JP3497631B2 - Vibration isolator for electrical equipment - Google Patents

Description

Detailed Description of the Invention

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a vibration isolator for electric equipment, which is in a state where it can be transported with the vibration isolating rubber attached to the bottom of the electric equipment body.

[0002]

2. Description of the Related Art FIGS. 10 and 11 show a conventional simple vibration isolator for electric equipment. In the vibration isolator for electric equipment, the base 3 is arranged below the base metal fitting 2 of the electric equipment main body 1, and the base hole 4 of the base metal fitting 2 is arranged.
Corresponding to the above, a full-screw type stud bolt 5 is screwed into the screw hole 3a of the laying base 3 to stand upright. The stud bolt 5 is fixed to the base 3 with a lock nut 6,
The tip of the stud bolt 5 is inserted into the base hole 4. An annular first anti-vibration rubber 7 is arranged on the outer periphery of the stud bolt 5 between the spread base 3 and the base metal fitting 2. Annular metal fittings 7a are integrally attached to both ends of the first vibration-proof rubber 7 in the vertical direction. Between the stud bolt 5 and the base hole 4, the tubular portion 8a of the annular second vibration-proof rubber 8 is arranged on the outer periphery of the stud bolt 5, and
A flange portion 8b having an outer diameter larger than the inner diameter of the base hole 4 is provided on the upper part of the vibration isolating rubber 8, and the flange portion 8b is placed on the base metal fitting 2. At the portion of the stud bolt 5 that has penetrated the base metal fitting 2, the nut 9 has a washer 10
It is screwed through.

In such a conventional simple type vibration isolator for electric equipment, when the vertical vibration generated during transportation is applied, the
Since it is not possible to prevent the plastic deformation of the anti-vibration rubber 7 of the above, in the case of transportation with the first anti-vibration rubber 7 attached, a spacer 11 such as wood is placed between the laying base 3 and the base metal fitting 2. The first anti-vibration rubber 7 that limits the longitudinal vibration that occurs during transportation.
Was protecting.

However, in the method of limiting the vibration by using the spacer 11 as described above, the spacer 11 having a required thickness at the time of transportation must be prepared in advance and inserted at the time of transportation, and also the arrival at the site. There is a troublesome problem that the spacer 11 must be removed before the post-installation.

As an anti-vibration device for electric equipment, which has solved such problems, there is also an anti-vibration device for electric equipment shown in FIG. In this vibration isolator for electrical equipment, the first vibration isolation rubber 7
Stopper bolts 12 are erected on the laying base 3 on both sides of the base metal fitting 3, and these stopper bolts 12 penetrate the base metal fitting 2 in the vertical direction. It has been proposed that these stopper nuts 13 limit the vertical vibration applied to the first anti-vibration rubber 7 during transportation.

[0006]

However, in the vibration isolator in which the plurality of stopper bolts 12 are provided around the first anti-vibration rubber 7, the structure becomes complicated.

An object of the present invention is to provide a vibration isolator for electric equipment which has a simple structure and can limit the vertical vibration applied to the vibration isolator during transportation.

Another object of the present invention is to provide an anti-vibration device for electric equipment which has a simple structure and can limit the longitudinal vibration applied to the anti-vibration rubber during transportation and can protect the anti-vibration rubber against lateral vibration during transportation. To provide.

Another object of the present invention is to provide a vibration isolator for electric equipment which has a simple structure and which can limit longitudinal vibration applied to the vibration isolator rubber during transportation and can suppress slippage of the electric equipment body against lateral vibration during transportation. To provide a device.

[0010]

According to the present invention, a laying base is arranged under a base metal fitting of an electric equipment body, and a stud bolt is erected on the laying base corresponding to a base hole of the base metal fitting. Is fixed to the laying base with a lock nut, the tip of the stud bolt is inserted into the base hole, and an annular anti-vibration rubber is placed on the outer periphery of the stud bolt between the laying base and the base metal fitting and penetrates the base metal fitting. The object of the improvement is an anti-vibration device for electric equipment in which a nut is screwed on the stud bolt.

The present invention is characterized in that a stopper member is provided which is supported by a stud bolt in the vibration isolating rubber and limits the compression of the vibration isolating rubber within the elastic limit of the vibration isolating rubber.

