JP2011038817A - Frequency variable fatigue testing device using electrically operated vibration generator - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a frequency variable fatigue testing device using an electrically operated vibration generator targeting a mold material of a ground coil for a superconducting magnetically levitated railroad, and making a fatigue test by applying a bend fatigue load to a material test piece by an electrically operated vibration generator as a drive source. <P>SOLUTION: The frequency variable fatigue testing device using an electrically operated vibration generator is equipped with: the electrically operated vibration generator 12 that energizes current at an optional frequency to a movable coil placed in a magnetic field environment by an excitation coil to generate linear vibration; a movable section 14 disposed at an upper portion of the electrically operated vibration generator 12; and a tool 18 for exciting test pieces including a link mechanism 17 composed at both the sides of a test piece 16 made of made of a mold material of a ground coil for a magnetically levitated railroad disposed at an upper portion of the movable section 14. <P>COPYRIGHT: (C)2011,JPO&INPIT

Description

  The present invention relates to a variable frequency fatigue testing apparatus using an electrodynamic vibration generator, and in particular, electrodynamic vibration for a molded resin material (hereinafter referred to as a mold material) of a magnetic levitation railway ground coil. The present invention relates to a frequency variable fatigue test apparatus using a generator.

  Conventionally, a ground coil in a superconducting magnetic levitation railway is placed in an environment where it is placed outdoors exposed to rain and wind and is subjected to electromagnetic excitation when passing through a high-speed train equipped with a superconducting magnet (Patent Document 1, below). 2).

JP 2006-262542 A JP 2008-295240 A

Factory Mart Japan homepage (http://www.fa-mart.co.jp/instron/03.html)

  As described above, for superconducting magnetically levitated railway ground coils that require long-term outdoor use, it is extremely important to evaluate the strength of the molding material that should support the ground coils, and the mechanical and electrical reliability of the actual machine How to prove this is an important issue for the time being. In particular, the high-frequency vibration environment is unique to superconducting magnetically levitated railways, and verification of the frequency dependence of the fatigue strength of polymer materials as viscoelastic behavior is essential for the strength design of such ground coils. It is.

On the other hand, currently used material fatigue test apparatuses are as follows.
(1) Baldwin type This is a constant load plane bending fatigue testing machine that generates centrifugal force by rotating an unbalanced pendulum at a constant speed, restrains left and right component forces with leaf springs, and uses only vertical force.

The conventional excitation frequency is fixed at 30 Hz, and the test frequency cannot be changed. Therefore, remodeling to 100 Hz has been attempted, but the structural members cannot withstand vibration acceleration in the resonance region, and changing the excitation frequency to 100 Hz is not expected to be realized with this type of fatigue testing machine.
(2) Hydraulic type Fatigue testing machine that uses hydraulic pressure as the drive source can output a relatively large load. On the other hand, a material with a low elastic modulus such as a resin piece does not follow high-frequency displacement, so it is high at high frequency. No stress is applied.
(3) Linear motor drive type This is an electric fatigue testing machine that uses a linear motor as the drive source. In principle, high frequency is easily output. However, in the case of a material with a low elastic modulus such as a resin piece, The displacement does not follow and high stress cannot be applied (see Non-Patent Document 1 above).

  In view of the above situation, the present invention applies a fatigue test by applying a bending fatigue load to a material specimen using an electrodynamic vibration generator as a driving source for a molding material of a superconducting magnetic levitation railway ground coil. An object of the present invention is to provide a variable frequency fatigue testing apparatus using an electrodynamic vibration generator.

In order to achieve the above object, the present invention provides
[1] In a variable frequency fatigue testing apparatus using an electrodynamic vibration generator, an electrodynamic that generates a linear vibration by energizing a moving coil placed in a magnetic field environment by an exciting coil with a current having an arbitrary frequency. Type vibration generator, movable part disposed above the electrodynamic vibration generator, and both sides of a test piece made of a molded material of a magnetic levitation railway ground coil disposed above the movable part And a test piece vibration jig having a link mechanism.

[2] In the variable frequency fatigue test apparatus using the electrodynamic vibration generator described in [1] above, a bending fatigue load is applied to the test piece by a test piece vibration jig having the link mechanism. Features.
[3] A variable frequency fatigue testing apparatus using the electrodynamic vibration generator according to [1] above, wherein the movable part includes a vibration accelerometer.

  [4] In the variable frequency fatigue test apparatus using the electrodynamic vibration generator according to [1], a load converter is provided between the movable part and the test piece vibration jig. To do.

  According to the present invention, the test piece of the ground material for the superconducting magnetic levitation railway ground coil can be vibrated at an arbitrary frequency, so the frequency dependence of the fatigue strength is verified and the strength of the ground coil is designed. Can contribute.

It is a schematic diagram which shows the operation | movement principle of the electrodynamic type vibration generator which concerns on this invention. It is a schematic diagram of a fatigue test apparatus for a molded material of a magnetic levitation railway ground coil using an electrodynamic vibration generator according to an embodiment of the present invention. It is a characteristic view of the generated strain of the test piece with respect to the set load of the electrodynamic vibration generator showing the embodiment of the present invention. It is a drawing substitute photograph which shows the fatigue test apparatus of the molding material of the magnetic levitation type railway ground coil using the electrodynamic type vibration generator of this invention.

  The variable frequency fatigue testing apparatus using the electrodynamic vibration generator of the present invention is an electrodynamic that generates a linear vibration by energizing a movable coil placed in a magnetic field environment by an exciting coil with a current having an arbitrary frequency. Type vibration generator, movable part disposed above the electrodynamic vibration generator, and both sides of a test piece made of a molded material of a magnetic levitation railway ground coil disposed above the movable part And a test piece vibration jig having a link mechanism.

