JP2021101187A - Device and method for testing free vibration of metal tube column - Google Patents

Abstract

To provide a device and a method for testing the free vibration of a metal tube column, capable of accurately detecting acceleration response in the horizontal direction to a free vibration test on the basis of only a load in the horizontal direction.SOLUTION: A device for testing the free vibration of a metal tube column, capable of confirming the free oscillation characteristics of a metal tube column 2 comprises; a wire 42 attached to the point of action 2b of the metal tube column 2 erected in an approximately vertical direction, stretched in an approximately horizontal direction and hung downward in an approximately vertical direction through a pulley 45; a weight 44 used as load means for vibrating the metal tube column 2 by loading a tensile force from the lower end of the wire 42 and bending the metal tube column 2 through the point of action 2b to transfer the metal tube column to an unloaded state; and an acceleration sensor 46 used as acceleration measurement means for measuring acceleration response in an approximately horizontal direction of a vibration in metal tube column 2.SELECTED DRAWING: Figure 5

Description

The present invention relates to a free vibration test apparatus and method for a metal tube column suitable for more accurately measuring the free vibration characteristics of a metal tube column used for an illumination column, a sign column, or the like.

Bending loads based on wind power and ground vibration are applied to metal pipe columns used for lighting columns and sign columns installed on the side of roads. Systems and methods for confirming mechanical characteristics with respect to such bending loads and vibration characteristics based on traffic vibration have been studied conventionally. (See, for example, Patent Document 1.)

FIG. 7A shows an example of a system configuration for confirming the mechanical characteristics of the conventional metal pipe column 7 with respect to a bending load. A wire 81 is attached to an action point 7a of a metal pipe column 7 fixed to a fixing jig 71, and the wire 81 is pulled. A load cell 82 is attached to the wire 81 so that the tensile load can be measured. The metal tube column 7 is in a state in which a bending load is applied as shown in FIG. 7 (b) by applying a tensile force after the base end portion 7b is fixed to the fixing jig 71. , Will be bent and deformed. By measuring the amount of deflection based on this bending deformation, it is possible to determine the mechanical characteristics and various behaviors with respect to the bending load.

FIG. 8 shows an enlarged state in the vicinity of the action point 7a of the metal pipe column 7 before and after bending deformation. Originally, in order to accurately apply the bending load, it is important to control the pulling direction of the wire 81 to be substantially perpendicular to the stretching direction H at the point of action 7a of the metal tube column 7. In the no-load state of the bending load, the stretching direction H at the point of action 7a of the metal pipe column 7 is horizontal, and the tensile direction of the wire 81 is perpendicular to the stretching direction H. Therefore, the measurement accuracy There is no particular problem in terms of.

However, as the bending load is applied, the stretching direction H at the point of action 7a of the metal tube column 7 is greatly inclined. Moreover, since the height of the force point 83 for applying the tensile force by the wire 81 is fixed, the tension direction of the wire 81 at the action point 7a of the metal tube column 7 is relative to the extension direction H of the metal tube column 7. It is not almost vertical, but diagonal. In addition to this, it can be seen that the horizontal position G'of the action point 7a after the bending deformation changes with respect to the horizontal position G of the working point 7a before the bending deformation. As described above, assuming that the horizontal position of the force point 83 of the wire 81 is fixed, the pulling direction of the wire 81 becomes more oblique than the initial position by the amount of change to the horizontal position G'of the action point 7a. It ends up.

As a result, as shown in FIG. 8, based on the tensile force of the wire 81 _{, in addition to the load PA1 in the substantially perpendicular direction to the stretching direction H that is originally desired to act, the axial force PA2} along the stretching direction H also acts. Will be done. Since this axial force _PA2 is a component of a force different from the bending load that should be originally applied, when this is applied as a combined load, it is not possible to accurately grasp the bending deformation characteristics. Therefore, it is necessary to cancel _{the axial force PA2} of the metal tube column 7 in the extending direction H.

