JP2000065704A - Creep tester - Google Patents

Abstract

PROBLEM TO BE SOLVED: To prevent the addition of an impact to a tester by providing a load lever buffer mechanism to the side end part of a wt. mounting part. SOLUTION: A feed screw 36 is rotated by a weight driving motor 42 to move a weight driving motor 42 to move a weight 10 to the moving original point in the vicinity of a fulcrum 25 and a test piece A is fixed to a chuck 13 in such a state that load is near to zero. Next, only by gradually moving the weight 10 in the side end part direction of a wt. mounting part along the rail of a load lever to move the same to the position generating predetermined stress in the test piece A, the predetermined arrangement of a tensile creep tester is completed. At this time, since the load applied to the test piece A increases smoothly and steplessly accompanied by the movement of the weight 10, it is prevented that impactive load is applied in the setting of load as is conventional to exert adverse effect on the test piece and an accurate test result is obtained. Further, constant stress can be easily applied to the fine irregularity of the cross-sectional area of the test piece.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a creep tester.

[0002]

2. Description of the Related Art In a conventional creep testing machine, a test piece is mounted below a fulcrum on one side of a load lever around a fulcrum, and a weight with a slot is suspended at an end far from the fulcrum on the other side. Then, to measure the deformation of the test piece elongation, compression, bending, etc., in order to apply a certain stress to the test piece,
For example, 100 kg, 50 kg, 10 kg, 5 kg, 1 kg
Kg, 0.5 kg, 0.1 kg, 0.05 kg, 0.0
Weights such as 1 kg, 0.005 kg, and 0.001 kg had to be appropriately selected, individually lifted and detached.

[0003]

Therefore, in the conventional creep testing machine, the weights of the weights suspended at the end of the load lever on the side of the action point are changed by manually lifting up and removing the weights individually. In order to apply a load required to apply a predetermined stress to the test piece, there is a problem that not only there is a fear of giving an impact to the test piece at the time of attachment / detachment, but also there is a problem that a great deal of time and labor is required. In some cases, the weight of the stake can reach hundreds of kilograms, which poses a problem in that the work is very dangerous.

[0004]

Accordingly, the present invention provides a creep for measuring the deformation of a test piece by mounting a test piece below one side of a load lever around a fulcrum and adding a weight to the other side. A creep testing machine characterized in that the weight is movably mounted along the longitudinal direction on the other side of the load lever in the testing machine. In addition, as a creep test machine according to the present invention,
The present invention is not limited to the tensile creep tester described in the illustrated embodiment, but includes other creep testers for compression, bending, and the like.

[0005] By moving the weight along the longitudinal direction of the load lever, the load applied to the test piece can be set in a stepless manner, so that the load can be accurately set in accordance with the cross-sectional area of the test piece. The stress can be easily set to a desired value, and even if the cross-sectional areas of a plurality of test pieces vary, the stress can be kept constant. The results are obtained, and the load can be easily controlled automatically in accordance with the cross-sectional area during the test. Therefore, there is an effect that a creep test with constant stress can be realized for the first time. In addition, since a single weight is moved along the longitudinal direction of the load lever to vary the load applied to the test piece, not only can labor and time be reduced, but also the risk is minimized. There is an effect that can be.

Further, in the present invention, a rail for moving a weight is formed at a weight mounting portion of the load lever, so that the weight moves smoothly.
It provides a creep test machine as described. The present invention also provides a creep tester according to claim 1 or 2, wherein a conveyor mechanism for moving a weight is provided in a weight mounting portion of the load lever, and the conveyor is moved smoothly by the conveyor mechanism. Is what you do.

Further, according to the present invention, the conveyor mechanism comprises a feed screw conveyor provided along the longitudinal direction of the load lever, and the weight can be moved by rotating the feed screw. A creep tester according to claim 3 is provided. With the feed screw conveyor, the weight can be moved with high precision, and the stop screw can be stopped and the weight can be stopped to set the position accurately.The screw shaft is screwed into the weight. The weight can be prevented from falling due to an earthquake or the like.

Further, according to the present invention, since the weight moving mechanism is provided so as to be movable by a driving device such as a driving motor or an actuator, the movement of the weight is controlled by the driving device to minimize the load setting labor. 5. A creep test with a constant stress, wherein the load can be easily controlled by weight movement control corresponding to a change in the cross-sectional area of the test piece during the test. And a creep tester described in (1).

Further, according to the present invention, since the driving device is provided at one side end of the load lever on which the test piece is mounted, the weight mounting portion can be freely provided regardless of the type of the driving device. 6. A weight as a counterweight, wherein the weight acts as a counterweight.
And a creep tester described in (1). Also,
The present invention provides a displacement meter for measuring the displacement of a test piece, comprising a displacement portion provided on a force point of a load lever for pulling the test piece and a detection portion provided on a support member for supporting the fulcrum of the load lever. A creep tester according to any one of claims 1 to 6, wherein the creep tester is configured to directly and accurately detect deformation of a test piece.

Further, according to the present invention, a counterweight is provided at one side end of the load lever to maintain the balance of the load lever on which the weight is mounted. A creep tester according to any one of the above. Also, the present invention provides a balance weight at one side end of the load lever,
The creep tester according to any one of claims 1 to 8, wherein the weight driving mechanism is maintained in balance. Further, the present invention is characterized in that, at a side end portion of the weight mounting portion, a lever buffer mechanism for supporting a load lever when a test piece is broken is provided so as not to give an impact to a creep test machine. A creep tester according to any one of claims 1 to 9 is provided.

The present invention also provides a creep tester for measuring a deformation of a test piece by mounting a test piece below one side of a load lever around a fulcrum and adding a weight to the other side. Provided is a creep test machine characterized by providing a lever buffer mechanism that supports a load lever when a test piece breaks at a side end of a mounting portion so as not to give an impact to the creep test machine. is there.

Conventionally, when a test piece breaks, the weight suspended from the end of the load lever at the point of action will fall sharply onto the machine base of the testing machine. However, as described above, the total amount of weight may vary depending on the case. Since the impact can reach several hundred kilograms, when it falls, it impacts other test specimens, and if multiple tests are performed simultaneously in parallel, the effect is not negligible. The present invention provides an accurate and safe configuration by providing a lever buffer mechanism for supporting a load lever when a test piece breaks at a side end of a weight mounting portion so as not to give an impact to a creep tester. A creep tester is provided. Although it is extremely difficult to support the weight near the fulcrum of the load lever, in the present invention, the test piece broke due to the provision of the lever buffer mechanism at the side end of the weight mounting portion far away from the fulcrum. In this case, the falling force applied to the load lever can be supported with a minimum force.

Further, according to the present invention, a lever buffer table is provided in the lever buffer mechanism, and a gap is provided between the lever buffer table and a side end of the weight mounting portion. Without affecting the load lever at all.
The creep testing machine according to claim 10 or 11, wherein the load lever is immediately supported at a small gap falling distance when the test piece breaks, and no impact is generated. Further, according to the present invention, since the lever shock absorber has an up-and-down movement mechanism, a gap provided between a side end of a weight mounting portion and the lever shock absorber can be variably set. And a creep tester described in (1).

Further, the present invention provides a proximity sensor and a detection signal of the proximity sensor in order to always keep a gap provided between a side end of the weight mounting portion and the lever shock absorber at a substantially constant interval. The creep testing machine according to any one of claims 10 to 13, wherein a driving device is provided for controlling the vertical movement of the lever buffer base in response to the vertical movement of the test piece in accordance with the length and deformation of the test piece. Is provided. Further, the present invention provides the creep tester according to any one of claims 10 to 14, wherein a shock absorbing member is provided on the lever shock absorber so that an impact at the time of cutting the test piece can be minimized. Things. Also,
The present invention provides a creep tester according to any one of claims 1 to 16, further comprising a thermostat for accommodating a test piece.

The creep testing machine according to any one of claims 1 to 16, wherein a plurality of said load levers are provided in parallel so that a plurality of creep tests can be performed simultaneously. Is provided. The creep test machine according to any one of claims 1 to 17, wherein a plurality of test pieces are accommodated in the constant temperature bath so that a plurality of creep tests can be performed at the same time. Is provided.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described based on embodiments with reference to the drawings. FIG. 1 is a schematic front view showing an embodiment of the creep tester of the present invention, FIG. 2 is a schematic side view thereof, and FIG. 4 is a side cross-sectional view of a lever damping mechanism, which is another main part, and FIG. 5 is a schematic front cross-sectional view showing a main part of the present embodiment in a partially longitudinal manner.

