JP2000234982A - Vibration-testing system - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a vibration-testing system for allowing continuous vibration from low frequency to high one by using a cylindrical coil being incorporated between vibration and grounding-part bodies as an electromagnetic damper. SOLUTION: A cylindrical coil 6 being fixed to a grounding-part body 4 for mounting is incorporated between vibration- and grounding-part bodies 3 and 4 for using as an electromagnetic damper, thus suppressing the vibration of the vibration-part body 3 with the resonance of an elastic support part and the vibration-part body 3, eliminating the need for stopping a vibration test once for suppressing the vibration of the elastic support part as conventionally, and performing the vibration test using a vibration testing system by the same vibration means from a low frequency to a high one.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration test apparatus, and more particularly, to a vibration test apparatus incorporating a cylindrical coil used as an electromagnetic damper.

[0002]

2. Description of the Related Art A vibration test apparatus 21 as an example of a conventional vibration test apparatus will be described below with reference to FIGS.

FIG. 3 is a longitudinal sectional view showing a configuration of a vibration test apparatus 21 as an example of a conventional vibration test apparatus. In FIG. 3, the vibration test apparatus 21 includes a movable part (vibration table).
22, vibrating section main body 23, grounding section main body 24, air spring 2
5, excitation coil 27, drive coil 28, support spring 29,
The grounding section main body 24 is constituted by a fixture 31 and is placed on the floor (earth) 30 so as to be grounded.

In the vibration test apparatus 21, when there is no fixture 31, a vibration phenomenon occurs when the movable section (vibration table) 22 is vibrated by the air spring 25, so that the vibration section main body 23 also generates vibration. .

[0005] Further, since the vibration phases of the movable section (vibration table) 22 and the vibration section main body 23 are in an opposite phase, only the vibration section main body 23 vibrates greatly, and the movable section (vibration table) 22 It becomes hard to vibrate.

[0006]

However, as shown in FIG. 4, the vibration characteristic of the vibrating portion main body 23 by the air spring 25 is such that the vibration level is low in a low frequency region below the natural vibration frequency and in the vicinity of the natural vibration frequency. It has a vibration frequency characteristic in which the vibration level is high, reaches a maximum value near the natural vibration frequency, and decreases in a high frequency region exceeding the natural vibration frequency.

Therefore, in the vibration test using the conventional vibration test apparatus 21, when the vibration is performed in a low frequency region below the natural vibration frequency of the air spring 25 and in the vicinity of the natural vibration frequency, the grounding unit main body 24 and the floor (earth) are used. 30 has a problem that it vibrates greatly, and it is difficult to vibrate from a low frequency.

For this reason, by using the fixing member 31 so as not to vibrate the air spring 25 only in a low frequency region where the vibration level of the air spring 25 is high and lower than the natural vibration frequency and in the vicinity of the natural vibration frequency, The transmission of the vibration to the floor 24 and the floor (earth) 30 is suppressed, and in the high frequency region where the vibration level of the air spring 25 is lower than the natural vibration frequency, the air spring 25 is vibrated without using the fixture 31. Was.

Therefore, a mechanism for fixing the air spring 25 and complicated vibration control are required, and continuous vibration from low frequency to high frequency cannot be performed. Had to stop.

The present invention solves such a problem by using a cylindrical coil incorporated between the vibrating section main body 23 and the grounding section main body 24 as an electromagnetic damper to reduce the frequency from low frequency to high frequency. An object of the present invention is to provide a vibration test device that enables continuous excitation.