Note The bending test method for a metal tube column, for example, disclosed in Patent Document 1, even when the bent metal tube column 7, to cancel the axial force P _A2 to the extending direction H, further techniques continue to load only the load P _A1 substantially perpendicular direction with respect to the stretching direction H is not otherwise disclosed.

Further, FIG. 9 shows a conventional system for performing a free vibration test. In this free vibration test, the metal tube column 7 is vibrated and its acceleration response is measured. As a vibration method, a wire 81 is attached to the point of action 7a, and a tensile force is applied from a force point 83 at the other end of the wire 81. As a result, a load in the diagonally downward direction is applied from the point of action 7a toward the point of force 83 on the ground via the wire 81. When such a load is applied, the load P _{B2 in the} vertical direction is also loaded as a combined load on the _{point of action 7a in addition to the load P B1 in the horizontal direction.} By moving the unloaded state by cutting the wire 81 in this state, the metal tube column 7 so that the vibrating load P _B1 of the vibration force is also horizontally applied to this case, the vertical load P _B2 Will be based on.

Therefore, in performing the free vibration test, _{in addition to the vibration force based on the horizontal load P B1} that is originally desired to be applied, the vibration force based on the vertical load P _B2 also acts. Since this load P _{B2 is a component of a force different from the horizontal load P B1} that should be originally loaded, when this load is applied as a combined vibration force, the damping rate of the metal tube column 7 alone is accurately grasped. It becomes difficult. _{Therefore, the vibration force based on the vertical load P B2} generated based on this excitation is canceled, and the horizontal acceleration response to the free vibration test is accurately detected based only on the _{horizontal load P B1.} The system has been desired in the past.

Further, when the metal pipe pillar 7 is vibrated while the cut wire 81 is attached to the point of action 7a, the metal pipe pillar 7 is affected by the wire 81 and the pulley 45, and the attenuation rate of the metal pipe pillar 7 alone is accurate. It becomes difficult to grasp the wire 81, and the wire 81 flies in all directions accordingly, resulting in a dangerous state.
Therefore, it is also necessary to ensure the safety of the measurement work by dropping the wire 81 from the point of action 7a when the tensile force is released by the wire 81 to shift to the no-load state.

Japanese Unexamined Patent Publication No. 2016-118433

Therefore, the present invention has been devised in view of the above-mentioned problems, and an object of the present invention is to more accurately measure the free vibration characteristics of metal pipe columns used for lighting columns, sign columns, and the like. In the above, it is an object of the present invention to provide a free vibration test apparatus and method for a metal pipe column capable of accurately detecting a horizontal acceleration response to a free vibration test based only on a horizontal load P _B1.

In order to solve the above-mentioned problems, the present inventors attach a wire to the point of action of a metal pipe column erected in a substantially vertical direction, stretch it in a substantially horizontal direction, and vertically downward through a pulley. By suspending the metal tube column from the lower end of the wire and applying a tensile force to the metal tube column, the metal tube column is bent through the action point and then moved to a no-load state to vibrate the metal tube column. , Invented a free vibration test apparatus and method for measuring the acceleration response of the vibration in the substantially horizontal direction in the metal pipe column.

The free vibration test device for a metal tube column according to the first invention is a free vibration test device for confirming the free vibration characteristics of a metal tube column, and is located at a point of action of a metal tube column erected in a substantially vertical direction. By attaching a wire that is attached, stretched in a substantially horizontal direction, and suspended substantially vertically downward via a pulley, and by applying a tensile force from the lower end of the wire, the metal pipe column is connected via the above-mentioned point of action. It is provided with a load means for vibrating the metal tube column by shifting it to a no-load state after bending the metal tube column, and an acceleration measuring means for measuring the acceleration response of the vibration in the metal tube column in a substantially horizontal direction. It is characterized by that.

In the free vibration test apparatus according to the second invention, in the first invention, the wire is formed by engaging a ring formed at one end with a hook protruding from the metal pipe column and bent downward. The loading means is characterized in that a tensile force for suspending a weight is applied from the lower end of the wire, and the wire is cut to shift to a no-load state so that the wire is naturally dropped from the hook.

