JP4366365B2 - Isolation device - Google Patents

Description

  The present invention relates to a vibration isolator. More specifically, buildings, tanks and other buildings, machinery and equipment, piping, and wiring are attached to foundations, soils, buildings, and other components to absorb earthquakes, mechanical vibrations, and other vibrations, and while wheels are running The present invention relates to a vibration isolator that absorbs vibrations.

The following technique is used for the vibration proofing / vibration control method in the fields of buildings, buildings, machines, piping, and the like (Non-Patent Document 1).
1) To suppress the influence of vibration, such as a damper 2) To be elastically supported for vibration isolation, as a vibration isolator or vibration isolation mount 3) To reduce the response of the vibration body, eliminate rattling and loosening Fastening 4) As an automatic control method, detect vibration input, reduce excitation force and response, or generate reverse force to attenuate

However, the conventional example has the following problems.
The conventional technique 1) uses a damper or the like, so that the apparatus is bulky and the application place is limited in terms of space.
In the conventional technique 2), for example, as shown in FIG. 32, a rubber mount 103 is inserted between a foundation 101 and a mounting member 102 such as a building or a machine, and an anchor bolt 104 and a nut 105 are fastened between the two members. It is a thing.
This rubber mount system can absorb vibrations with small vibrations, but cannot absorb large vibrations, so there is a limit to the vibration-proofing ability, and there is a problem that the rubber mount has a life span and the ability decreases with time.
In the prior art 3), for example, as shown in FIG. 33, an attachment member 102 placed on a foundation 101 is fixed by an uncassette 106. A spring washer 107 is passed through a threaded portion of the uncassette 106 and a nut 108 is used. It is configured to tighten. When the uncassette 106 is fixed to the base 101, a pilot hole is made in the base 101. However, when the pilot hole can be manually or punched, it is not straight due to the material variation of the base. For this reason, the uncassette 106 is often inclined at an angle of θ. In this case, even if the nut 108 is tightened, a gap g is generated, which cannot be securely tightened, and is easily loosened.
Further, as shown in FIG. 34, there is also a method of attaching the piping 110 to the mount 112 attached to the wall surface of the building 111 with a band 113 or the like. Although there is a vibration effect, it cannot exert a great vibration-proofing force, which leads to a pipe rupture accident in the event of an earthquake or the like.
The conventional example of 4) requires a sensor as a vibration detector as a control element, an inertial mass for damping, an actuator as an operating force generator, a servo mechanism for control, a power source, etc. Mechanism. For this reason, it can be used only when there is enough space and cost.
5) Furthermore, none of the prior arts 1) to 4) described above has a compactness that can be incorporated into a wheel or the like and a degree of freedom of incorporation.

Mechanical Engineering Handbook Engineering Chapter C8 Environmental Equipment 207-208 Japan Society of Mechanical Engineers

  In view of the above circumstances, the present invention provides a vibration isolator that is compact and can be easily mounted, can be applied in all technical fields such as buildings and wheels, and has a large vibration absorption capability for its size. For the purpose.

The vibration isolator of the first invention is an inner member attached to the vibration source side member or the vibration body side member, an enclosure member attached to the vibration body side member or the vibration source side member, extrapolated to the inner member, and the enclosure consists of a vibration absorber spring is inserted into the member, the vibration absorbing spring is a coil spring in which the wound shape in a non-circular, in contact with the circumferential direction of the plurality of positions with respect to the outer circumferential surface of the inner member, And it is a spiral wound spring which contacts the inner peripheral surface of the surrounding member at a plurality of locations in the circumferential direction and whose winding shape changes spirally in the longitudinal direction.
The vibration isolator of the second invention is an inner member attached to the vibration source side member or the vibration body side member, an enclosure member attached to the vibration body side member or the vibration source side member, and extrapolated to the inner member, and the enclosure consists of a vibration absorber spring is inserted into the member, the vibration absorbing spring is a coil spring in which the wound shape in a non-circular, in contact with the circumferential direction of the plurality of positions with respect to the outer circumferential surface of the inner member, and are those with respect to the inner peripheral surface of the enclosing member contacts the circumferential direction of the plurality of positions, Ri Oh spiral coil spring whose winding shape is changed spirally in the longitudinal direction, said enclosing member and said vibration absorbing spring Both are concentrically and multiply provided.
In the vibration isolator of the third invention, in the first or second invention, an engagement groove for engaging the vibration absorbing spring is formed on the outer peripheral surface of the inner member and the inner peripheral surface of the surrounding member. Features.
A vibration isolator according to a fourth aspect of the invention is characterized in that, in addition to the vibration isolator according to claim 1 or 2, a spring that absorbs vibration in a direction orthogonal to the vibration absorption direction of the vibration isolator is provided.