[0011]

According to the first aspect of the present invention,
A vibrating section main body having a DC magnetic field to be excited by an exciting coil supplied with a DC current, a vibrating table provided with a drive coil for generating vibration in a magnetic field generated by the exciting coil, and the vibrating section; A grounding portion main body that has an elastic supporting portion that supports a part of the main body via an elastic member, and that is grounded through the elastic supporting portion, wherein the vibration of the drive coil is caused by a DC magnetic field excited by the exciting coil. In a vibration test apparatus that vibrates the vibrating table in a predetermined vibration frequency band by continuously changing the frequency, a damper is further fixed to a position of the grounding section main body facing the vibrating section main body, and When the vibration frequency is in a predetermined low frequency region, the vibration displacement generated in the vibrating portion main body is applied to the grounding portion main body through the damper, and the vibration frequency of the vibration table is in a predetermined high frequency region. Characterized by being configured to act on the grounding body via the elastic support portion of the vibration displacement generated in the pressurized Fubu body.

According to the vibration test apparatus of the present invention, when the vibration frequency of the vibrating table is in a predetermined low frequency range, the vibration displacement generated in the vibrating section main body is connected to the ground via the damper. When the vibration frequency of the vibrating table is in a predetermined high frequency range, the vibration displacement generated in the vibrating section main body is applied to the grounding section main body via the elastic support section.

Therefore, it is not necessary to temporarily stop the vibration test to suppress the vibration of the elastic support portion as in the prior art, and the vibration test can be performed by the vibration test apparatus from the low frequency to the high frequency using the same vibration means. . Further, even in a low frequency region where a substantial vibration test is difficult in a conventional vibration test apparatus, a damping force generated by a vibration displacement generated in the vibrating section main body is applied to the grounding section main body via the damper. By acting, a large displacement and speed can be obtained in the vibrating section main body, and a vibration test by a vibration test device can be performed in a wide vibration frequency range. Further, a vibration test can be performed without requiring a mechanism for fixing the elastic support portion or complicated vibration control.

According to a second aspect of the present invention, in the vibration test apparatus according to the first aspect, the vibrating portion main body forms a magnetic pole using at least a portion facing the damper as a magnetic member, and the grounding damper is provided with a magnetic pole. It is formed of an exciting coil, and the exciting section side magnetic pole and the grounding section main body side exciting coil constitute an electromagnetic damper.

According to a second aspect of the present invention, the vibrating portion main body has a magnetic pole formed by using at least a portion facing the damper as a magnetic member, and the grounding damper is formed by an exciting coil. By forming an electromagnetic damper with the exciting section main body side magnetic pole and the grounding section main body side exciting coil, when the vibration frequency of the shaking table is in a predetermined low frequency region, vibration displacement generated in the exciting section main body is reduced. It acts on the grounding section main body through the damper.

Therefore, it is possible to easily configure an electromagnetic damper that applies a damping force generated by the vibration displacement generated in the vibrating section main body to the grounding section main body.

[0017]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, an embodiment of a vibration test apparatus according to the present invention will be described in detail with reference to FIGS.
First, the configuration will be described.

FIG. 1 is a longitudinal sectional view showing the structure of a vibration test apparatus 1 according to one embodiment of the present invention. In FIG. 1, a vibration test apparatus 1 includes a movable part (vibration table) 2, a vibrating part main body 3, a grounding part main body 4, an air spring 5, a cylindrical coil 6,
Cylindrical coil connecting portion 6a, cylindrical coil gap 6b,
An excitation coil 7, a drive coil 8, a support spring 9, and a floor (earth) 10 are provided, and the grounding section main body 4 is placed on the floor (earth) 10.

The structure of the vibration test apparatus 1 is basically the same as the structure of the conventional vibration test apparatus 21. However, as shown in FIG. By incorporating the cylindrical coil 6 fixed and attached to the grounding section main body 4 via the cylindrical coil connecting section 6a and using this as an electromagnetic damper, the vibrating section main body 3 and the air spring 5
The point that the vibration of the vibrating section main body 3 is suppressed by the resonance with the above is a novel point of the present invention. Note that FIG.
The same components as those of the vibration test apparatus 21 shown in FIG.