In the case of the embodiment, the creep tester of the present invention
A thermostatic chamber 1 having a test piece mounting part, a load lever 2 for swinging about a fulcrum 25 to pull the test piece at a power point 26 and mounting a weight on a long rod portion on the opposite side, a weight driving part 4, and a lever A buffer mechanism 5 is provided. The thermostat 1 is located on the lower front side, and the thermostat 1 is located behind the thermostat 1.
A stirring fan motor 11 for keeping the inside of the chamber at a constant temperature via a heater is provided. In the case of the embodiment, as shown in FIG.
In the thermostat 1, a plurality of test chambers 12 are provided in parallel so that a plurality of test pieces A can be tested at the same time.
3 is a test piece observation window, 17 is an operation panel, and 18 is a record display window.

As shown in FIG. 3, chucks 13 are provided at the upper and lower sides of the test chamber 12 so that both ends of the test piece A can be chucked according to the standard and pulled vertically. It is. The lower chuck 13 is firmly fixed to the testing machine stand, while the upper chuck 13 is integrated with a chuck member 21 that penetrates above the thermostatic chamber 1 and extends to and near the load lever 2. Is attached. Although not shown in the drawing, a cross-sectional observation device for the test piece A is provided to automatically detect the cross-sectional area of the test piece that changes every moment during the creep test, and to apply a load corresponding to the changing cross-sectional area. A constant stress test can be made possible.

The chuck member 21 loosely penetrates the chuck guide 15 provided at the front end of the fulcrum support base 14 provided integrally with the body, and the upper end thereof has a force point 26 of the load lever 2.
Are fixed integrally to a chuck member mounting portion 28 of a coupling 27 provided rotatably around the center. In the case of the embodiment, the load lever 2 is composed of two rails 22 provided in parallel at a fixed interval as shown in the center of FIG.
In the position, the coupling 27 is provided rotatably by bearings between the rails 22 so as to be orthogonal to the rails, so that the coupling 27 is rotatable about the force point 26. Accordingly, when the load lever 2 is inclined around the fulcrum 25 due to the deformation of the test piece A, the linearity of the chuck member 21 is maintained.

On the coupling 27, a displacement shaft 34 is vertically provided integrally and vertically with the chuck member 21, and a displacement portion integral with the displacement shaft 34 is provided in the electronic displacement meter 24. It is configured so that the deformation generated in the test piece A can be accurately measured by moving. The displacement meter 24 is integrally supported by a fixing member 34 on a support frame 8 provided on a column 7 erected integrally with the fulcrum support base 14 along the chuck member 21. The fulcrum 25 for swingably supporting the load lever 2 composed of the two rails 22 is horizontally mounted on the fulcrum support bases 14 on both outer sides of the two rails 22 as partially shown in FIG. Two rails 22 are provided on the fulcrum shaft 16 via the bearing 9.
Is rotatably supported. That is, when a plurality of the load levers 2 according to the present invention are provided in parallel, the rails 22 constituting the adjacent load levers 2 are horizontally provided in such a manner that the rails 22 constituting the load levers 2 are stretched over the fulcrum support bases 14 erected therebetween. The fulcrum shaft 16 is configured to be supported on both sides. Accordingly, at the position of the fulcrum 25, the two rails 22 constituting the load lever 2 are supported on the fulcrum shaft 16 outside thereof, and the fulcrum shaft 16 does not exist between the rails. .

The two rails 22 are firmly integrated as load levers 2 at both ends and the like, and support points 25 are provided.
The weight mounting portion 30 is formed in two rails on the opposite side of the power point 25 with the center as the center, and the weight 10 according to the present invention is movably guided. In the case of the embodiment, the weight 10 is formed of a rectangular parallelepiped having a thickness capable of loosely passing between the two rails 22 via the guide gap, and the center of gravity passes on a line connecting the fulcrum 25 and the force point 26. It is movably provided by four upper and lower four pairs of wheels 33. In the case of the embodiment, the wheel 33 is formed of a wheel with a flange like a wheel of a railway track, and the flange is fitted into the guide gap, so that the weight 10 moves smoothly without sideways or the like. I have.

A feed screw 36 is rotatably provided at the center of the two rails 22 of the load lever 2 so that the axis passes along a line connecting the fulcrum 25 and the force point 26. The feed screw 36 is connected to the bearing 23 at the rear end of the rail 22 and the power point 26.
The bearing 27 is rotatably supported between a bearing 31 provided on the rail 22 near the distal end of the coupling 27.
The rotating shaft portion 46 on the distal end portion side is connected to a motor shaft 48 of a drive motor 42 provided at the distal end portion of the load lever 2 via a flywheel-shaped shaft coupling 45. The rotary shaft 46 between the shaft coupling 45 and the bearing 31 is provided with an encoder 47 for detecting the rotation speed of the feed screw 36. The rotation shaft 39 of the feed screw 36 penetrating through the coupling 27 portion of the force point 26 has the load lever 2 inclined between the rotation shaft 39 and the through hole 29 provided in the coupling 27 as shown in FIGS. Needless to say, spaces are provided so as not to contact each other.

The weight 10 is provided with a through hole 32 passing through the center of gravity.
Female screw members 37 and 38 that are rotatably screwed to 6 are detachably and integrally fixed and provided, and the weight 10 moves on the rail 22 as the feed screw 36 rotates. . Since the female screw members 37 and 38 rotatably screwed to the feed screw 36 are detachably provided,
There is no need to provide a female screw through the weight, and the weight can be easily attached to and detached from the load lever 2. In the present invention, the conveyor mechanism that controls the rail transport of the weight 10 is configured to include a belt conveyor that can move the weight by rotating a belt, in addition to the feed screw conveyor mechanism in the above embodiment. In addition, the conveyor mechanism may be constituted by an endless annular transfer member having a weight fixed in the middle, and the weight may be moved by rotating the transfer member.

In addition, as the driving device 4 for the conveyor mechanism, the weight 10 can be provided so as to be able to control the movement of the weight 10 by a driving device such as a hydraulic actuator in addition to the driving motor. Proximity sensors including limit switches 19 and 20 are provided near the starting point and the ending point near the fulcrum 25 of the load lever 2 so as to regulate the moving range of the weight 10. A counterweight 40 is provided on the load lever 2 between the drive motor 42 and the power point 26, and the balance of the load lever 2 when the weight 10 is moved to the movement origin near the fulcrum is measured to obtain the balance before the test. The test piece A is configured not to give an extra force. Also, the counterweight 40 is provided so as to be adjustable in position, and the weight 10
And the load lever 2 may be configured to be in the equilibrium stable state at the origin of movement of the weight 10.

A balance weight 41 is provided on the motor mounting plate 43 of the drive motor 42 so as to correct the imbalance of the load around the axis of the load lever 2 due to the load of the drive motor 42. . In addition, the present invention relates to the side end portion 44 of the weight mounting portion 30.
Further, a lever buffer mechanism 5 for supporting the load lever 2 when the test piece A is broken is provided so as not to give an impact to the creep tester. The configuration of the lever buffer mechanism 5 is common to all creep testing machines that mount a test piece on one side of a load lever around a fulcrum and add a weight to the other side to measure the deformation of the test piece. It can be implemented.

The lever buffer mechanism 5 includes a lever buffer table 5
1 and the lever buffer 51 and the weight mounting portion 3
A gap 49 is provided between the side edge portion 44 and the zero side end portion 44. In the creep test, the deformation from the start of deformation of the test piece A to the cutting can be predicted. Therefore, the lever buffer 51 is attached to the weight mounting portion 30 through a gap corresponding to the length of the deformation to be measured in the test. By providing the side end portion 44, the lever buffer 51 can hold the test piece A at a close distance from the test piece A being cut and the weight mounting portion 30 going to drop downward. Also,
The present invention is characterized in that a shock-absorbing member 52 is provided on the lever shock-absorbing table 51 to minimize the impact.
In addition, the present invention provides the lever buffer 51 with a vertical movement mechanism 50.
Is provided. Thereby, not only can the gap 49 provided between the side end portion 44 of the weight mounting portion 30 and the lever buffer table 51 be appropriately adjusted according to the deformation of the test piece A, but also the creep test can be performed. The gap 49 can be maintained at a substantially constant interval corresponding to the deformation of the test piece A in the middle.