According to the first aspect of the present invention, when a vibration external force is applied to the inner member or the surrounding member, the vibration absorbing spring inserted between the inner member and the surrounding member is deformed, and vibration energy is generated by the generation of stress against the deformation. Absorb. Since the vibration absorbing spring is bent and deformed in a sealed space surrounded by the inner member and the surrounding bending member, the absorbed energy can be increased and the vibration absorbing effect is high. In addition, since the winding shape of the vibration absorbing spring is non-circular, the omnidirectional vibration absorption is possible because the vibration absorbing action by deformation is exerted regardless of the radial direction of the external force. And since the winding shape of the vibration absorbing spring changes in a spiral shape in the longitudinal direction, the direction in which the apex generated by forming the non-circular shape comes into contact with the inside of the surrounding member increases, and the vibration external force is increased. Even if it acts from any direction, the deformation of the vibration absorbing spring is equalized, and a high vibration absorbing ability can always be exhibited.
According to the second invention, since the vibration absorbing spring and the surrounding member are multiple, the vibration absorbing capacity is doubled. Moreover, since it is assembled concentrically, it is compact and can be installed in a small space .
According to the third invention, even if a vibration external force in the long axis direction is applied to the vibration absorbing spring, the vibration absorbing spring does not come off from the inner member or the surrounding member, and the vibration absorbing spring is not deformed in the long axis direction. The vibration external force can be absorbed repeatedly. Therefore, it is possible to absorb both vibrations in the major axis direction and the radial direction.
According to the fourth invention, the vibration isolator according to claims 1 and 2 absorbs one vibration, and the vibration in the direction orthogonal thereto, for example, the vibration in the vertical direction with respect to the horizontal direction can be absorbed by another spring. The ability to deal with such issues will increase.

Next, an embodiment of the present invention will be described with reference to the drawings.
FIG. 1 is an explanatory diagram of the basic configuration of the vibration isolator of the present invention, i diagrams (A) and (B) of FIG. 2 are explanatory diagrams of a vibration isolator using a regular wound spring, and ii diagrams (A) and (B). FIG. 3 is an explanatory view of a vibration isolator using a helical spring, and FIG. 3 is an explanatory view of the vibration isolator using an elliptic spring.

(Basic configuration)
First, the basic configuration of the vibration isolator of the present invention will be described based on FIG.
Reference numeral 1 denotes an inner member, which is a member that extrapolates a vibration absorbing spring 3 to be described later and transmits vibration external force to the vibration absorbing spring 3 or receives vibration from the vibration absorbing spring 3. The inner member 1 is a solid member or a hollow member. Examples of solid members include bolts, uncassettes, and axles. Examples of the hollow member include piping such as a gas pipe and wiring pipes. In short, the outer shape may be a circular member or a polygonal member similar to this, and members other than the above examples can be used as long as this requirement is satisfied.
Reference numeral 2 denotes a surrounding member, which is a member that accommodates a vibration absorbing spring 3 to be described later, transmits vibration external force to the vibration absorbing spring 3, and receives vibration from the vibration absorbing spring 3. The surrounding member 2 only needs to have a cylindrical surface or a polygonal surface similar to the cylindrical surface, and the outer peripheral surface may have an arbitrary shape. Further, even if this surrounding member 2 lacks a part in the circumferential direction, it does not have to completely surround the vibration absorbing spring 3 as long as it is in contact with the vibration absorbing spring 3 described above at several points. . In many cases, a cylindrical member is used as the surrounding member 2, but in the case of a wheel, a hollow portion formed in the boss portion is applicable.
3 is a vibration absorbing spring. The vibration absorbing spring 3 is inserted into the inner member 1 and inserted into the surrounding member 2. That is, it is inserted into a space surrounded by the inner member 1 and the surrounding member 2, and is in contact with the inner wall surface and the outer wall surface. The vibration-absorbing spring 3 is a spring having a non-circular winding shape, and a polygon or ellipse that is a triangle or more is used. In short, what is necessary is just to contact the outer peripheral surface of the inner member 1 and the inner peripheral surface of the surrounding member 2 at two or more points. And it is a spirally wound spring whose winding shape changes spirally in the longitudinal direction.