As described above, when the stopper member for supporting the compression of the vibration isolating rubber within the elastic limit of the vibration isolating rubber by being supported by the stud bolt in the vibration isolating rubber is provided, the antivibration rubber during transportation by the stopper member. It is possible to limit the vertical vibration applied to. Therefore, it is not necessary to provide a plurality of stopper bolts around the vibration isolating rubber as in the conventional case, and the structure of the vibration isolating device can be simplified.

The stopper member is composed of a lock nut screwed to the stud bolt, and the height of the lock nut is set to a height that limits the compression of the vibration isolating rubber to within the elastic limit of the vibration isolating rubber. It is preferable.

As described above, when the stopper member is composed of the lock nut screwed to the stud bolt, the stopper member can be implemented without increasing the number of parts.

The height of the lock nut may be set to a height lower than the height of the anti-vibration rubber when the anti-vibration rubber is set and a static load is applied to the main body of the electric device by an allowable amplitude. preferable.

As described above, when the height of the lock nut is set to a height lower than the height of the anti-vibration rubber when the anti-vibration rubber is set and the static load of the main body of the electric device is applied, by an allowable amplitude. The longitudinal vibration applied to the vibration isolating rubber during transportation can be limited within the range of the allowable amplitude of the vibration isolating rubber.

It is preferable that the outer diameter of the lock nut is set smaller than the inner diameter of the anti-vibration rubber, and the outer diameter of the lock nut is set larger than the inner diameter of the base hole.

As described above, when the outer diameter of the lock nut is set smaller than the inner diameter of the anti-vibration rubber, the anti-vibration rubber can be easily attached to the lock nut and the anti-vibration rubber is tightly fitted to the outer periphery of the lock nut. The anti-vibration rubber exhibits better performance in anti-vibration properties than the conventional ones. Also, if the outer diameter of the lock nut is set larger than the inner diameter of the base hole,
It is possible to reliably prevent the lock nut from penetrating the base hole of the base fitting.

The stopper member may have a structure integrally formed with the stud bolt.

As described above, when the stopper member is formed integrally with the stud bolt, there are advantages that the number of parts is reduced and the assembly is easy.

The stud bolt may be welded to the laying base while being screwed to the laying base.

As described above, when the stud bolt is screwed to the spread base and is welded to the spread base,
It is possible to prevent the stud bolt from loosening during use and changing the height of the stopper member.

The distance between the inner circumference of the vibration isolating rubber and the outer circumference of the stopper member or the lock nut is preferably set to a dimension that can limit the deviation of the vibration isolating rubber in the shearing direction against lateral vibration.

As described above, if the distance between the inner circumference of the vibration isolating rubber and the outer circumference of the stopper member or the lock nut is set to a dimension that can limit the deviation of the vibration isolating rubber in the shearing direction against lateral vibration, the lateral vibration during transportation can be reduced. The anti-vibration rubber can be protected from vibration.

A vibration-proof rubber tube or vibration-proof sleeve is arranged on the outer circumference of the stud bolt in the base hole, and the distance between the outer circumference of the vibration-proof rubber tube or vibration-proof sleeve and the inner circumference of the base hole is set. It is preferable that the size is set so as to limit the slip of the electric device main body against lateral vibration.

As described above, the vibration-proof rubber tube portion or the vibration-proof sleeve is disposed on the outer circumference of the stud bolt in the base hole, and the outer circumference of the vibration-proof rubber tube portion or the vibration-proof sleeve and the inner circumference of the base hole are arranged. If the distance between and is set to a dimension that can limit the slip of the electric device body against lateral vibration, the range in which the electric device body slips against lateral vibration during transportation can be limited.

[0027]

1 to 5 (A) and (B) show a first example of an embodiment of a vibration isolator for electric equipment according to the present invention. The parts corresponding to those in FIG. 11 described above are denoted by the same reference numerals.