The lever buffer 51 is provided with a coil spring between a base 61 and a receiving base 62 at a U-shaped bottom piece.
The buffer member 52 made of rubber, synthetic resin, or the like is provided, and the upright pieces on both sides guide the end of the rail 22. A rack member 63 is provided integrally below the center of the base 61, and the rack member 63 is provided so as to be vertically movable by a guide member 53 integrally fixed to the apparatus body. The rack member 63 is engaged with a pinion member that is driven to rotate by the vertical drive motor 55 in the guide member 53. Guide rollers 54 for vertically moving the rack member 63 are provided above and below the guide member 53. A switch contact portion 57 is provided near the lower end of the rack member 63, and is provided with limit switches 58, 5 provided on the body.
9, the upper and lower limit positions of the lever shock absorber 51 are regulated. The vertical movement mechanism of the lever buffer 51 is not limited to the rack and pinion mechanism of the embodiment. For example, the rack member 63 includes a screw shaft having an upper end rotatably mounted on the base 61, and a screw shaft. It is needless to say that a conventionally known structure such as a screw mechanism or the like that can be moved up and down by a rotating nut member or the like provided on the body can be used.

In this embodiment, the up-down movement mechanism 50 provided on the lever buffer 51 allows the gap 49 to be maintained at a substantially constant interval corresponding to the deformation of the test piece A during the creep test. A gap sensor composed of a proximity switch 60 and the like is provided between the weight 51 and the weight mounting section 30, and the test piece A is deformed during the creep test, and the gap 49 is formed.
When the is narrowed, the gap sensor is activated so that the vertical drive motor 55 is driven to lower the lever buffer table 51 so that the gap 49 does not disappear, and the lever buffer table 51 and the weight mounting unit 30 come into contact with each other to perform measurement. In addition to preventing the influence from being exerted, even when the test piece is cut at any time, a constant gap 49 is maintained so that no impact is applied to the entire apparatus. In this embodiment, between the lower side of the side end of the weight mounting portion 30 and the upper end of the lever buffer 51, always 1-2
mm. Reference numeral 56 denotes a U-shaped upright piece of the lever buffer 51, which guides the end of the rail 22 therebetween. Reference numeral 64 denotes a cover body of the lever buffer mechanism 5.

In the embodiment of the present invention, as shown in FIG. 1 or FIG. 5, a plurality of load levers 2 are provided in parallel so that a plurality of creep tests can be performed simultaneously. And In this case, a plurality of creep tests can be performed simultaneously under the same temperature condition by using a configuration in which a plurality of test pieces A are accommodated in parallel in the constant temperature bath 1. In FIG. 5, in the six sets of devices capable of performing the creep test, in order from left to right, the first position of the drive motor 42, the second position of the counterweight 40, and the third position 26, the fourth and fifth are the positions of the fulcrum shaft 16, and the sixth is an explanatory diagram for explaining the configuration at the position of the lever buffer mechanism at the side end of the weight mounting portion.

In the configuration of the above embodiment, the feed screw 36 is rotated by the weight drive motor 42 to move the weight 10 to the origin of movement in the vicinity of the fulcrum 25.
Is fixed to the chuck 13 in a state close to zero load. Next, only by moving the weight 10 gradually along the rail 22 of the load lever 2 toward the side end of the weight mounting portion 30 to generate a predetermined stress on the test piece A,
The predetermined installation of the tensile creep test will be completed. At this time, the load applied to the test piece A is the weight 10
Since it gradually increases in a stepless manner with the movement of the test piece, it is possible for the load to be applied in a stepwise manner when setting the load, as in the past, which could adversely affect the test specimen. And accurate test results are obtained. In addition, by applying a load steplessly, a constant stress can be easily applied to subtle variations in the cross-sectional area of the test piece.

When a change in the cross-sectional area of the test piece is detected by the device for observing the cross-sectional area of the test piece during the creep test, the weight 10 is moved along the rail in response to the change. A creep test at a constant stress can be realized. At this time, in the tester of the embodiment of the present invention, when the test piece is deformed, the chuck member 21 is vertically displaced upward, and the load lever 22 is tilted downward at the side end of the weight mounting portion 30. However, at this time, if the side end of the weight mounting portion 30 contacts the lever buffer table 51 beyond the buffer gap 49, the creep test cannot be performed accurately thereafter. Therefore, in the embodiment of the present invention, first, in order to always keep the buffer gap 49 between the lower part of the side end of the weight mounting part 30 and the upper end of the proximity sensor 60 provided above the lever buffer base 51 at a constant interval, The lever buffer 51 is configured to be able to move up and down. In this embodiment, a gap of 1 to 2 mm is always provided between the lower side of the weight mounting portion 30 and the upper end of the lever buffer 51. In the present embodiment, the vertical movement mechanism 50 uses the rack and pinion mechanism to move the lever buffer 51 that moves up and down based on the gap detection signal of the proximity sensor 60 to the vertical drive motor 55.
Drives the pinion to control the movement of the
Is displaced downward so that a buffer gap 49 between the lower side of the side end of the weight mounting portion 30 and the upper end of the lever buffer 51 is always kept at a constant interval.

When the elongation limit of the test piece A is reached, the test piece A breaks. In the conventional creep tester, when the test piece A breaks, the weight mounting portion 30 of the load lever 2 is largely inclined downward, but in the present invention, in this case, the buffer gap 49 is used.
The side end portion of the weight illuminating portion 30 is received and supported via the member, so that the generation of a large force on the weight mounting portion 30 can be suppressed. Therefore, when a plurality of creep tests can be performed at the same time as in the embodiment of the present invention, for example, a creep test is performed under the same load using test pieces of different materials, respectively, or the same material is used. It is possible to perform a creep test under different loads using the same specimen, and even if another creep test is performed simultaneously, the creep test will not adversely affect the test of the other specimen by cutting the specimen. The test can be performed.

[0033]

As described above, according to the creep tester according to the present invention, the test piece is mounted below one side of the load lever around the fulcrum, and the weight is added to the other side, and In the creep tester for measuring the deformation, the weight is moved along the longitudinal direction of the load lever by having a configuration in which the weight is movably mounted along the longitudinal direction on the other side of the load lever. Since the load applied to the test piece can be set in a stepless manner, the load can be accurately set according to the cross-sectional area of the test piece, so that the stress can be easily set to a desired value. In addition to the fact that the stress can be kept constant even if there are variations in the cross-sectional area of multiple test specimens, the effect of preventing variations in measured values and obtaining accurate test results Ri, further, since the load during the test by moving control weights can easily be automatically controlled in accordance with the change in cross-sectional area, there is an effect that can be achieved for the first time the creep tests stress constant. In addition, since a single weight is moved along the longitudinal direction of the load lever to vary the load applied to the test piece, not only the labor and time can be reduced, but also the danger when setting the load. Has an effect that can be minimized.

Further, in the present invention, a rail for moving a weight is formed in a weight mounting portion of the load lever, so that the weight moves smoothly.
With the configuration of the creep tester described, there is an effect that the heavy weight can be smoothly moved by the rail. 3. The creep testing machine according to claim 1, wherein a weight moving portion of the load lever is provided with a conveyor mechanism for moving the weight, and the conveyor is moved smoothly by the conveyor mechanism. Has an effect that a heavy weight can be smoothly moved by the conveyor mechanism.

Further, in the present invention, the conveyor mechanism includes a feed screw conveyor provided along the longitudinal direction of the load lever, and the weight can be moved by rotating the feed screw. The creep tester according to the third aspect of the present invention has the effect that the weight can be moved with high precision by the feed screw conveyor, and the feed screw can be stopped only by stopping the feed screw and stopping the weight. There is an effect that the position can be accurately set and set, and since the screw shaft is screwed into the weight, the weight can be prevented from dropping from the load lever due to an earthquake or the like. Further, according to the present invention, the weight moving mechanism is driven by having the configuration of the creep tester according to claim 3 or 4, wherein the weight moving mechanism is provided so as to be able to move by a driving device such as a driving motor or an actuator. It can be controlled by the device to minimize the load setting labor, and the load can be easily controlled by the weight movement control corresponding to the change in the cross-sectional area of the test piece during the test. There are effects such as realization.