  In the above-described vibration isolator, when the inner member 1 is attached to a vibration source side member (for example, a foundation, a machine that generates or transmits vibration, a building, or the like), the surrounding member 2 is a vibration body side member (for example, a foundation top). Buildings and machinery, piping installed in buildings, etc.). Conversely, when the surrounding member 2 is attached to the vibration source side member, the inner member 1 is attached to the vibration body side.

(Principle of vibration absorption)
Next, the vibration absorption principle will be described.
In FIG. 1B, it is assumed that a vibration external force Fa is applied to the surrounding member 2 now. This vibration external force Fa is directed to a position corresponding to the apex of the triangle of the vibration absorbing spring 3. At this time, the apex of the vibration absorbing spring 3 is pushed by the surrounding member 2 from the normal state of the solid line and is deformed so that the sandwiching angle is widened as shown by the two-dot chain line. The vibration is absorbed by this deformation, and when the vibration external force Fa disappears, the surrounding member 2 is returned to the original position by the elastic force of the vibration absorbing spring 3.
Next, it is assumed that a vibration external force Fb in the opposite direction is applied. The direction of the vibration external force Fb is directed to a straight line portion between two vertices of the vibration absorbing spring 3, and the two vertices on both sides thereof are pushed. In this case, the linear portion of the vibration absorbing spring 3 is curved in an arc shape, and when the vibration is absorbed by this deformation and the vibration external force Fa disappears, the surrounding member 2 is returned to the original position by the restoring force of the vibration absorbing spring 3. .

When a vibration external force is applied from a direction other than Fa and Fb, the two patterns are combined. Therefore, on the plane orthogonal to the major axis direction of the vibration absorbing spring 3, even if an external vibration force from any direction of 360 ° is applied, the vibration absorbing spring 3 is deformed to absorb the vibration. That is, vibration can be absorbed in all directions.
The above explanation of the principle is an example in which a vibration external force is applied to the surrounding member 2, but the same applies when a vibration external force is applied to the inner member 1, and an equivalent vibration absorbing ability can be exhibited.
In order to avoid resonance, the natural frequency of the vibration absorbing spring 3 should be removed as much as possible from the frequency of the assumed external vibration force.

The above vibration absorbing effect is performed by the vibration absorbing spring 3 being bent and deformed in a state of being in close contact with the wall surface in the donut-shaped cylindrical space between the inner wall of the surrounding member 2 and the outer wall of the inner member 1. Since a large force is required compared with bending deformation or the like, a large absorption energy can be obtained for using a small member, and hence a vibration absorbing effect is enhanced.
In addition, the necessary members are only three members, that is, the inner member 1, the surrounding member 2, and the vibration absorbing spring 3, and there is an advantage that it can be manufactured at low cost. Moreover, since it is very compact, it can be applied to a small portion of the mounting space and can be applied to many industrial fields.

Figure 2 is that shows a preferred embodiment of the present invention and a reference example of the vibration absorber spring 3.
The vibration absorbing spring 3 shown in FIGS. i (A) and (B) has a triangular winding shape and has five winding stages. The number of turns may be 4 or less, or 6 or more, depending on the application location. In this specification, the change in the major axis direction of the winding shape is referred to as a winding shape, but this winding shape does not change and is the same in the long axis direction. In other words, the vibration absorbing spring 3 is a fixed spiral spring having a triangular apex at the same position in each step. In contrast to this regular wound spring , the vibration absorbing spring of the present invention has a configuration shown in FIG.
The vibration absorbing spring 3 shown in FIGS. 2A and 2B has a triangular winding shape, and as a winding shape, the top of the spring is slightly shifted in the circumferential direction at each step, and the spiral winding changes spirally. It is a spring. When forming a polygonal (e.g., triangular) winding spring on an anchor bolt, the outer diameter of the winding spring is increased when the anchor bolt is mounted by setting the inner diameter (space) to a slightly smaller dimension. The In this state, the position of the apex of each polygon (for example, a triangle) becomes a spiral, the relationship between the points of contact between the apex of the coil spring and the inner surface of the cylindrical pipe is made uniform, and any horizontal energy can be obtained. Can absorb well. Although this spiral wound spring takes extra time to manufacture, since it contacts the inner wall of the bending member 2 in many angular directions exceeding three directions, the vibration absorption effect is more effective for vibration external force from any direction. There is an advantage that can be played.