In the vibration isolator for electric equipment of this example, the laying base 3 is arranged below the base metal fitting 2 of the electric equipment main body 1, and the screw holes of the laying base 3 corresponding to the base holes 4 of the base metal fitting 2. A stud bolt 5 of a total screw type is screwed into the 3a to stand upright. An annular first anti-vibration rubber 7 is arranged on the outer periphery of the stud bolt 5 between the spread base 3 and the base metal fitting 2. Annular metal fittings 7a are integrally attached to both ends of the first vibration-proof rubber 7 in the vertical direction. A stopper member 14 is provided which is supported by the stud bolts 5 in the first anti-vibration rubber 7 and limits the compression of the first anti-vibration rubber 7 within the elastic limit of the first anti-vibration rubber 7. There is. The stopper member 14 is composed of a lock nut 6 screwed to the stud bolt 5 in this example. The stud bolt 5 is fixed to the floor base 3 by the lock nut 6. The lock nut 6 has a circular outer surface, and a pair of spanner hooks 6a is provided on the outer periphery of the upper portion thereof. The height x of the lock nut 6 is set to a height that limits the compression of the first vibration isolating rubber 7 within the elastic limit of the first vibration isolating rubber 7. Also, in this example,
The distance between the inner circumference of the annular first vibration-proof rubber 7 and the outer circumference of the lock nut 6 is set to a size that can limit the deviation of the first vibration-proof rubber 7 in the shearing direction against lateral vibration. The tip of the stud bolt 5 is inserted into the base hole 4. Between the stud bolt 5 and the base hole 4, a cylindrical portion 8a of an annular second anti-vibration rubber 8 is arranged on the outer periphery of the stud bolt 5, and the base hole is provided above the second anti-vibration rubber 8. A flange portion 8b having an outer diameter larger than the inner diameter of 4 is provided, and the flange portion 8b is placed on the base metal fitting 2. The distance between the outer circumference of the cylindrical portion 8a of the second vibration-proof rubber 8 and the inner circumference of the base hole 4 is set to a size that can limit slip of the electric device body 1 against lateral vibration. A nut 9 is screwed onto a portion of the stud bolt 5 penetrating the base fitting 2 via a washer 10.

In particular, in this example, the height x of the lock nut 6 is
Is set several mm lower than the height y of the first anti-vibration rubber 7 including the thickness of the metal fitting 7a when the first anti-vibration rubber 7 is set and the static load of the electric device body 1 is applied. ing. This value is a value that holds the first anti-vibration rubber 7 within its elastic limit.

The outer diameter φE of the lock nut 6 is set to be smaller than the inner diameter φF of the first anti-vibration rubber 7 by several mm, and the outer diameter of the lock nut 6 is set larger than the inner diameter of the base hole 4.

In this way, when the height of the lock nut 6 is set to a height that limits the compression of the first vibration isolating rubber 7 within the elastic limit of the first vibration isolating rubber 7, the lock nut 6 is set. Can be used to limit the amount of compression applied to the first anti-vibration rubber 7 during transportation. Therefore, it is not necessary to provide a plurality of stopper bolts 12 around the first anti-vibration rubber 7 as in the prior art, and the structure of the anti-vibration device can be simplified.

In particular, the height of the lock nut 6 is set such that the first vibration damping rubber 7 is set to include the thickness of the metal fitting 7a when the static load of the electric device body 1 is applied to the first vibration damping rubber. Rubber 7
If the height is set to a height lower than the height of the first vibration-proof rubber by an allowable amplitude, the longitudinal vibration applied to the first vibration-proof rubber 7 during transportation can be limited within the range of the allowable amplitude of the first vibration-proof rubber 7.

Further, as in this example, the gap between the inner circumference of the first vibration-proof rubber 7 and the outer circumference of the lock nut 6 can limit the deviation in the shearing direction of the first vibration-proof rubber 7 against lateral vibration. When the dimensions are set, it is possible to limit the deviation in the shearing direction of the first vibration-proof rubber 7 against lateral vibration during transportation, and at the same time protect the first vibration-proof rubber 7 from lateral vibration during transportation. can do.

Further, as in this embodiment, the cylindrical portion 8a of the second vibration-proof rubber 8 is arranged on the outer periphery of the stud bolt 5 in the base hole 4, and the cylindrical portion 8a of the second vibration-proof rubber 8 is arranged. If the distance between the outer periphery of the electric device body 1 and the inner periphery of the base hole 4 is set to a size that can limit the slip of the electric device body 1 against lateral vibration, the range in which the electric device body 1 slips against lateral vibration during transportation is limited. be able to.

