possible to prevent an eccentric load from being applied to the load load device 10. Thus, an accurate load can be measured by the load measuring device (load cell 30).

  Next, referring to the overall configuration diagram of the creep test apparatus 1 ′ not including the slide support apparatus 60 shown in FIG. 8 and FIGS. 9-1 and 9-2, the slide support mechanism ( A creep test apparatus 1 'not provided with the slide support apparatus 60) will be described. Here, FIG. 9-1 shows an enlarged view of the A ′ portion of FIG. 8, and FIG. 9-2 shows an enlarged view of the B ′ portion of FIG.

  First, the A ′ portion (left end portion of the test specimen P) in FIG. 8 will be described. That is, when the center part of the test body P is bent by the operation of the pair of load devices 10, the load support block 60a located on the upper portion of the spacer 70 is formed by the α of the test body P as shown in FIG. With the inclination in the direction, it is inclined in the clockwise direction (arrow α side). As a result, the intermediate spacer 50 disposed on the upper portion of the load bearing block 60a is similarly inclined in the α direction.

  Similarly, as shown in FIG. 8B ′ (the right end of the test specimen P), when the test specimen P is bent toward the center, as shown in FIG. The load bearing block 60a located at is inclined in the counterclockwise direction (arrow β side) as the specimen P is inclined in the β direction. As a result, the intermediate spacer 50 disposed on the upper portion of the load bearing block 60a is similarly inclined in the β direction. As described above, unlike the creep test apparatus 1 of the first embodiment, in the case of the creep test apparatus 1 ′ that does not include the slide support device 60, the pair of intermediate spacers 50 are also located at the center side like the specimen P. Since the intermediate spacer 50 cannot be kept horizontal due to the inclination of the test body P, the intermediate spacer 50 is swung from side to side due to the inclination of the specimen P. As a result, the load measuring device (load cell 30) is not moved. The problem arises that an eccentric load acts and an accurate load cannot be measured.

[Evaluation experiment using creep test equipment]
Next, the creep test apparatus 1 having the slide support mechanism (slide support apparatus 60) shown in the first embodiment and the creep test apparatus not having the slide support mechanism (slide support apparatus 60) shown in FIG. The evaluation experiment result by 1 'is demonstrated.

  FIG. 10A is a diagram showing a comparison result of displacement in the Y direction (perpendicular to the specimen P), and a solid line among them indicates measurement data obtained by the creep test apparatus 1 ′ that does not include the slide support device 60. The dotted lines represent measurement data obtained by the creep test apparatus 1 including the slide support device 60, respectively. As shown in the figure, when comparing an example of both displacements, in the creep test apparatus 1 (displacement is 15.4 mm) provided with the slide support apparatus 60, the creep test apparatus 1 'not provided with the slide support apparatus 60 is shown. It can be seen that the displacement is less than (displacement is 16.7 mm).

10-2 is a diagram showing a comparison result of stresses in the Z direction (cylindrical axis direction of the test specimen P). Like FIG. 10-1, a solid line indicates a creep test in which the slide support device 60 is not provided. In the measurement data obtained by the apparatus 1 ′, the dotted lines represent the measurement data obtained by the creep test apparatus 1 including the slide support device 60. As shown in the figure, when one example of both stresses is compared, the creep test apparatus 1 (stress is 21.8 kg / mm ² ) provided with the slide support device 60 does not include the slide support device 60. It can be seen that the stress is less than that of the apparatus 1 ′ (stress is 22.9 kg / mm ² ).

  As described above, in the present invention, the creep test apparatus 1 includes the pair of load application devices 10 disposed on both ends in the longitudinal direction of the test body P and the slide support device 60. A creep test by four-point bending using the apparatus 10 can be performed, and thereby measurement data for the periphery of the central portion of the specimen P can be accurately collected. Further, since the slide support device 60 is constructed by assembling the slide support block 61 and the cylindrical block 63 that follow the displacement direction of the test body P and incline in the opposite directions, the angular displacement due to the bending load is detected by the slide support device. 60, so that an equilibrium state by the load application device 10 can always be maintained. In this embodiment, the load load device shows two-point four-point bending, but two or more load load devices can also be provided.