  The vibration absorbing spring 3 shown in FIG. 3 is a spiral wound spring that has an elliptical winding shape and has its winding shape changed into a spiral shape and the apex shifted in the circumferential direction for each step of the number of turns. The vibration-absorbing spring 3 has a long-diameter outer end in contact with the inner peripheral surface of the surrounding member 2, and a short-diameter outer peripheral surface in contact with the outer peripheral surface of the inner member 1. Absorb. And since each vertex is scattered radially, the vibration external force in all directions can be absorbed effectively.

Each embodiment of the present invention will be described below.
1st-8th embodiment is a vibration isolator which has the vibration absorption function of the direction which cross | intersects the axial direction of an inner member. That is, when an inner member such as a foundation bolt is upright, the vibration isolator absorbs horizontal vibration.
(First embodiment)
1st Embodiment shown in FIG. 4 is an example which installs a building and a mechanical apparatus on foundation Ba. Am indicates a building such as a building or a tank or a mounting member of a mechanical device.
The inner member in the vibration isolator D of the present embodiment is an anchor bolt 1 and is fixed to the foundation Ba. The spring case 2 which is a surrounding member is a cylindrical member, and is fixed to the attachment member Am. The vibration absorbing spring 3 is placed between the anchor bolt 1 and the spring case 2. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring. As an assembling procedure, a method of inserting the vibration absorbing spring 3 into the anchor bolt 1 and press-fitting the spring case 2 from above can be used.
A rubber mount 21 is placed on the upper surface of the foundation Ba. The rubber mount 21 is used to perform a vibration absorbing function, but is not essential to the present invention. However, when used, there is an advantage that the vibration absorption effect is synergistically increased.

A plate 22 is placed on the upper surface of the rubber mount 21 (the upper surface of the foundation Ba when the rubber mount 21 is not used), and a steel ball 24 is placed between the plate 22 and the lower surface of the surrounding member 2. Further, the plate 23 is placed on the upper surface of the mounting member Am, and the plate 25 is placed with the steel ball 24 interposed therebetween. The upper and lower vibration isolation mechanisms are provided so that the movement of the steel ball 24 in the front-rear and left-right directions is ensured, and the attachment member side does not move together due to the vibration of the foundation Ba. The plates 22, 23, 25 are preferably provided with guide grooves for guiding the steel balls 24.
A nut 4 is screwed to the male screw portion 1a of the head of the anchor bolt 1, and is attached to the foundation Ba of the attachment member Am. Note that if the tightening force of the nut 4 is too strong, the vibration isolation by the steel ball 24 will not be effective, and if it is too weak, the play will increase, so it is important to set an appropriate tightening force.

In this embodiment, when the foundation Ba is shaken due to an earthquake or the like, the roll is transmitted to the vibration absorbing spring 3 via the anchor bolt 1, and the vibration is absorbed by the vibration absorbing spring 3 being deformed as described above. Note that the pitching is absorbed by the rubber mount 21.
As a result of absorbing the vibrations in this way, vibrations can no longer be transmitted to the building or machine connected to the mounting member Am, or the transmitted vibrations can be reduced.

(Second Embodiment)
2nd Embodiment shown in FIG. 5 is also an example which installs a building and a mechanical apparatus via attachment member Am on foundation Ba.
As shown in the drawing, the vibration isolation mechanism is characterized in that it has a double structure of an inner vibration isolation portion Di and an outer vibration isolation portion Do.
The inner vibration isolator Di is composed of an anchor bolt 1, a first spring case 2, and a first vibration absorbing spring 3 that are substantially the same as those in FIG. 4. The anchor bolt 1 is fixed to the foundation Ba, but the first spring case 2 is attached to the attachment member Am via the second spring case 12.
The outer vibration isolation portion Do uses the outer peripheral surface of the first spring case 2 as an inner member, and a second vibration absorbing spring 13 is extrapolated on the outer periphery, and the second spring case 12 is disposed on the outer periphery thereof. An attachment member Am is attached to the second spring case 12. With this structure, the two vibration isolation parts Di and Do are concentrically incorporated in a compact manner.
Both the first vibration-absorbing spring 3 and the second vibration-absorbing spring 13 may be a regular wound spring or a spiral wound spring.