The free vibration test method for a metal pipe column according to the third invention is a free vibration test method for confirming the free vibration characteristics of a metal pipe column, and is used at a point of action of a metal pipe column erected in a substantially vertical direction. By attaching a wire, stretching it in a substantially horizontal direction, suspending it substantially vertically downward via a pulley, and applying a tensile force from the lower end of the wire, the metal pipe column is flexed through the action point. It is characterized in that the metal pipe column is vibrated by shifting it to a no-load state after the plumb bob, and the acceleration response of the vibration in the metal pipe column in a substantially horizontal direction is measured.

According to the present invention having the above-described configuration, in performing the free vibration test, only the vibration force based on the horizontal load that is originally desired to be applied acts, and the vibration force based on the vertical load acts particularly. There is no. Therefore, it is possible to accurately grasp the damping rate in the horizontal direction of the metal pipe column. That is, according to this free vibration test device, the vibration force based on the vertical load generated based on the vibration is canceled, and the horizontal acceleration response to the free vibration test is accurate based only on the horizontal load. Can be detected.

It is a figure which shows the form of the bending test apparatus of a metal tube column as 1st Embodiment. It is a figure which shows the case where the metal pipe column is bent and deformed in 1st Embodiment. It is a figure which shows the example which further includes a laser displacement meter and a control PC in 1st Embodiment. It is a figure for demonstrating the structure which directly changes the angle of the telescopic shaft of a hydraulic cylinder. It is a figure which shows the form of the free vibration test apparatus of a metal tube column as a 2nd Embodiment. It is a figure for demonstrating the bent part which is formed in an L shape. It is a figure which shows the system configuration example for confirming the mechanical property with respect to the bending load of a conventional metal pipe column. It is a figure which shows the enlarged state in the vicinity of the action point of the metal tube column before and after bending deformation. It is a figure which shows the system for performing a conventional free vibration test.

Hereinafter, embodiments for carrying out the present invention will be described in detail with reference to the drawings.

1st Embodiment FIG. 1 shows the embodiment of the bending test apparatus 1 as the 1st embodiment. The bending test device 1 includes a fixing jig 11 for fixing the base end 2a of the metal pipe column 2 to be bent, a wire 12 having one end attached to an action point 2b of the metal pipe column 2, and a metal pipe column. A lighting unit 13 provided at the upper end 2c of the wire 12, a load cell 14 provided at the middle stage of the wire 12, a pulley 15 around which the wire 12 is wound, and a hydraulic cylinder 16 to which the other end of the wire 12 is attached are provided. ing. The bending test device 1 further includes a hydraulic cylinder 17 for controlling the horizontal position of the pulley 15.

The metal pipe column 2 to be subjected to the bending test is a steel tubular structure applied to all columnar structures such as lighting columns and sign columns installed on the side of a road, antenna columns unrelated to the road, and columns for fences. It is a pillar. In the following description, a case of testing a lighting column provided with a lighting unit 13 at the upper end 2c will be described as an example.

The fixing jig 11 is provided with a fixing means for fitting and fixing the base end 2a of the metal pipe column 2. The fixing jig 11 is configured so that the base end 2a can be fixed so that the extending direction B of the metal pipe column 2 is substantially horizontal as shown in FIG. 1 in a no-load state. The fixing to the fixing jig 11 is not limited to fitting the base end 2a, and in the case of the metal pipe column 2 with the base plate, the base plate is fixed to the fixing jig 11 by bolting, etc. Any fixing method may be used as long as the base end 2a of the metal pipe column 2 can be fixed.

When attaching one end of the wire 12 to the point of action 2b of the metal pipe column 2, the wire 12 may be wound around the point of action 2b and tied. Further, the wire 12 may be attached to one end of the wire 12 to a jig (not shown) provided from the beginning at the point of action 2b. The wire 12 is relayed by the load cell 14. As a result, when a tensile force is applied to the wire 12, the stress is directly transmitted to the load cell 14. The wire 12 is stretched vertically downward from the point of action 2b of the metal pipe column 2 in the no-load state shown in FIG. The other end of the wire 12 is wound around the pulley 15 and stretched in a substantially horizontal direction, and is attached to the hydraulic cylinder 16.