Further, according to the present invention, there is provided a creep testing machine according to claim 5, wherein the driving device is provided at one side end on which the test piece of the load lever is mounted.
There is an effect that the weight mounting portion can be freely provided irrespective of the form of the driving device, and also an effect that the weight acts as a counterweight. Further, the present invention provides a displacement meter for measuring the displacement of the test piece, a displacement portion provided on a force point of a load lever for pulling the test piece, and a detection portion provided on a support member for supporting the fulcrum of the load lever. With the configuration of the creep testing machine according to any one of claims 1 to 6, there is an effect that the deformation of the test piece can be directly detected with high precision on the point of force.

The present invention is further characterized in that a counterweight is provided at one side end of the load lever so as to maintain the balance of the load lever on which the weight is mounted. Has the effect of realizing a zero load on the weight mounted on the load lever when a test piece is mounted or the like. Further, according to the present invention, a balance weight is provided at one side end of the load lever so as to maintain the balance of the weight drive mechanism.
Since the creep tester according to any one of the above aspects is configured, an offset load around the axis of the load lever by the weight drive mechanism can be offset to maintain the balance.

Further, in the present invention, a lever buffer mechanism for supporting a load lever when a test piece breaks is provided at a side end of the weight mounting portion so as not to give an impact to a creep tester. The creep tester according to any one of claims 1 to 9, wherein the weight suspended from the end of the load lever at the point of action of the load lever is conventionally used when the test piece breaks. Although it will fall suddenly on the table, the total weight may reach several hundred kilograms in some cases, so when falling,
In addition, when the impact is applied to the test piece being tested and a plurality of tests are performed simultaneously in parallel, the effect cannot be ignored, but the present invention is provided at the side end of the weight mounting portion. Since the lever buffer mechanism can support the load lever at a short distance when the test piece breaks, it has the effect of not giving an impact to the creep test machine, and the effect of providing an accurate and safe creep test machine. There is. Although it is extremely difficult to support the weight near the fulcrum of the load lever, the present invention provides the lever buffer mechanism at the side end of the weight mounting portion far away from the fulcrum,
There is an effect that the drop force applied to the load lever when the test piece breaks can be supported with a minimum force.

The present invention also provides a creep tester for measuring a deformation of a test piece by mounting a test piece below one side of a load lever around a fulcrum and adding a weight to the other side. The creep tester is characterized in that a lever buffer mechanism is provided at the side end of the mounting portion to support the load lever when the test piece breaks, so that no impact is applied to the creep tester. is there. Further, according to the present invention, in the lever shock absorbing mechanism, a lever shock absorbing stand is provided via a gap between the lever damping mechanism and a side end of the weight mounting portion, wherein the creep testing machine according to claim 10 or 11 is provided. Has the effects that the lever shock absorber does not have any adverse effect on the load lever being measured, and the load lever is immediately supported by a small gap drop distance when the test piece breaks, so that no impact is generated.

Further, according to the present invention, since the lever shock absorber is provided with a vertical movement mechanism, the gap provided between the side end of the weight mounting portion and the lever shock absorber can be variably set. According to the configuration of the creep tester according to claim 12, a buffer gap provided between a side end of the weight mounting portion and the lever buffer table is appropriately adjusted in accordance with deformation of the test piece. In addition to this, there is an effect that the impact gap can be maintained at a substantially constant interval corresponding to the deformation of the test piece during the creep test.

Further, the present invention provides a proximity sensor and a detection signal of the proximity sensor so that a buffer gap provided between a side end portion of the weight mounting portion and the lever buffer table is always kept at a substantially constant interval. A drive device for controlling the vertical movement of the lever buffer table in accordance with the length of the test piece, and automatically moves up and down in accordance with the length and deformation of the test piece.
By having the configuration of the creep tester according to any one of the above, the impact gap can be maintained at a substantially constant interval in response to the deformation of the test piece during the creep test, so that the test piece breaks at an unexpected position. Even if this is done, the load lever can be held by a close fall and the creep test can be performed without causing any adverse effects on other test pieces and without impact on the entire test machine. Have.

The creep testing machine according to any one of claims 10 to 14, wherein a shock absorbing member is provided on the lever shock absorbing stand so that an impact at the time of cutting the test piece can be minimized. Has an effect that the impact due to the fracture of the test piece can be reduced. In addition, the present invention has a creep tester according to any one of claims 1 to 16, characterized in that a thermostat for accommodating a test piece is provided.
The test piece can be tested at a predetermined temperature in a thermostat.

The creep testing machine according to any one of claims 1 to 16, wherein a plurality of said load levers are provided in parallel so that a plurality of creep tests can be performed simultaneously. By having the configuration of
Since multiple creep tests can be performed at the same time, for example, creep tests can be performed with the same load using test pieces of different materials, or different loads can be performed using test pieces of the same material. Has the effect that a creep test can be performed. The creep test machine according to any one of claims 1 to 17, wherein a plurality of test pieces are accommodated in the constant temperature bath so that a plurality of creep tests can be performed at the same time. Has the effect that a plurality of test pieces can be simultaneously subjected to creep tests under the same temperature conditions.

[Brief description of the drawings]

FIG. 1 is a schematic front view of an embodiment of a creep tester of the present invention.

FIG. 2 is a schematic side view of the embodiment of FIG.

FIG. 3 is a schematic enlarged side view showing a main part of the embodiment of FIG.

FIG. 4 is a schematic enlarged side view showing another main part of the embodiment of FIG.

FIG. 5 is a schematic enlarged vertical sectional front view showing the six load levers of the embodiment shown in FIG.

[Explanation of symbols]

 REFERENCE SIGNS LIST 1 constant temperature bath 2 load lever 3 test specimen observation window 4 weight drive unit 5 lever buffer mechanism 6 coupling support shaft 7 support column 8 support frame 9 bearing unit 10 weight 11 stirring fan motor 12 test chamber 13 chuck 14 fulcrum support base 15 chuck Guide unit 16 Support shaft 17 Operation panel unit 18 Record display unit 19, 20 Limit switch 21 Chuck member 22 Rail 23 Bearing unit 24 Displacement meter 25 Support point 26 Force point 27 Coupling 28 Chuck member mounting unit 29 Through hole 30 Weight mounting unit 31 Bearing unit REFERENCE SIGNS LIST 32 through hole 33 wheel 34 displacement shaft 35 guide measuring unit 36 feed screw 37, 38 female screw member 39 rotation shaft 40 counterweight 41 balance weight 42 drive motor 43 motor mounting plate 44 side end 45 shaft coupling 46 rotation shaft 47 Encoder 4 Motor shaft 49 Buffer gap 50 Vertical movement mechanism 51 Lever buffer 52 Buffer member 53 Guide member 54 Guide roller 55 Vertical drive motor 56 Upright piece 57 Switch contact section 58, 59 Limit switch 60 Proximity switch 61 Base 62 Receiver 63 Rack member 64 Cover body

[Procedure amendment]

[Submission date] June 10, 1999 (1999.6.1
0)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Full text

[Correction method] Change

[Correction contents]

[Document Name] Statement

[Title of the Invention] Creep testing machine

[Claims]

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a creep tester.

[0002]

2. Description of the Related Art In a conventional creep testing machine, a test piece is mounted below a fulcrum on one side of a load lever around a fulcrum, and a weight with a slot is suspended at an end far from the fulcrum on the other side. Then, to measure the deformation of the test piece elongation, compression, bending, etc., in order to apply a certain stress to the test piece,
For example, 100 kg, 50 kg, 10 kg, 5 kg, 1 kg
Kg, 0.5 kg, 0.1 kg, 0.05 kg, 0.0
Weights such as 1 kg, 0.005 kg, and 0.001 kg had to be appropriately selected, individually lifted and detached.