The vibration isolation mechanism is provided at the lower part and the upper part. The lower blocking mechanism includes a plate 22 on the base Ba, a plate 25 on the lower surface of the first spring case 2, and a steel ball 24 therebetween. The upper blocking mechanism includes a plate 26 on the mounting member Am, a plate 27 on the upper surface of the first spring case 2, and an uppermost plate 28, and a steel ball is disposed between the plates. The plates 22, 25, 26, 27, 28 are preferably provided with guide grooves for guiding the steel balls 24. With these blocking mechanisms, the vibration of the foundation Ba is not directly transmitted to the mounting member Am.
Further, a gap x is provided between the second spring case 12 and the lower plate 25. In this case, since the second vibration absorbing spring 13 functions in the same way as a normal compression spring, it is possible to absorb vibrations in the major axis direction of the vibration absorbing springs 3, 13, that is, the vertical direction.

Also in this embodiment, when the foundation Ba is shaken due to an earthquake or the like, the roll is first transmitted to the first vibration absorbing spring 3 via the anchor bolt 1 and then transmitted to the second vibration absorbing spring 13 via the first spring case 2. Since the two first and second vibration absorbing springs 3 and 13 are deformed together to absorb the roll, it is possible to absorb a larger vibration external force as compared with the case of one vibration absorbing portion.
In addition, since all the three members have a concentric structure, they are compact and applicable even in a narrow place.

  The above embodiment is an example in which the first and second spring cases 2 and 12 and the vibration absorbing first and second springs 3 and 13 are configured to be concentric and doubly configured. In this case, it is possible to configure a vibration isolator capable of exhibiting a large vibration absorption force while being relatively compact.

(Third embodiment)
The embodiment shown in FIG. 6 is an example using a ball bolt 1 as an inner member. The spherical bolt 1 has a spherical portion 1b at the lower end of the shaft portion, and is used for an anchor.
A vibration absorbing spring 3 is extrapolated to the outer periphery of the ball bolt 1, and a spring case 2, which is a surrounding member, is extrapolated to the outside thereof. This basic structure is substantially the same as that shown in FIG. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.

An example of use of this embodiment will be described with reference to FIG.
The foundation Ba is made of, for example, concrete, and a spring case 2 in which a ball bolt 1 and a vibration absorbing spring 3 are set is driven and fixed therein. The head of the ball bolt 1 protrudes from the foundation Ba, passes through the hole of the mounting member Am, and the nut 4 is screwed into the screw portion 1a. If the nut 4 is tightened, the mounting member Am is fixed to the foundation Ba, and a building or a mechanical device can be installed.

In this embodiment, when an earthquake occurs and the foundation Ba is shaken, the vibration absorbing spring 3 is deformed to absorb the vibration and not transmit it to the mounting member Am side or reduce it.
Further, when the vibration isolator D is embedded in the concrete base Ba, as shown by the angle θ, even if it is slightly inclined, if the nut 4 is tightened, the vibration absorbing spring 3 is deformed and the ball bolt 1 is made vertical. Therefore, the fixing of the mounting member Am can be ensured.

(Fourth embodiment)
The embodiment shown in FIG. 8 is an example in which piping is attached to a building or other structure.
(I) In the figure, Am is an attachment member, and F is a clamp such as a band.
In this embodiment, the pipe 1 through which piping and wiring are passed is used as it is as the inner member. That is, this pipe is a hollow inner member.
In the piping work, the vibration absorbing spring 3 is extrapolated to the outer periphery of the pipe 1 which is an inner member, the spring case 2 which is a surrounding member is inserted to the outer side, and the outer periphery of the spring case 2 is fastened on the mounting member Am with an appropriate band F. Just do it. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.
Also in this embodiment, vibration transmitted from the building to the pipe 1 due to an earthquake or the like can be absorbed by the vibration absorbing spring 3. Further, it is possible to prevent the vibration on the pipe 1 side from being transmitted to the building or the machine device side.
(Ii) The figure shows the spring case 2 using a structure lacking a part in the circumferential direction, and the spring case 2 is directly attached to the attachment member Am. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.
Also in this embodiment, since the vibration absorbing spring 3 is in contact with the inner periphery of the spring case 2, the vibration from the pipe 1 can be absorbed or the vibration to the pipe 1 can be absorbed.