The lighting unit 13 is a device for turning on / off a lighting lamp based on an electric signal, and is composed of, for example, an incandescent lamp, an LED, or the like. If the lighting unit 13 does not seem to affect the performance of the metal tube column 2, the configuration of the lighting unit 13 may be omitted. The same applies to the metal tube column 2 without the illumination unit 13.

The load cell 14 is directly loaded with the tensile force applied to the wire 12. The load cell 14 measures the tensile force applied to the wire 12. The measured value of the tensile force measured by the load cell 14 is converted into an electric signal and sent to an analysis device such as a PC.

The pulley 15 guides the tensioning direction of the wire 12 stretched from the point of action 2b in a substantially horizontal direction. The pulley 15 is configured to be movable in the horizontal direction according to the expansion and contraction of the attached hydraulic cylinder 17.

The hydraulic cylinder 16 is installed so that the telescopic shaft 16a is in a substantially horizontal direction. The hydraulic cylinder 16 is configured so that the telescopic shaft 16a can be expanded and contracted in response to an electric signal. The other end of the wire 12 is attached to the tip of the telescopic shaft 16a. The hydraulic cylinder 16 can pull the wire 12 in the horizontal direction by contracting the telescopic shaft 16a. Further, the hydraulic cylinder 16 can relax the tensile force of the wire 12 by extending the expansion / contraction shaft 16a. By controlling the electric signal transmitted to the hydraulic cylinder 16, the telescopic shaft 16a can be contracted, and the tensile force of the wire 12 can be adjusted.

The hydraulic cylinder 17 is installed so that the telescopic shaft 17a is in a substantially horizontal direction. The hydraulic cylinder 17 is configured so that the telescopic shaft 17a can be expanded and contracted in response to an electric signal. A pulley 15 is attached to the tip of the telescopic shaft 17a. By contracting the telescopic shaft 17a, the hydraulic cylinder 17 can control the pulley 15 so as to approach itself in the horizontal direction. By extending the telescopic shaft 17a, the hydraulic cylinder 17 can be controlled to push the pulley 15 in the horizontal direction (pulling direction A in the drawing). That is, the horizontal position of the pulley 15 can be freely adjusted by expanding and contracting the expansion / contraction shaft 17a of the hydraulic cylinder 17, and the wire 12 is stretched from the point of action 2b as shown in FIG. It is possible to control the setting angle φ. The stretching angle φ referred to here is set to 0 ° with reference to the wire 12 stretched in the vertical direction in the no-load state. The tension angle φ is gradually increased as the pulley 15 is pushed out in the pulling direction A as the expansion / contraction shaft 17a of the hydraulic cylinder 17 expands.

Next, the measurement operation in the first embodiment will be described. First, as shown in FIG. 1 described above, various configurations of the metal tube column 2 and the bending test device 1 in a no-load state are set. Next, an electric signal is transmitted to the hydraulic cylinder 16 in order to start the pulling operation. As a result, the expansion / contraction shaft 16a of the hydraulic cylinder 16 starts contracting, and the wire 12 attached to the expansion / contraction shaft 16a is pulled. As a result, a tensile stress is applied to the wire 12, and a bending load is applied to the action point 2b of the metal pipe column 2 attached to one end of the wire 12 via the wire 12. The tensile stress applied to the wire 12 is sequentially measured by the load cell 14.

When a bending load is applied through the wire 12, the metal tube column 2 is bent and deformed as shown in FIG. When the metal tube column 2 begins to bend due to bending deformation, the bending angle θ at the point of action 2b is measured. As shown in FIG. 2, the deflection angle θ corresponds to the difference angle between the extension direction B ′ of the metal tube column 2 at the point of action 2b and the horizontal direction. Since the stretching direction B of the metal tube column 2 in the no-load state is the horizontal direction, the deflection angle θ is 0 °. On the other hand, as the amount of bending deformation of the metal tube column 2 increases, the bending angle θ gradually increases.