[0003]

Therefore, in the conventional creep testing machine, the weights of the weights suspended at the end of the load lever on the side of the action point are changed by manually lifting up and removing the weights individually. In order to apply a load required to apply a predetermined stress to the test piece, there is a problem that not only there is a fear of giving an impact to the test piece at the time of attachment / detachment, but also there is a problem that a great deal of time and labor is required. In some cases, the weight of the stake can reach hundreds of kilograms, which poses a problem in that the work is very dangerous.

[0004]

Accordingly, the present invention provides a creep for measuring the deformation of a test piece by mounting a test piece below one side of a load lever around a fulcrum and adding a weight to the other side. In the test machine, a load lever buffer mechanism for supporting the load lever when the test piece breaks is provided at the side end of the weight mounting portion for mounting the weight on the other side of the load lever, and an impact is applied to the creep test machine. The present invention provides a creep test machine characterized in that the creep test machine is configured so as not to have any creep test.

Conventionally, when a test piece breaks, the weight suspended from the end of the load lever at the point of action falls sharply onto the machine base of the testing machine. However, as described above, the total amount of weight may vary depending on the case. Since the impact can reach several hundred kilograms, when it falls, it impacts other test specimens, and if multiple tests are performed simultaneously in parallel, the effect is not negligible. The present invention provides a load lever buffer mechanism at the side end of the weight mounting portion for supporting the load lever when the test piece breaks, and is configured not to give an impact to the creep test machine, so that accurate and safe A simple creep tester is provided. Although it is extremely difficult to support the weight near the fulcrum of the load lever, the present invention breaks the test piece by providing the load lever buffer mechanism at the side end of the weight mounting part far away from the fulcrum. In this case, the falling force applied to the load lever can be supported with a minimum force.

Further, the present invention provides a load lever shock absorber provided in the load lever shock absorber mechanism, and a gap provided between the load lever shock absorber and a side end of the weight mounting portion. 2. The creep test according to claim 1, wherein the load lever has no adverse effect on the load lever being measured, and the load lever is immediately supported at a small gap drop distance when the test piece breaks, so that no impact occurs. Machine. Further, according to the present invention, the load lever shock absorber has an up-and-down movement mechanism, so that the gap provided between the side end of the weight mounting portion and the load lever shock absorber can be variably set. Item 4. A creep tester according to item 2.

Further, the present invention provides a proximity sensor and a detection signal of the proximity sensor so as to keep a gap provided between a side end of the weight mounting portion and the load lever shock absorber at a substantially constant interval. 4. A creep according to claim 1, further comprising a drive device for controlling the vertical movement of the load lever shock absorber according to the length of the test piece, and automatically moving the test piece in accordance with the length and deformation of the test piece. A testing machine is provided. Further, the present invention provides the creep tester according to any one of claims 1 to 4, wherein a shock-absorbing member is provided on the load lever shock-absorbing table so that an impact at the time of cutting the test piece can be minimized. Is what you do.

The present invention also relates to a creep tester for measuring a deformation of a test piece by mounting a test piece below one side of the load lever around a fulcrum and adding a weight to the other side. The creep tester according to any one of claims 1 to 5, wherein the weight is movably mounted along a longitudinal direction on the other side of the creep tester. The creep tester according to the present invention is not limited to the tensile creep tester described in the illustrated embodiment, but may include other creep testers for compression, bending, and the like.

By moving the weight along the longitudinal direction of the load lever, the load applied to the test piece can be set steplessly, so that the load can be set accurately in accordance with the cross-sectional area of the test piece. The stress can be easily set to a desired value, and even if the cross-sectional areas of a plurality of test pieces vary, the stress can be kept constant. The results are obtained, and the load can be easily controlled automatically in accordance with the cross-sectional area during the test. Therefore, there is an effect that a creep test with constant stress can be realized for the first time. In addition, since a single weight is moved along the longitudinal direction of the load lever to vary the load applied to the test piece, not only can labor and time be reduced, but also the risk is minimized. There is an effect that can be.

Further, in the present invention, a rail for moving a weight is formed in a weight mounting portion of the load lever, so that the weight moves smoothly.
It provides a creep test machine as described. The present invention also provides a creep test machine according to claim 6 or 7, wherein a conveyor mechanism for moving a weight is provided at a weight mounting portion of the load lever, and the conveyor is moved smoothly by the conveyor mechanism. Is what you do.

Further, in the present invention, the conveyor mechanism comprises a feed screw conveyor provided along the longitudinal direction of the load lever, and the weight can be moved by rotating the feed screw. A creep tester according to claim 8 is provided. With the feed screw conveyor, the weight can be moved with high precision, and the stop screw can be stopped and the weight can be stopped to set the position accurately.The screw shaft is screwed into the weight. The weight can be prevented from falling due to an earthquake or the like.

Further, according to the present invention, since the weight moving mechanism is provided so as to be controllable by a driving device such as a driving motor or an actuator, the movement of the weight is controlled by the driving device and the load setting labor is minimized. 10. A creep test with a constant stress being realized, wherein load control can be facilitated by weight movement control corresponding to a change in the cross-sectional area of the test piece during the test. And a creep tester described in (1).

Further, according to the present invention, since the driving device is provided at one side end of the load lever on which the test piece is mounted, the weight mounting portion can be freely provided regardless of the type of the driving device. 2. The method according to claim 1, wherein the weight also acts as a counterweight.
0 is provided. Further, the present invention provides a displacement meter for measuring a displacement of a test piece, a displacement portion provided on a force point of a load lever for pulling the test piece, and a detecting portion provided on a support member for supporting the fulcrum of the load lever. The creep tester according to any one of claims 1 to 11, wherein the deformation of the test piece can be directly detected with high accuracy.

Further, according to the present invention, a counterweight is provided at one side end of the load lever so as to maintain the balance of the load lever on which the weight is mounted. A creep tester according to any one of the above. The creep test according to any one of claims 1 to 13, wherein a balance weight is provided at one side end of the load lever so as to maintain the balance of the weight drive mechanism. Machine.

Further, the present invention provides a creep tester according to any one of claims 1 to 14, further comprising a thermostat for accommodating a test piece. Also,
The present invention provides the creep testing machine according to any one of claims 1 to 15, wherein a plurality of the load levers are provided in parallel so that a plurality of creep tests can be performed at the same time. is there. The creep testing machine according to any one of claims 1 to 16, wherein a plurality of test pieces are accommodated in the constant temperature bath so that a plurality of creep tests can be performed at the same time. Is provided.

[0016]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Embodiments of the present invention will be described based on embodiments with reference to the drawings. FIG. 1 is a schematic front view showing an embodiment of the creep tester of the present invention, FIG. 2 is a schematic side view thereof, and FIG. 4 is a side cross-sectional view of a load lever buffering mechanism as another main part, and FIG. 5 is a schematic front cross-sectional view showing a main part of the present embodiment in a partially longitudinal manner.

In the case of the embodiment, the creep tester of the present invention
A thermostatic chamber 1 having a test piece mounting portion, a load lever 2 for swinging about a fulcrum 25 to pull a test piece at a power point 26 and mounting a weight on a long rod portion on the opposite side, a weight driving section 4, and a load A lever buffer mechanism 5 is provided. The constant temperature bath 1 is located at the lower front side, and a stirring fan motor 11 for keeping the inside of the constant temperature bath 1 at a constant temperature via a heater is provided behind the constant temperature bath 1. In the case of the embodiment, as shown in FIG. 1, a plurality of test chambers 12 are provided in parallel in the thermostat 1 so that a plurality of test pieces A can be tested at the same time. 3 is a test piece observation window, 17 is an operation panel, and 18 is a record display window.

As shown in FIG. 3, chucks 13 are provided at the upper and lower sides of the test chamber 12 so that both ends of the test piece A can be chucked according to the standard and pulled vertically. It is. The lower chuck 13 is firmly fixed to the testing machine stand, while the upper chuck 13 is integrated with a chuck member 21 that penetrates above the thermostatic chamber 1 and extends to and near the load lever 2. Is attached. Although not shown in the drawing, a cross-sectional observation device for the test piece A is provided to automatically detect the cross-sectional area of the test piece that changes every moment during the creep test, and to apply a load corresponding to the changing cross-sectional area. A constant stress test can be made possible.