Hereinafter, embodiments of the present invention will be described in detail.
FIG. 1 is a schematic diagram showing an operation principle of an electrodynamic vibration generator according to the present invention, FIG. 1 (a) shows a current waveform applied to a movable part coil, and FIG. 1 (b) shows an electrodynamic type. It is a schematic diagram which shows the generation principle of the force by the electromagnetic force of a vibration generator.
In FIG. 1, 1 is a vibration generator main body, 2 is a lower excitation coil, 3 is an upper excitation coil, 4 is a movable part coil capable of supplying an arbitrary current, and 5 is a movable part.

When a current having a waveform as shown in FIG. 1A is supplied to the movable part coil 4, the movable part 5 rises in the case of a positive current, and the movable part 5 falls in the case of a negative current. That is, when a sine wave is supplied, the movable part 5 vibrates linearly in the up and down direction. In addition, the frequency supplied to the movable part coil 4 can be made variable.
FIG. 2 is a schematic view of a fatigue test apparatus for a magnetic levitation railway ground coil mold material using an electrodynamic vibration generator according to an embodiment of the present invention.

  In this figure, 11 is a fixed part of the electrodynamic vibration generator, 12 is a vibration generator body, and 13 is a vibration isolator disposed between the fixed part 11 of the electrodynamic vibration generator and the vibration generator body 12. A spring, 14 is a movable part arranged on the upper part of the vibration generator main body 12, 15 is a vibration accelerometer mounted on the movable part 14, 16 is a test piece made of a molded material of a magnetic levitation railway ground coil, and 18 is A test piece vibration jig 19 having a link mechanism 17 is a strain gauge affixed to the test piece 16, and is used to preliminarily determine the vibration conditions. Reference numeral 20 denotes a load converter disposed at a connecting portion between the movable portion 14 and the test piece vibration jig 18 for controlling the load applied to the test piece 16 to be constant.

By driving the electrodynamic vibration generator, the movable portion 14 vibrates linearly in the vertical direction. Then, the vibration is transmitted to the test piece vibration jig 18 having the link mechanism 17, and a bending fatigue load can be applied to the test piece 16, and a material fatigue test can be performed.
FIG. 3 is a characteristic diagram of the generated strain of the test piece with respect to the set load of the electrodynamic vibration generator according to the embodiment of the present invention. FIG. 3 (a) is 30 Hz, FIG. 3 (b) is 70 Hz, and FIG. FIG. 3C is a strain (μ) characteristic diagram of the test piece with respect to a set load (N) when driven at 100 Hz and FIG. 3D, respectively.

From these figures, it can be seen that the strain with respect to the load at each frequency has linearity. That is, it can be seen that the electrodynamic vibration generator of the present invention functions effectively as a frequency variable fatigue test apparatus.
FIG. 4 is a drawing-substituting photograph showing a fatigue test apparatus for a magnetic levitation railway ground coil mold material using the electrodynamic vibration generator of the present invention.

In this figure, 21 is a vibration generator main body, 22 is a movable part, 23 is a vibration accelerometer mounted on the movable part 22, 24 is a load transducer, and 25 is a test made of a molded material of a magnetic levitation railway ground coil. It is a piece.
Because it is configured in this way, bending fatigue load can be applied to the material test piece via the test piece vibration jig using the electrodynamic vibration generator, and the frequency dependence in the fatigue strength is verified, It can be used for the strength design of the ground coil.

  In addition, this invention is not limited to the said Example, Based on the meaning of this invention, a various deformation | transformation is possible and these are not excluded from the scope of the present invention.

  The variable frequency fatigue test apparatus using the electrodynamic vibration generator of the present invention is directed to a superconducting magnetic levitation railway ground coil mold material, using the electrodynamic vibration generator as a drive source during a fatigue test. The present invention can be used as a fatigue test apparatus capable of applying a bending fatigue load to a material test piece via a test piece vibration jig having a link mechanism.

DESCRIPTION OF SYMBOLS 1, 12, 21 Vibration generator main body 2 Lower excitation coil 3 Upper excitation coil 4 Movable part coil 5, 14, 22 Movable part 11 Fixed part 13 Anti-vibration spring 15, 23 Vibration accelerometer 16, 25 Magnetically levitated railway ground Test piece made of coil molding material 17 Link mechanism 18 Test piece vibration jig 19 Strain gauge 20, 24 Load transducer

Claims (4)

(A) an electrodynamic vibration generator for energizing a moving coil placed in a magnetic field environment by an exciting coil with a current having an arbitrary frequency to generate a linear vibration;
(B) a movable part disposed at the top of the electrodynamic vibration generator;
(C) It comprises a test piece vibration jig having a link mechanism configured on both sides of a test piece made of a molding material of a magnetic levitation railway ground coil disposed above the movable portion. A variable frequency fatigue testing device using an electrodynamic vibration generator.   2. The variable frequency fatigue test apparatus using the electrodynamic vibration generator according to claim 1, wherein a bending fatigue load is applied to the test piece by a test piece vibration jig having the link mechanism. Frequency variable fatigue testing equipment using an electric vibration generator.   2. The variable frequency fatigue testing apparatus using the electrodynamic vibration generating apparatus according to claim 1, wherein the movable part is provided with a vibration accelerometer.   The frequency variable fatigue test apparatus using the electrodynamic vibration generator according to claim 1, further comprising a load converter between the movable part and the test piece vibration jig. A variable frequency fatigue tester using a vibration generator.