Further, by setting the outer diameter of the lock nut 6 to be smaller than the inner diameter of the first anti-vibration rubber 7, the first anti-vibration rubber 7 can be easily attached to the lock nut 6 and the lock nut 6 can be easily mounted. The performance of the vibration-proof property of the first vibration-proof rubber 7 is better than that of the first vibration-proof rubber 7 which is tightly fitted to the outer periphery of the rubber plate 6.

Further, the outer diameter of the lock nut 6 is set to the base hole 4
If it is set larger than the inner diameter, the lock nut 6 can be surely prevented from penetrating the base hole 4 of the base metal fitting 2.

FIG. 6 shows a second example of the embodiment of the vibration isolator for electric equipment according to the present invention. The parts corresponding to those in FIG. 1 described above are denoted by the same reference numerals.

In the vibration isolator for electric equipment of this example, an example in which a normal bolt is used as the stud bolt 5 is shown. A spring washer 15 is interposed between the lock nut 6 and the laying base 3 by being fitted to the stud bolt 5. An antivibration sleeve 16 made of fluororesin or rubber is fitted on the outer periphery of the stud bolt 5 at a portion passing through the base hole 4 of the base fitting 2 and supported on the lock nut 6. Along with this, the second anti-vibration rubber 8 has a flat annular shape. The distance between the outer circumference of the vibration-proof sleeve 16 and the inner circumference of the base hole 4 is set to a dimension that can limit the slip of the electric device body 1 against lateral vibration. Other configurations are the first
It is similar to the example.

With such a structure, the same effect as the first example can be obtained. Further, by providing the anti-vibration sleeve 16 as in this example, it is possible to prevent the stud bolt 5 and the base metal fitting 2 from coming into contact with each other due to vibration during transportation or use.

Also in the first example, the spring washer 15 can be interposed between the lock nut 6 and the laying base 3 by being fitted to the stud bolt 5. Further, instead of the vibration-proof sleeve 16, the second vibration-proof rubber 8 having the structure shown in FIG. 1 can be used as in the first example.

FIG. 7 shows a third example of the embodiment of the vibration isolator for electric equipment according to the present invention. The parts corresponding to those in FIG. 1 described above are denoted by the same reference numerals.

In the vibration isolator for electric equipment of this embodiment, the stud bolt 5 is welded to the laying base 3 at the welding portion 17 while being screwed onto the laying base 3. Other configurations are similar to those of the second example.

When the stud bolt 5 is screwed to the base 3 in this manner and welded to the base 3 at the welded portion 17, the stud bolt 5 loosens during transportation or use and the stud bolt 5 serving as a stopper member. The height of the can be prevented from changing.

FIG. 8 shows a fourth example of the embodiment of the vibration isolator for electric equipment according to the present invention. The parts corresponding to those in FIG. 1 described above are denoted by the same reference numerals.

In the vibration isolator for electric equipment of this example, the stopper member 14 is formed integrally with the stud bolt 5.

When the stopper member 14 is formed integrally with the stud bolt 5 as described above, the number of parts is reduced and the assembly is easy.

FIG. 9 shows another example of the stud bolt 5 used in the vibration isolator for electric equipment according to the present invention.

The stud bolt 5 is screwed only at the fitting portion of the second vibration-proof rubber 8 having the structure as in the first example or the vibration-proof sleeve 16 having the structure as shown in FIGS. 6, 7, and 8. The absence portion 5a is provided.

By providing the stud bolt 5 with the threadless portion 5a in this manner, it is possible to prevent the second vibration-proof rubber 8 or the vibration-proof sleeve 16 from being cracked by the screw of the stud bolt 5 due to vibration during transportation. You can

The constituent features of some of the plurality of inventions described in the present specification will be described below.

(1) A laying base is arranged under a base metal fitting of an electric equipment body, and a stud bolt is erected on the laying base corresponding to a base hole of the base metal fitting, and the tip of the stud bolt is the base. An annular first anti-vibration rubber is inserted into the hole between the laying base and the base metal fitting, and an annular first anti-vibration rubber is arranged between the stud bolt and the base hole. A vibration isolating device for an electric device, wherein an annular second vibration isolating rubber tubular part or a vibration isolating sleeve is arranged on an outer periphery, and a nut is screwed into a portion of the stud bolt penetrating the base metal fitting, A stopper member is provided, which is supported by the stud bolt in the first vibration isolating rubber and limits the compression of the first vibration isolating rubber within the elastic limit of the first vibration isolating rubber. An anti-vibration device for electric equipment, which is characterized in that

(2) The stopper member is composed of a lock nut screwed to the stud bolt, and the height of the lock nut causes the compression of the first anti-vibration rubber to be elastic. The antivibration device for electric equipment according to (1) above, wherein the height is set within a limit.