The method of measuring the deflection angle θ may be manually performed by an operator. In such a case, a rod, a rope or the like may be attached to the point of action 2b, and the amount of deflection y at the point of action 2b may be calculated. Since the distance from the base end 2a to the point of action 2b is known, the deflection angle θ can be calculated based on the calculated deflection amount y.

Next, the position of the pulley 15 in the tensile direction A is controlled based on the deflection angle θ calculated from the measured deflection amount y. At this time, the position of the pulley 15 in the pulling direction A is controlled so that the tension angle φ of the wire 12 from the point of action 2b becomes equal to the deflection angle θ. The position of the pulley 15 in the pulling direction A is controlled by the hydraulic cylinder 17. That is, the worker acquires in advance the positional relationship of the pulley 15 in the pulling direction A with respect to the tension angle φ. Then, the position of the tension direction A of the tension angle φ that is equal to the deflection angle θ obtained by calculation is specified by referring to the positional relationship acquired in advance. Then, the pulley 15 is moved to the position of the specified tension direction A.

As a result, the tensioning angle φ of the wire 12 is controlled so as to be substantially equal to the bending angle θ. The fact that the stretching angle φ of the wire 12 is substantially equal to the bending angle θ means that the stretching direction of the wire 12 is substantially perpendicular to the stretching direction at the point of action 2b. That is, according to the present invention, even when the action point 2b in the metal tube column 2 bends and the stretching direction changes due to bending deformation, a bending load is applied in the direction perpendicular to the stretching direction of the action point 2b. It becomes possible. As a result, it is possible to apply only the bending load that is originally desired to be applied in the bending test of the metal tube column 2, and the axial force applied in the stretching direction of the metal tube column 2 can be made almost zero. It is possible to perform highly accurate measurement. The analysis of the actual bending deformation characteristics is performed based on the tensile load detected by the load cell 14 and the data such as the deflection amount y and the deflection angle θ calculated based on the detected displacement amount.

Further, by further contracting the expansion / contraction shaft 16a by the hydraulic cylinder 16, the metal tube column 2 is further bent and deformed, and the bending angle θ at the point of action 2b also changes. After detecting the deflection angle θ after this change, the hydraulic cylinder 17 is controlled so that the tension angle φ of the wire 12 becomes substantially equal to the deflection angle θ. As a result, each time the metal tube column 2 is further bent and deformed and the bending angle θ of the action point 2b changes, it is possible to continue applying the bending load in the direction perpendicular to the stretching direction of the action point 2b. .. As a result, the bending load is continuously applied in the direction perpendicular to the stretching direction of the point of action 2b from the start of bending deformation of the metal tube column 2 based on the tensile force P of the wire 12 until the end of the test. It becomes possible. This makes it possible to measure the bending deformation performance of the metal tube column 2 with high accuracy. In the present invention, it is not essential that the tension angle φ and the deflection angle θ of the wire 12 are completely equal to each other, and there may be some deviation between the values.

In the above-described embodiment, the case where the measurement of the deflection angle θ at the point of action 2b and the control of the tension angle φ of the wire 12 are both performed manually by an operator has been described as an example. It is not limited to.

For example, as shown in FIG. 3, a laser displacement meter 18 and a control PC 19 may be further provided. The laser displacement meter 18 irradiates the working point 2b and the upper end 2c to be measured with a laser beam, and measures the amount of displacement at the working point 2b and the upper end 2c. Based on this measured displacement amount, the control PC 19 calculates the deflection amount y.

The control PC 19 calculates the deflection angle θ from the calculated deflection amount y as described above. The control PC 19 controls the expansion / contraction shaft 17a of the hydraulic cylinder 17 and moves the pulley 15 so that the calculated deflection angle θ and the tension angle φ of the wire 12 are substantially equal to each other.