The chuck member 21 loosely penetrates the chuck guide 15 provided at the front end of the fulcrum support base 14 provided integrally with the body, and the upper end thereof has a force point 26 of the load lever 2.
Are fixed integrally to a chuck member mounting portion 28 of a coupling 27 provided rotatably around the center. In the case of the embodiment, the load lever 2 is composed of two rails 22 provided in parallel at a fixed interval as shown in the center of FIG.
In the position, the coupling 27 is provided rotatably by bearings between the rails 22 so as to be orthogonal to the rails, so that the coupling 27 is rotatable about the force point 26. Accordingly, when the load lever 2 is inclined around the fulcrum 25 due to the deformation of the test piece A, the linearity of the chuck member 21 is maintained.

On the coupling 27, a displacement shaft 34 is vertically provided integrally and vertically with the chuck member 21, and a displacement portion integral with the displacement shaft 34 is provided in the electronic displacement meter 24. It is configured so that the deformation generated in the test piece A can be accurately measured by moving. The displacement meter 24 is integrally supported by a fixing member 34 on a support frame 8 provided on a column 7 erected integrally with the fulcrum support base 14 along the chuck member 21. The fulcrum 25 for swingably supporting the load lever 2 composed of the two rails 22 is horizontally mounted on the fulcrum support bases 14 on both outer sides of the two rails 22 as partially shown in FIG. Two rails 22 are provided on the fulcrum shaft 16 via the bearing 9.
Is rotatably supported. That is, when a plurality of the load levers 2 according to the present invention are provided in parallel, the rails 22 constituting the adjacent load levers 2 are horizontally provided in such a manner that the rails 22 constituting the load levers 2 are stretched over the fulcrum support bases 14 erected therebetween. The fulcrum shaft 16 is configured to be supported on both sides. Accordingly, at the position of the fulcrum 25, the two rails 22 constituting the load lever 2 are supported on the fulcrum shaft 16 outside thereof, and the fulcrum shaft 16 does not exist between the rails. .

The two rails 22 are firmly integrated as load levers 2 at both ends and the like, and support points 25 are provided.
The weight mounting portion 30 is formed in two rails on the opposite side of the power point 25 with the center as the center, and the weight 10 according to the present invention is movably guided. In the case of the embodiment, the weight 10 is formed of a rectangular parallelepiped having a thickness capable of loosely passing between the two rails 22 via the guide gap, and the center of gravity passes on a line connecting the fulcrum 25 and the force point 26. It is movably provided by four upper and lower four pairs of wheels 33. In the case of the embodiment, the wheel 33 is formed of a wheel with a flange like a wheel of a railway track, and the flange is fitted into the guide gap, so that the weight 10 moves smoothly without sideways or the like. I have.

A feed screw 36 is rotatably provided at the center of the two rails 22 of the load lever 2 so that the axis passes along a line connecting the fulcrum 25 and the force point 26. The feed screw 36 is connected to the bearing 23 at the rear end of the rail 22 and the power point 26.
The bearing 27 is rotatably supported between a bearing 31 provided on the rail 22 near the distal end of the coupling 27.
The rotating shaft portion 46 on the distal end portion side is connected to a motor shaft 48 of a drive motor 42 provided at the distal end portion of the load lever 2 via a flywheel-shaped shaft coupling 45. The rotary shaft 46 between the shaft coupling 45 and the bearing 31 is provided with an encoder 47 for detecting the rotation speed of the feed screw 36. The rotation shaft 39 of the feed screw 36 penetrating through the coupling 27 portion of the force point 26 has the load lever 2 inclined between the rotation shaft 39 and the through hole 29 provided in the coupling 27 as shown in FIGS. Needless to say, spaces are provided so as not to contact each other.

The weight 10 is provided with a through hole 32 passing through the center of gravity.
Female screw members 37 and 38 that are rotatably screwed to 6 are detachably and integrally fixed and provided, and the weight 10 moves on the rail 22 as the feed screw 36 rotates. . Since the female screw members 37 and 38 rotatably screwed to the feed screw 36 are detachably provided,
There is no need to provide a female screw through the weight, and the weight can be easily attached to and detached from the load lever 2. In the present invention, the conveyor mechanism that controls the rail transport of the weight 10 is configured to include a belt conveyor that can move the weight by rotating a belt, in addition to the feed screw conveyor mechanism in the above embodiment. In addition, the conveyor mechanism may be constituted by an endless annular transfer member having a weight fixed in the middle, and the weight may be moved by rotating the transfer member.

In addition, as the driving device 4 for the conveyor mechanism, the weight 10 can be provided so as to be able to control the movement of the weight 10 by a driving device such as a hydraulic actuator in addition to the driving motor. Proximity sensors including limit switches 19 and 20 are provided near the starting point and the ending point near the fulcrum 25 of the load lever 2 so as to regulate the moving range of the weight 10. A counterweight 40 is provided on the load lever 2 between the drive motor 42 and the power point 26, and the balance of the load lever 2 when the weight 10 is moved to the movement origin near the fulcrum is measured to obtain the balance before the test. The test piece A is configured not to give an extra force. Also, the counterweight 40 is provided so as to be adjustable in position, and the weight 10
And the load lever 2 may be configured to be in the equilibrium stable state at the origin of movement of the weight 10.

A balance weight 41 is provided on the motor mounting plate 43 of the drive motor 42 so as to correct the imbalance of the load around the axis of the load lever 2 due to the load of the drive motor 42. . In addition, the present invention relates to the side end portion 44 of the weight mounting portion 30.
In addition, a load lever buffer mechanism 5 for supporting the load lever 2 when the test piece A breaks is provided so as not to give an impact to the creep test machine. The configuration of the load lever buffering mechanism 5 is such that in all creep test machines that mount a test piece on one side of a load lever around a fulcrum and add a weight to the other side to measure deformation of the test piece, It can be implemented in common.

The load lever buffer mechanism 5 is characterized in that a load lever buffer table 51 is provided, and a gap 49 is provided between the load lever buffer table 51 and the side end 44 of the weight mounting section 30. Things. In the creep test,
Since the deformation from the start of deformation of the test piece A to the cutting can be predicted, the load lever shock absorber 51 is connected to the side end of the weight mounting portion 30 through a gap corresponding to the length of the deformation to be measured in the test. 44, the test piece A
Can be held by the load lever shock absorber 51 at a short distance from the weight mounting portion 30 when it is cut. Further, the present invention is characterized in that a shock absorbing member 52 is provided on the load lever shock absorbing base 51 to minimize the impact. In the present invention, the vertical movement mechanism 50 is provided on the load lever shock absorber 51. Thereby, the weight mounting portion 30 is formed corresponding to the deformation of the test piece A.
Not only can the gap 49 provided between the side end portion 44 and the load lever buffer table 51 be appropriately adjusted,
The gap 49 can be maintained at a substantially constant interval corresponding to the deformation of the test piece A during the creep test.

The load lever shock absorber 51 has the shock absorber 52 made of a coil spring, rubber or synthetic resin between the base 61 and the receiving stand 62 at the U-shaped bottom piece. The end of the rail 22 is guided. A rack member 63 is provided integrally below the center of the base 61, and the rack member 63 is provided so as to be vertically movable by a guide member 53 integrally fixed to the apparatus body. The rack member 63 is engaged with a pinion member that is driven to rotate by the vertical drive motor 55 in the guide member 53. Guide rollers 54 for vertically moving the rack member 63 are provided above and below the guide member 53. A switch contact portion 57 is provided near the lower end of the rack member 63, and is provided with limit switches 58, 5 provided on the body.
9, the upper and lower limit positions of the load lever buffer table 51 are regulated. The vertical movement mechanism of the load lever shock absorber 51 is not limited to the rack and pinion mechanism of the embodiment. For example, the rack member 63 includes a screw shaft having an upper end rotatably mounted on the base 61, and a screw shaft. It goes without saying that a conventionally known structure such as a screw mechanism or the like can be used in which the shaft is moved up and down by a rotating nut member or the like provided on the body.