(3) The height of the lock nut is greater than the height of the first anti-vibration rubber when the first anti-vibration rubber is set and a static load is applied to the main body of the electric device. The vibration isolation device for electric equipment according to (2) above, wherein the vibration isolation device is set to a height lower by an amount corresponding to the above.

(4) The outer diameter of the lock nut is set smaller than the inner diameter of the first vibration-proof rubber, and the outer diameter of the lock nut is set larger than the inner diameter of the base hole. The vibration isolator for electric equipment according to (2) or (3) above.

(5) The vibration isolator for electric equipment as described in (1) above, wherein the stopper member is formed integrally with the stud bolt.

(6) The electric machine according to any one of (1) to (5), wherein the stud bolt is welded to the laying base while being screwed to the laying base. Anti-vibration device for equipment.

(7) The distance between the inner circumference of the first anti-vibration rubber and the outer circumference of the stopper member or the lock nut is such that displacement in the shearing direction of the first anti-vibration rubber against lateral vibration can be limited. The vibration-damping device for electric equipment according to any one of (1) to (6) above.

(8) The distance between the outer circumference of the second vibration-proof rubber or the outer circumference of the vibration-proof sleeve and the inner circumference of the base hole is set to a size that can limit slip of the electric device body against lateral vibration. The above (1) characterized in that it is set
The vibration-damping device for electric equipment according to any one of to (7).

[0059]

In the vibration isolator for electric equipment of the present invention, since the stopper member is provided which is supported by the stud bolt in the anti-vibration rubber to limit the compression of the anti-vibration rubber within the elastic limit of the anti-vibration rubber. The stopper member can limit the vertical vibration applied to the vibration isolating rubber during transportation. Therefore, it is not necessary to provide a plurality of stopper bolts around the anti-vibration rubber as in the prior art, the structure of the anti-vibration device can be simplified, and the cost can be reduced.

If the stopper member is composed of a lock nut screwed into the stud bolt, it can be carried out without increasing the number of parts.

Further, if the height of the lock nut is set to a height lower than the height of the anti-vibration rubber when the anti-vibration rubber is set and the static load of the main body of the electric device is applied, the height of the anti-vibration rubber is set by It is possible to limit the longitudinal vibration applied to the vibration isolating rubber within the range of the allowable amplitude of the vibration isolating rubber.

Further, by setting the outer diameter of the lock nut smaller than the inner diameter of the anti-vibration rubber, it becomes easy to attach the anti-vibration rubber to the lock nut, and the anti-vibration rubber is tightly fitted to the outer periphery of the lock nut. The anti-vibration rubber exhibits better performance in anti-vibration properties than the conventional ones.

If the outer diameter of the lock nut is set larger than the inner diameter of the base hole, it is possible to reliably prevent the lock nut from penetrating the base hole of the base fitting.

Further, if the stopper member is formed integrally with the stud bolt, the number of parts is reduced and the assembly is easy.

Further, when the stud bolt is screwed to the spread base and welded to the spread base, it is possible to prevent the stud bolt from loosening and changing the height of the stopper member during transportation or use.

Further, if the distance between the inner circumference of the vibration isolating rubber and the outer circumference of the stopper member or the lock nut is set to a size that can limit the deviation of the vibration isolating rubber in the shearing direction against the lateral vibration, the lateral vibration during transportation will be reduced. The anti-vibration rubber can be protected.

Further, a vibration-proof rubber tube or vibration-proof sleeve is arranged on the outer circumference of the stud bolt in the base hole, and the outer circumference of the vibration-proof rubber tube or vibration-proof sleeve and the inner circumference of the base hole are arranged. If the interval is set to a dimension that can limit the slip of the electric device body against lateral vibration, the range in which the electric device body slips against lateral vibration during transportation can be limited.

[Brief description of drawings]

FIG. 1 is a vertical cross-sectional view of a first example of an embodiment of an anti-vibration device for electric equipment according to the present invention.