As a result, the load direction of the bending load is perpendicular to the stretching direction of the point of action 2b from the start of bending deformation of the metal tube column 2 based on the tensile force P of the wire 12 to the end of the test. It becomes possible to control automatically. In particular, by using automatic control, the bending test can be performed without human intervention, and the burden of test labor can be reduced. In addition to this, the deflection angle θ of the metal tube column 2 can be measured in real time through the laser displacement meter 18, and the tensile direction of the action point 2b by the wire 12 can be controlled in real time accordingly. In particular, the laser displacement meter can measure a slight displacement of the point of action 2b at a fine pitch, and automatic control by the control PC 19 corresponding to this can be realized at a fine pitch. Therefore, it is possible to further improve the measurement accuracy of the bending test.

In addition, in the present invention, the stretching direction at the action point 2b of the metal tube column 2 is calculated from the deflection angle θ, and the wire 12 is relative to the calculated stretching direction at the action point 2b, except for the case where the above-mentioned processing operation is a matter. Anything may be used as long as it is controlled so that the tensioning angle φ of the above is substantially vertical.

The present invention is not limited to the above-described embodiment. For example, the structure of the pulley 15 may be omitted, and the extension angle φ may be controlled by directly changing the angle of the telescopic shaft 16a of the hydraulic cylinder 16 as shown in FIG. 4, for example.

2nd Embodiment FIG. 5 shows the embodiment of the free vibration test apparatus 4 as the 2nd embodiment. In this free vibration test apparatus 4, the base end 2a of the metal pipe column 2 to be tested is fixed to the ground and erected so that the extending direction thereof is the vertical direction. The free vibration test device 4 is attached to a wire 42 having one end attached to the point of action 2b of the metal pipe column 2, an illumination unit 43 provided to the upper end 2c of the metal pipe column 2, and a lower end of the wire 42. It includes a weight 44, a pulley 45 around which the wire 42 is wound, and an acceleration sensor 46 provided in the vicinity of the action point 2b of the metal pipe column 2.

The metal pipe column 2 subject to the free vibration test is a steel tubular structure applied to all columnar structures such as lighting columns and sign columns installed on the side of a road, antenna columns unrelated to the road, and columns for fences. It is the same as the first embodiment that it is a pillar of. In the following description, a case of testing a lighting column provided with a lighting unit 13 at the upper end 2c will be described as an example.

When attaching one end of the wire 42 to the point of action 2b of the metal pipe column 2, the wire 42 may be wound around the point of action 2b and tied. Further, the wire 42 may be attached to one end of the wire 42 to a jig (not shown) provided from the beginning at the point of action 2b. The wire 42 is stretched in a substantially horizontal direction with respect to the point of action 2b. The other end of the wire 42 is wound around the pulley 45, stretched in a substantially vertical direction, and attached to the weight 44.

The height of the pulley 45 is adjusted from the point of action 2b in order to guide the direction of the wire 42 stretched substantially horizontally from the point of action 2b in the substantially vertical direction.

The acceleration sensor 46 measures the acceleration and performs appropriate signal processing to acquire information such as inclination and movement of the action point 2b, vibration and impact.

The free vibration test method in the second embodiment will be described. First, as shown in FIG. 5 described above, various configurations of the metal tube column 2 and the free vibration test device 4 are set. When the weight 44 is suspended from the wire 42 at the time of this setting, a tensile force is applied to the wire 42, and a bending load is applied to the action point 2b of the metal pipe column 2 to which the wire 42 is attached. As a result, the metal pipe column 2 is bent and deformed.

Next, the wire 42 on which the weight 44 is suspended is cut. When the wire 42 is cut, the metal tube column 2 is put into a no-load state, and the metal tube column 2 freely vibrates as shown by the dotted line in FIG. The point of action 2b also vibrates in response to the free vibration of the metal tube column 2, but the acceleration is measured by the acceleration sensor 46 attached in the vicinity thereof.