The vibrating section main body 3 is a magnetic body that stores a main part of the vibration test apparatus 1 and is magnetized by an exciting coil 7 stored therein. Further, it has an annular drive coil 8 formed along the cylinder at the lower end of the movable section (vibration table) 2. A drive coil gap 8 formed between the upper end of the vibrating section main body 3 and the drive coil 8.
In b, a DC magnetic field is formed.

As shown in FIG. 1, the drive coil 8 is a coil fixed to the lower end of the movable portion (vibration table) 2 in the drive coil gap 8b. The drive coil 8, the exciting current from the drive circuit (not shown) is input, the current I flowing through each coil, the inner coil flux Bi and outer coil magnetic flux B _o is generated.

The drive coil 8 is disposed at the lower end of the movable section (vibration table) 2 so as to cause vertical vibration together with the movable section (vibration table) 2 in the magnetic field generated in the drive coil gap 8b by the excitation coil 7. Drive coil 8
When a DC current flows through the drive coil gap 8b, the current acts on a DC magnetic field formed in the drive coil gap 8b to generate an AC force, and the movable portion (vibration table) 2 vibrates up and down.

The movable portion (vibration table) 2 is supported by the central portion 3a of the vibrating portion main body by a support spring 9 so that FIG.
It becomes possible to vibrate in the vertical direction indicated by the arrow A in the middle. And
On the upper surface of the movable section (vibration table) 2, a test object is installed.

As shown in FIG. 1, the vibration test apparatus 1 according to the present embodiment is mounted on the surface of the grounding section main body 4 facing the bottom of the vibration section main body 3 via the cylindrical coil connecting section 6a. A fixed cylindrical coil 6 is incorporated.

Next, the operation will be described.

When a displacement occurs due to the vibration of the vibrating section main body 3, the relative velocity v between the vibrating section main body 3 and the cylindrical coil 6.
Occurs. The cylindrical coil 6 fixedly attached to the grounding section main body 4 shares the magnetic field generated by the exciting coil 7 in the exciting section main body 3, and thereby, the cylindrical coil 6 is formed in a cylindrical shape with the vibration of the exciting section main body 3. A damping force F proportional to the relative speed v of the coil 6 is generated.

The damping force F for suppressing the vibration of the vibrating section main body 3 is determined by the magnetic flux density B in the gap 6b of the cylindrical coil 6, the effective coil length l of the cylindrical coil 6, and the resistance of the cylindrical coil 6. It is determined by R _C , the attenuation adjustment resistance R, and the relative speed v of the cylindrical coil 6 with respect to the vibrating section main body 3, and has the following equation (1).

[0028]

(Equation 1)

From the relationship of the equation (1), the damping force F for suppressing the vibration of the vibrating section main body 3 is proportional to the relative speed v of the cylindrical coil 6 with respect to the vibrating section main body 3.

Due to the above effects, the damping force F for suppressing the vibration of the vibrating section main body 3 works effectively in a region where the displacement of the vibrating section main body 3 is large. FIG. 2 shows a vibration frequency characteristic of the air spring 5 of the vibration test apparatus 1 according to the present invention in which the cylindrical coil 6 is incorporated. Since the cylindrical coil 6 acts as an electromagnetic damper and suppresses the vibration of the vibrating section main body 3, even in the low frequency region below the natural vibration frequency and in the region near the natural vibration frequency, the ground section main body 4 and the floor ( It is difficult to transmit vibration to the (earth) 10.

In a high frequency region exceeding the natural vibration frequency, the vibration frequency characteristic of the air spring 5 as shown in FIG. The relative speed v of the cylindrical coil 6 with respect to the body 3 also decreases. Therefore, the damping force F for suppressing the vibration of the vibrating section main body 3 decreases in proportion to the relative speed v of the cylindrical coil 6 with respect to the vibrating section main body 3 according to the relationship of the following equation (1). Grounding unit 4 and floor (earth) 1
Vibration is not easily transmitted to zero.