  As described above, the creep test apparatus and the creep test method according to the present invention relate to a creep test apparatus and a creep test method for performing a creep test on a pressure vessel (boiler piping), and in particular, a four-point bending creep test. It is suitable for a creep test apparatus and a creep test method capable of performing the above.

1 is a front view showing an overall configuration of a creep test apparatus according to Example 1. FIG. 1 is a side view showing an overall configuration of a creep test apparatus according to Example 1. FIG. It is a figure which shows the implementation condition of the creep test by the creep test apparatus shown in FIG. FIG. 4 is an enlarged view of a portion A in FIG. 3. It is a figure which shows the front view of a slide support block, a top view, and a side view, respectively. It is a figure which shows the front view of a cylindrical block, a top view, and a side view, respectively. It is an enlarged view of the A section of FIG. It is an enlarged view of the B section of FIG. It is the figure which implemented the creep test by the creep test apparatus which does not employ | adopt a slide support apparatus. It is an enlarged view of the A 'part of FIG. It is an enlarged view of the B 'part of FIG. It is a figure which shows the evaluation experiment result by a creep test apparatus. It is a figure which shows the evaluation experiment result by a creep test apparatus.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1, 1 'Creep test apparatus 10 Load loading apparatus 20 Screw jack 30 Load cell 40 Connection beam 41 Guide roller 50 Intermediate spacer 60 Slide support apparatus 61 Slide support block 63 Cylindrical block 70 Spacer

Claims (2)

Both ends of the test body arranged in the longitudinal direction are horizontally supported by a pair of support columns, and a predetermined load is applied to the test body by a load load device during a predetermined high temperature state. In a creep test apparatus for performing a creep test of
The load applying device is:
A first load application device arranged on one side in the longitudinal direction of the test specimen; a second load application device arranged on the other side in the longitudinal direction of the test specimen;
First measuring means for measuring a first load applied by the first load applying device;
Second measuring means for measuring a second load applied by the second load applying device;
A first displacement block member having an arcuate concave surface portion fixedly connected to each of the first load loading device and the second load device via a first intermediate member; and the test body A second displacement block member having an arc-shaped convex surface portion fixedly connected to each of one side and the other side in the longitudinal direction via a second intermediate member. A slide support device for assembling the displacement block member and the second displacement block member so as to be in slidable contact with each other, and supporting an equilibrium state with respect to the specimen by the first load load device and the second load load device; ,
A recording device for recording the displacement, strain and test conditions of the specimen,
The second displacement block member of the slide support device is:
A creep test apparatus that tilts while slidingly contacting the first displacement block member as the test body is tilted . Both ends of the test body arranged in the longitudinal direction are horizontally supported by a pair of support columns, and a predetermined load is applied to the test body by a load load device during a predetermined high temperature state. A creep test method applied to a creep test apparatus for performing a creep test of
A first load application step of applying a predetermined load by a first load application device arranged on one side in the longitudinal direction of the specimen;
A second load application step of applying a predetermined load by a second load application device arranged on the other side in the longitudinal direction of the specimen;
A first measurement step of measuring a first load applied by the first load application device;
A second measuring step for measuring a second load applied by the second load applying device;
A first displacement block member having an arcuate concave surface portion fixedly connected to each of the first load loading device and the second load device via a first intermediate member; and the test body A second displacement block member having an arc-shaped convex surface portion fixedly connected to each of one side and the other side in the longitudinal direction via a second intermediate member. In a slide bearing device, wherein a displacement block member and the second displacement block member are assembled so as to be in sliding contact with each other, and an equilibrium state with respect to the specimen is supported by the first load loading device and the second load loading device. A creep test method comprising: a displacement step in which the second displacement block member tilts while slidingly contacting the first displacement block member as the test body is inclined .

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