In particular, in the free vibration test apparatus 4, only the load in the horizontal direction is applied to the action point 2b of the metal pipe column 2 via the wire 42. _{Therefore, only the horizontal load PC1} is applied to the action point 7a, and the vertical load is not applied. By cutting the wire 42 in this state, the tensile force is released and the state shifts to the no-load state, so that the metal tube column 2 vibrates, but the vibrating force applied at this time is only the _{horizontal load PC1.} Will be based on.

Therefore, in performing the free vibration test, _{only the vibration force based on the horizontal load PC1} that is originally desired to be applied acts, and the vibration force based on the vertical load does not particularly act. Therefore, it is possible to accurately grasp the damping rate of the metal pipe column 7 in the horizontal direction. That is, this according to the free vibration test apparatus 4, to cancel the vibration force based on vertical load generated on the basis of the excitation, only on the basis of only the horizontal direction of the load P _C1, the horizontal direction of the acceleration to the free vibration test It is possible to detect the response accurately.

In the second embodiment, as shown in FIG. 6, the ring 48 formed at one end of the wire 42 is projected from the point of action 2b in the metal pipe column 2 and bent downward. It may be locked to the hook 50 to be held. The ring 48 may be a ring-shaped structure separately tied to the wire 42, or the wire 42 itself may be tied so as to form a ring.

The bent portion 51 is not limited to the case where it is formed in an L shape as shown in FIG. 6, and may have at least any shape as long as the bent portion 51 is bent downward. ..

When a tensile force is applied to the wire 42, the tensile force can be applied to the metal tube column 2 via the wire 42 in which the ring 48 is locked to the bent portion 51 as shown in FIG. , It becomes possible to bend this.

However, when the wire 42 is cut, it naturally falls from the hook due to the gravity of the wire 42. As a result, by vibrating the metal pipe pillar 2 while the cut wire 42 is attached to the point of action 2b, the metal pipe pillar 2 is not affected by the wire 42 and the pulley 45, and the attenuation rate of the metal pipe pillar 2 alone is reduced. In addition to being able to accurately grasp the wire 42, it is possible to prevent the wire 42 from flying in all directions, and it is possible to ensure the safety of the measurement work.

1 Bending test device 2, 7 Metal tube column 2a Base end 2b Action point 2c Upper end 4 Free vibration test device 11 Fixing jig 12, 42 Wire 13, 43 Lighting unit 14 Load cell 15 Pulley 16, 17 Hydraulic cylinder 16a, 17a Expansion and contraction Shaft 18 Laser displacement meter 44 Weight 45 Pulley 46 Accelerometer 48 Ring 50 Hook 51 Bent part

Claims (3)

It is a free vibration test device for confirming the free vibration characteristics of metal pipe columns.
A wire attached to the point of action of a metal pipe column erected in a substantially vertical direction, stretched in a substantially horizontal direction, and suspended substantially vertically downward via a pulley.
A load means for vibrating the metal tube column by applying a tensile force from the lower end of the wire to bend the metal tube column through the action point and then shifting the metal tube column to a no-load state.
A free vibration test apparatus for a metal pipe column, which comprises an acceleration measuring means for measuring an acceleration response in a substantially horizontal direction of the vibration in the metal pipe column. The wire is formed by engaging a ring formed at one end with a hook that protrudes from the metal pipe column and is bent downward.
The claim is characterized in that the load means applies a tensile force for suspending a weight from the lower end of the wire, and by cutting the wire to shift to a no-load state, the wire is naturally dropped from the hook. Item 1. The free vibration test apparatus according to item 1. This is a free vibration test method for confirming the free vibration characteristics of metal pipe columns.
A wire is attached to the point of action of a metal pipe column erected in the approximately vertical direction, and this is stretched in the approximately horizontal direction and suspended approximately vertically downward via a pulley.
By applying a tensile force from the lower end of the wire, the metal tube column is bent through the action point, and then the metal tube column is moved to a no-load state to vibrate the metal tube column.
A free vibration test method for a metal pipe column, which comprises measuring an acceleration response in a substantially horizontal direction of the vibration in the metal pipe column.

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