FIG. 2 is a side view showing a state in which a stud bolt is erected on the spread base in the first example.

FIG. 3 is a side view showing a state in which a lock nut is screwed onto the stud bolt of FIG.

4A and 4B are a plan view and a side view of a first anti-vibration rubber used in the first example.

5A and 5B are a plan view and a side view of a second anti-vibration rubber used in the first example.

FIG. 6 is a vertical cross-sectional view of a second example of the embodiment of the vibration isolator for electric equipment according to the present invention.

FIG. 7 is a vertical cross-sectional view of a third example of the embodiment of the vibration isolator for electric equipment according to the present invention.

FIG. 8 is a vertical cross-sectional view of a fourth example of the embodiment of the vibration isolator for an electric device according to the present invention.

FIG. 9 is a side view showing another example of the stud bolt used in the present invention.

FIG. 10 is a side view of a conventional simple type vibration isolator for electric equipment.

FIG. 11 is a vertical cross-sectional view of a conventional simple type vibration isolator for electric equipment.

FIG. 12 is a side view of a conventional vibration isolator for electric equipment using a stopper bolt.

[Explanation of symbols]

1 Electric equipment body 2 base metal fittings 3 floor base 4 base hole 5 stud bolt 5a Screwless part 6 lock nuts 6a Spanner hook 7 First anti-vibration rubber 7a metal fittings 8 Second anti-vibration rubber 8a tube 8b Flange part 9 nuts 10 washers 11 Spacer 12 Stopper bolt 13 Stopper nut 14 Stopper member 15 spring washer 16 Anti-vibration sleeve 17 Weld

─────────────────────────────────────────────────── ───Continued from the front page (56) Bibliographic data Sho 59-140418 (JP, U) Sakai flat 2-27709 (JP, U) Sakai 63-39911 (JP, U) (58) Survey Field (Int.Cl. ⁷ , DB name) H01F 27/06

Claims (8)

(57) [Claims] 1. A laying base is arranged under a base metal fitting of an electric equipment main body, and a stud bolt is erected on the laying base corresponding to a base hole of the base metal fitting, and a tip of the stud bolt is provided at the base hole. A ring-shaped anti-vibration rubber is arranged on the outer periphery of the stud bolt between the laying base and the base metal fitting, and a nut is screwed onto the portion of the stud bolt penetrating the base metal fitting. In an anti-vibration device for electric equipment, a stopper member is provided which is supported by the stud bolt in the anti-vibration rubber and limits the compression of the anti-vibration rubber within the elastic limit of the anti-vibration rubber. Anti-vibration device for electrical equipment. 2. The stopper member is composed of a lock nut screwed to the stud bolt, and the height of the lock nut is such that the compression of the vibration isolating rubber is restricted within the elastic limit of the vibration isolating rubber. The anti-vibration device for electric equipment according to claim 1, wherein 3. The height of the lock nut is set to a height lower by an allowable amplitude than the height of the anti-vibration rubber when the anti-vibration rubber is set and the static load of the electric device body is applied. The anti-vibration device for electric equipment according to claim 2, wherein 4. The outer diameter of the lock nut is set smaller than the inner diameter of the anti-vibration rubber, and the outer diameter of the lock nut is set larger than the inner diameter of the base hole. 3. A vibration control device for electric equipment according to item 3. 5. The vibration isolator for electric equipment according to claim 1, wherein the stopper member has a structure formed integrally with the stud bolt. 6. The vibration isolator for an electric device according to claim 1, wherein the stud bolt is welded to the laying base while being screwed to the laying base. apparatus. 7. The gap between the inner circumference of the vibration isolating rubber and the outer circumference of the stopper member or the lock nut is set to a size capable of limiting the deviation of the vibration isolating rubber in the shearing direction against lateral vibration. The vibration-damping device for electric equipment according to any one of claims 1 to 6. 8. An anti-vibration rubber tube portion or an anti-vibration sleeve is disposed on the outer periphery of the stud bolt in the base hole, and the inner periphery of the anti-vibration rubber tube portion or anti-vibration sleeve and the base hole are arranged. The vibration isolation device for electric equipment according to any one of claims 1 to 7, wherein the distance from the circumference is set to a size that can limit slip of the electric equipment body against lateral vibration.