In this embodiment, the vertical movement mechanism 50 provided on the load lever buffer table 51 allows the load lever to be maintained at a substantially constant interval in response to the deformation of the test piece A during the creep test. Buffer table 51 and weight mounting part 3
A gap sensor including a proximity switch 60 and the like is provided between 0 and 0. If the test piece A is deformed during the creep test and the gap 49 is narrowed, the gap 49 is not lost.
The gap sensor is activated, the vertical drive motor 55 is driven to lower the load lever buffer table 51, and the load lever buffer table 51 and the weight mounting unit 30 are brought into contact with each other so that the measurement is not affected and the test is performed. It is configured such that a constant gap 49 can be maintained at all times so that no impact is applied to the entire apparatus even when the piece is cut. In the present embodiment, a gap of 1 to 2 mm is always provided between the lower side of the side end of the weight mounting portion 30 and the upper end of the load lever shock absorber 51. Reference numeral 56 denotes a U-shaped upright piece of the load lever buffer 51, which guides the end of the rail 22 therebetween. 64
Denotes a cover body of the load lever buffer mechanism 5.

In the embodiment of the present invention, as shown in FIG. 1 or FIG. 5, a plurality of load levers 2 are provided in parallel so that a plurality of creep tests can be performed simultaneously. And In this case, a plurality of creep tests can be performed simultaneously under the same temperature condition by using a configuration in which a plurality of test pieces A are accommodated in parallel in the constant temperature bath 1. In FIG. 5, in the six sets of devices capable of performing the creep test, in order from left to right, the first position of the drive motor 42, the second position of the counterweight 40, and the third position 26, the fourth and fifth are the positions of the fulcrum shaft 16, and the sixth is an explanatory diagram for explaining the configuration at the position of the load lever buffer mechanism at the side end of the weight mounting portion.

In the configuration of the above embodiment, the feed screw 36 is rotated by the weight drive motor 42 to move the weight 10 to the origin of movement in the vicinity of the fulcrum 25.
Is fixed to the chuck 13 in a state close to zero load. Next, only by moving the weight 10 gradually along the rail 22 of the load lever 2 toward the side end of the weight mounting portion 30 to generate a predetermined stress on the test piece A,
The predetermined installation of the tensile creep test will be completed. At this time, the load applied to the test piece A is the weight 10
Since it gradually increases in a stepless manner with the movement of the test piece, it is possible for the load to be applied in a stepwise manner when setting the load, as in the past, which could adversely affect the test specimen. And accurate test results are obtained. In addition, by applying a load steplessly, a constant stress can be easily applied to subtle variations in the cross-sectional area of the test piece.

When a change in the cross-sectional area of the test piece is detected by the device for observing the cross-sectional area of the test piece during the creep test, the weight 10 is moved along the rail in response to the change. A creep test at a constant stress can be realized. At this time, in the tester of the embodiment of the present invention, when the test piece is deformed, the chuck member 21 is vertically displaced upward, and the load lever 22 is tilted downward at the side end of the weight mounting portion 30. However, at this time, if the side end of the weight mounting portion 30 contacts the load lever buffer table 51 beyond the buffer gap 49, the creep test cannot be performed accurately thereafter.
Therefore, in the embodiment of the present invention, first, in order to always keep the buffer gap 49 between the lower end of the side end of the weight mounting portion 30 and the upper end of the proximity sensor 60 provided above the load lever buffer base 51 at a constant interval. , So that the load lever buffer table 51 can move up and down. In the present embodiment, a gap of 1 to 2 mm is always provided between the lower side of the side end of the weight mounting portion 30 and the upper end of the load lever shock absorber 51. In the present embodiment, the vertical movement mechanism 50 controls the movement of the load lever buffer table 51 that moves up and down by the rack and pinion mechanism by driving the pinion with the vertical drive motor 55 based on the gap detection signal of the proximity sensor 60. Then, the load lever buffer table 51 is displaced downward, and the buffer gap 49 between the lower side end of the weight mounting portion 30 and the upper end of the load lever buffer table 51 is always maintained at a constant interval. ing.

When the elongation limit of the test piece A is reached, the test piece A breaks. In the conventional creep tester, when the test piece A breaks, the weight mounting portion 30 of the load lever 2 is largely inclined downward, but in the present invention, in this case, the buffer gap 49 is used.
The side end portion of the weight illuminating portion 30 is received and supported via the member, so that the generation of a large force on the weight mounting portion 30 can be suppressed. Therefore, when a plurality of creep tests can be performed at the same time as in the embodiment of the present invention, for example, a creep test is performed under the same load using test pieces of different materials, respectively, or the same material is used. It is possible to perform a creep test under different loads using the same specimen, and even if another creep test is performed simultaneously, the creep test will not adversely affect the test of the other specimen by cutting the specimen. The test can be performed.

[0033]

As described above, according to the creep tester according to the present invention, the test piece is mounted below one side of the load lever around the fulcrum, and the weight is added to the other side, and In a creep tester for measuring deformation, a load lever buffer mechanism for supporting a load lever when a test piece breaks is provided at a side end of a weight mounting portion for mounting the weight on the other side of the load lever, and a creep test is performed. With the construction of a creep test machine characterized in that it is configured not to give an impact to the machine, conventionally, when the test piece breaks, the weight suspended from the end of the load lever at the point of action of the load lever Although the weight may drop sharply on the table, the total weight may reach several hundred kilograms in some cases. If you perform the test at the same time in parallel,
Although the effect was not negligible, the present invention allows the load lever to be supported at a close distance when the test piece is broken by the load lever buffer mechanism provided at the side end of the weight mounting portion. Has the effect of not giving an impact to the creep tester, and has the effect of providing an accurate and safe creep tester. Although it is extremely difficult to support the weight near the fulcrum of the load lever, the present invention provides a load lever buffer mechanism at the side end of the weight mounting portion far away from the fulcrum. There is an effect that the falling force applied to the load lever when the rupture occurs can be supported with a minimum force.

According to the present invention, in the load lever shock absorbing mechanism, a load lever shock absorber is provided with a gap between the load lever shock absorbing mechanism and a side end of the weight mounting portion.
By having the configuration of the creep test machine described, the load lever shock absorber has no adverse effect on the load lever being measured, and when the test piece breaks, the load lever is immediately supported at a small gap drop distance. This has the effect of not causing impact.

Further, according to the present invention, since the load lever shock absorber is provided with a vertical movement mechanism, the gap provided between the side end of the weight mounting portion and the load lever shock absorber can be variably set. The creep tester according to claim 2 has a configuration, so that a buffer gap provided between a side end of the weight mounting portion and the load lever buffer table in accordance with deformation of a test piece is appropriately adjusted. In addition to being able to adjust, there is an effect that the impact gap can be maintained at a substantially constant interval corresponding to the deformation of the test piece during the creep test.

The present invention also provides a proximity sensor and a detection device for detecting the proximity sensor so that a buffer gap provided between the side end of the weight mounting portion and the load lever buffer table is always maintained at a substantially constant interval. 2. The apparatus according to claim 1, further comprising a driving device for controlling the vertical movement of the load lever shock absorber according to the signal, and automatically moving the test piece in accordance with the length and deformation of the test piece.
According to the configuration of the creep tester described in any one of (1) to (3), the impact gap can be maintained at a substantially constant interval corresponding to the deformation of the test piece during the creep test, so that the test piece can be placed at an unexpected position. Even if it breaks, the load lever can be held by a close fall and the creep test can be performed without adversely affecting other test pieces and without impacting the entire test machine. Having.

The creep test according to any one of claims 1 to 4, wherein a shock-absorbing member is provided on the load lever shock-absorbing table so that an impact at the time of cutting the test piece can be minimized. By having the configuration of the machine, there is an effect that the impact due to the fracture of the test piece can be reduced.

The creep testing machine according to any one of claims 1 to 5, wherein the weight is movably mounted along the longitudinal direction on the other side of the load lever. With this configuration, the load applied to the test piece can be set steplessly by moving the weight along the longitudinal direction of the load lever, so that the load can be set accurately according to the cross-sectional area of the test piece. And the stress can be easily set to a desired value, and the stress can be kept constant even if the cross-sectional areas of a plurality of test pieces vary. This has the effect of preventing variations in the results and providing accurate test results.Furthermore, by controlling the movement of the weights, it is possible to automatically control the load according to changes in the cross-sectional area during the test. Since it to the easy, there is an effect that it is possible to realize a creep test to stress constant. In addition, since a single weight is moved along the longitudinal direction of the load lever to vary the load applied to the test piece, not only the labor and time can be reduced, but also the danger when setting the load. Has an effect that can be minimized.