[0032]

(Equation 2)

Therefore, the vibration frequency can be continuously varied from the low vibration frequency region to the high vibration frequency region by the same vibrating means, and the vibration test is temporarily stopped to stop the vibration of the air spring 5 as in the prior art. Vibration test equipment 1 without suppression
Can be performed under appropriate conditions according to the vibration frequency.

Further, since the vibration of the vibrating section main body 3 can be suppressed, even in a low vibration frequency region where a substantial vibration test was difficult with the conventional vibration test apparatus,
A large vibration can be performed, and a vibration test using a vibration test apparatus can be performed in a wide frequency range.

[0035]

According to the first aspect of the present invention, it is not necessary to temporarily stop the vibration test to suppress the vibration of the elastic support portion, unlike the conventional case, and the same vibration means from low frequency to high frequency is used. A vibration test can be performed by a vibration test device. Further, even in a low frequency region where a substantial vibration test is difficult in a conventional vibration test apparatus, a damping force generated by a vibration displacement generated in the vibrating section main body is applied to the grounding section main body via the damper. By acting, a large displacement and speed can be obtained in the vibrating section main body, and a vibration test by a vibration test device can be performed in a wide vibration frequency range. Further, a vibration test can be performed without requiring a mechanism for fixing the elastic support portion or complicated vibration control.

According to the second aspect of the present invention, it is possible to easily configure an electromagnetic damper that applies a damping force generated by a vibration displacement generated in the vibrating portion main body to the grounding portion main body.

[Brief description of the drawings]

FIG. 1 is a longitudinal sectional view showing a structure of a vibration test apparatus 1. FIG.

FIG. 2 is a vibration frequency characteristic of the air spring 5 in the vibration test apparatus 1.

FIG. 3 is a longitudinal sectional view showing the structure of the vibration test device 21.

4 is a vibration frequency characteristic of an air spring 25 in the vibration test device 21. FIG.

[Explanation of symbols]

 DESCRIPTION OF SYMBOLS 1 Vibration test apparatus 2 Movable part (vibration table) 3 Exciting part main body 3a Exciting part main body central part 4 Grounding part main body 5 Air spring 6 Cylindrical coil 6a Cylindrical coil connection part 6b Cylindrical coil gap 7 Exciting coil 8 Drive Coil 8b Drive coil gap 9 Support spring 10 Floor (earth) 21 Vibration tester 22 Movable part (vibration table) 23 Vibration part main body 23a Vibration part main body center part 24 Ground part main body 25 Air spring 28 Drive coil 29 Support spring 30 Floor (earth) 31 Fixture A Vibration direction of movable part (vibration table) C Magnetic field generated by exciting coil

Claims (2)

[Claims] An exciting unit main body having a DC magnetic field excited by an exciting coil supplied with a DC current, and a shaking table provided with a drive coil for generating vibration in a magnetic field generated by the exciting coil. A grounding portion main body that has an elastic supporting portion that supports a part of the vibrating portion main body via an elastic member, and that is grounded through the elastic supporting portion, and a DC magnetic field that is excited by the exciting coil. In a vibration test apparatus that vibrates the vibrating table in a predetermined vibration frequency band by continuously varying a vibration frequency of the drive coil, a damper is further fixed to a position of the grounding section main body facing the vibrating section main body. When the vibration frequency of the vibrating table is in a predetermined low frequency range, the vibration displacement generated in the vibrating section main body acts on the grounding section main body via the damper, and the vibration frequency of the vibrating table increases to a predetermined high frequency. A vibration test apparatus wherein a vibration displacement generated in the vibrating section main body is applied to the grounding section main body via the elastic support section in a frequency range. 2. The vibrating section main body has a magnetic pole formed by using at least a portion facing the damper as a magnetic member, the damper is formed by an exciting coil, and the vibrating section main body side magnetic pole and the grounding section main body side are formed. 2. The vibration test apparatus according to claim 1, wherein an electromagnetic damper is constituted by the exciting coil.