Further, in the present invention, a weight moving rail is formed in the weight mounting portion of the load lever, so that the weight moves smoothly.
With the configuration of the creep tester described, there is an effect that the heavy weight can be smoothly moved by the rail. 8. The creep tester according to claim 6, wherein a conveyor mechanism for moving the weight is provided at the weight mounting portion of the load lever, and the conveyor is moved smoothly by the conveyor mechanism. Has an effect that a heavy weight can be smoothly moved by the conveyor mechanism.

Further, according to the present invention, the conveyor mechanism comprises a feed screw conveyor provided along the longitudinal direction of the load lever, and the weight can be moved by rotating the feed screw. The creep tester according to claim 8, which has an effect that the weight can be moved with high precision by the feed screw conveyor, and stops only by stopping the feed screw and stopping the weight. There is an effect that the position can be accurately set and set, and since the screw shaft is screwed into the weight, the weight can be prevented from dropping from the load lever due to an earthquake or the like. Further, according to the present invention, the weight moving mechanism is driven by having the configuration of the creep tester according to claim 8 or 9, wherein the weight moving mechanism is provided so as to be able to move by a driving device such as a driving motor or an actuator. It can be controlled by the device to minimize the load setting labor, and the load can be easily controlled by the weight movement control corresponding to the change in the cross-sectional area of the test piece during the test. There are effects such as realization.

Further, according to the present invention, the above-mentioned driving device is provided at one side end on which the test piece of the load lever is mounted, so that the weight mounting portion is formed by the creep tester according to the present invention. In addition to the effect of being able to be freely provided regardless of the form of the driving device, there is an effect that the weight also acts as a counterweight. Further, the present invention provides a displacement meter for measuring the displacement of the test piece, a displacement portion provided on a force point of a load lever for pulling the test piece, and a detection portion provided on a support member for supporting the fulcrum of the load lever. The creep tester according to any one of claims 1 to 11, characterized in that the deformation of the test piece can be directly detected on the point of force with high accuracy.

According to the present invention, a counterweight is provided at one side end of the load lever to maintain the balance of the load lever on which the weight is mounted. Has the effect of realizing a zero load on the weight mounted on the load lever when a test piece is mounted or the like. The creep test according to any one of claims 1 to 13, wherein a balance weight is provided at one side end of the load lever so as to maintain the balance of the weight drive mechanism. With the configuration of the machine, there is an effect that offset load around the axis of the load lever by the weight drive mechanism can be offset to maintain balance.

Further, according to the present invention, the creep tester according to any one of claims 1 to 14 is provided with a thermostatic chamber for accommodating the test specimen, whereby the test specimen is thermostated. The test can be performed under a predetermined temperature.
Further, the present invention provides a creep testing machine according to any one of claims 1 to 15, wherein a plurality of the load levers are provided in parallel so that a plurality of creep tests can be performed simultaneously. By having the same, multiple creep tests can be performed at the same time.For example, a creep test can be performed with the same load using test pieces of different materials, or a test piece of the same material can be used for each. Thus, the creep test can be performed with different loads. Further, according to the present invention, a plurality of test pieces are accommodated in the constant temperature bath so that a plurality of creep tests can be performed at the same time.
By having the creep tester described in any one of the above, there is an effect that a creep test of a plurality of test pieces can be performed simultaneously under the same temperature condition.

[Brief description of the drawings]

FIG. 1 is a schematic front view of an embodiment of a creep tester of the present invention.

FIG. 2 is a schematic side view of the embodiment of FIG.

FIG. 3 is a schematic enlarged side view showing a main part of the embodiment of FIG.

FIG. 4 is a schematic enlarged side view showing another main part of the embodiment of FIG.

FIG. 5 is a schematic enlarged vertical sectional front view showing the six load levers of the embodiment shown in FIG.

[Description of Signs] 1 constant temperature bath 2 load lever 3 test piece observation window 4 weight drive unit 5 load lever buffer mechanism 6 coupling support shaft 7 support 8 support frame 9 bearing unit 10 weight 11 stirring fan motor 12 test chamber 13 chuck 14 Supporting point support base 15 Chuck guide 16 Supporting axis 17 Operation panel 18 Recording display 19, 20 Limit switch 21 Chuck member 22 Rail 23 Bearing 24 Displacement meter 25 Support 26 Force point 27 Coupling 28 Chuck member mounting part 29 Through hole 30 Weight mounting part 31 Bearing part 32 Through hole 33 Wheel 34 Displacement shaft 35 Guide measuring part 36 Feed screw 37, 38 Female screw member 39 Rotating shaft part 40 Counterweight 41 Balance weight 42 Drive motor 43 Motor mounting plate 44 Side end 45 Shaft Joint 46 Rotation shaft 7 Encoder 48 Motor shaft 49 Buffer gap 50 Vertical movement mechanism 51 Load lever buffer table 52 Buffer member 53 Guide member 54 Guide roller 55 Vertical drive motor 56 Standing piece 57 Switch abutment 58, 59 Limit switch 60 Proximity switch 61 Base 62 Cradle 63 Rack member 64 Cover body

Claims (18)

[Claims] 1. A creep tester for measuring a deformation of a test piece by mounting a test piece under one side of a load lever around a fulcrum and adding a weight to the other side, the creep tester comprising: A creep test machine characterized in that the weight is movably mounted along the longitudinal direction. 2. The creep testing machine according to claim 1, wherein a rail for moving a weight is formed on a weight mounting portion of the load lever. 3. The creep testing machine according to claim 1, wherein a conveyor mechanism for moving a weight is provided at a weight mounting portion of the load lever. 4. The conveyor mechanism comprises a feed screw conveyor provided along the longitudinal direction of a load lever, wherein the weight can be moved by rotating the feed screw. The creep testing machine according to claim 3, wherein 5. The creep testing machine according to claim 3, wherein the conveyor mechanism is provided so as to be able to control the movement by a drive device such as a drive motor or an actuator. 6. The creep testing machine according to claim 5, wherein the driving device is provided at one end of the load lever on which a test piece is mounted. 7. A displacement meter for measuring a displacement of a test piece, comprising: a displacement portion provided on a force point of a load lever for pulling the test piece; and a detection portion provided on a support member for supporting the fulcrum of the load lever. The creep test machine according to any one of claims 1 to 6, wherein 8. The load lever according to claim 1, wherein a counter weight is provided at one side end of the load lever to maintain the balance of the load lever on which the weight is mounted. The creep test machine described. 9. The creep testing machine according to claim 1, wherein a balance weight is provided at one end of the load lever so as to maintain the balance of the weight drive mechanism. . 10. A creep tester is provided with a lever buffering mechanism for supporting a load lever when a test piece breaks at a side end of the weight mounting portion so as not to give an impact to a creep tester. Item 10. A creep tester according to any one of Items 1 to 9. 11. A creep tester for mounting a test piece below one side of a load lever with a fulcrum as a center and applying a weight to the other side to measure deformation of the test piece. A creep tester characterized by providing a lever buffer mechanism at the end for supporting a load lever when a test piece breaks, so as not to give an impact to the creep tester. 12. The creep test machine according to claim 10, wherein the lever buffer mechanism has a lever buffer table provided with a gap between the lever buffer mechanism and a side end of the weight mounting section. 13. The creep test machine according to claim 12, wherein the lever shock absorber has a vertical movement mechanism. 14. A proximity sensor for maintaining a gap provided between a side end of the weight mounting portion and the lever shock absorber at a substantially constant interval, and a lever shock absorber in response to a detection signal of the proximity sensor. The creep test machine according to any one of claims 10 to 13, further comprising a drive control device for controlling vertical movement. 15. The creep test machine according to claim 10, wherein a buffer member is provided on the lever buffer table. 16. The creep tester according to claim 1, further comprising a thermostat containing said test piece. 17. The creep testing machine according to claim 1, wherein a plurality of said load levers are provided in parallel so that a plurality of creep tests can be performed at the same time. 18. A plurality of test pieces are stored in the constant temperature bath,
The creep testing machine according to any one of claims 1 to 17, wherein a plurality of creep tests can be performed simultaneously.