(Fifth embodiment)
This embodiment is a vibration isolation structure for piping buried in the soil or the like.
In FIG. 9, 1 is a pipe such as a pipe that is an inner member, 2 is a spring case that is a surrounding member, and 3 is a vibration absorbing spring, which is the same as the above embodiments. A protective pipe 5 is buried in the soil G or concrete G, and the pipe 1 is passed through the inside. And the vibration isolator D and D which consist of the spring case 2 and the vibration-absorbing spring 3 are set | placed on the suitable place of the longitudinal direction of the pipe 1 at intervals. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.
In this embodiment, if there is an earthquake or the like, the vibration absorbing spring 3 can absorb the vibration and prevent the pipe 1 from being damaged.

(Sixth embodiment)
This embodiment is also a vibration isolation structure for piping buried in the soil or the like.
As shown in FIG. 10, vibration isolators D and D comprising a spring case 2 and a vibration absorbing spring 3 as a surrounding member are arranged in the soil G with a space in place in the longitudinal direction of the pipe 1 as an inner member. ing. And the protection pipe 5 shown in FIG. 9 is removed by stuffing cushion materials 6, such as rubber | gum, between each vibration isolator D, D. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.
According to this embodiment, both horizontal and vertical vibrations can be absorbed by the vibration absorbing spring 3 and the cushion material 6.

(Seventh embodiment)
This embodiment is also an example of installation of piping buried in the soil or the like.
In FIG. 11, 1 is a pipe which is an inner member, and 2 is a spring case which is a surrounding member. In the present embodiment, two vibration isolators D and D are combined and attached to a joint portion of two pipes 1 and 1 embedded in the soil G. That is, the flanges 1a of the two pipes 1 and 1 are connected to each other by the bolt 1b, and two renewal devices D and D are attached adjacent to the flange 1a. The vibration absorbing spring 3 is inserted into the outer periphery of the pipe 1 inside the spring case 2. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring. It should be noted that the spring case 2 may be sealed with a suitable sealing material so that earth and sand etc. are not put inside.
In this embodiment, there is an advantage that vibration at the weakest joint of the pipe can be absorbed.

(Eighth embodiment)
In the embodiment shown in FIG. 12, the vibration absorbing function in the long axis direction is added to the vibration absorbing function in the radial direction in the vibration absorbing spring 3. As shown in the enlarged views of FIGS. 12 and 13, engagement grooves 7 and 8 are formed in the outer peripheral surface of the inner member 1 and the inner peripheral surface of the surrounding member 2. The vibration absorbing spring 3 is engaged with the engaging grooves 7 and 8. Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used.
Due to this engaging action, even if a vibration external force in the major axis direction (vertical direction in the figure) is applied to the vibration absorbing spring 3, the vibration absorbing spring 3 is not detached from the inner member 1 or the surrounding member 2. Moreover, the vibration absorbing spring 3 can absorb the vibration external force by repeating the bending deformation in the long axis direction. Therefore, in this embodiment, it is possible to absorb both vertical and horizontal (long axis direction and radial direction) vibrations.

The following ninth to fourteenth embodiments are vibration isolation devices having vibration absorbing functions in directions orthogonal to each other by the vibration absorbing spring 3 and another spring. Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used.
(Ninth embodiment)
The ninth embodiment shown in FIGS. 14 and 15 is an example in which a building such as a building or a tank, a mechanical device, or the like is installed on the foundation Ba via a mounting member Am.
The vibration isolation mechanism of the present embodiment is configured by combining a horizontal vibration isolation part D that absorbs horizontal vibrations and a vertical vibration isolation part E that absorbs vertical vibrations.
First, as basic parts of the vibration isolation mechanism, a base bolt 31 attached perpendicularly to the base Ba, an inner cylinder 32 arranged around the base bolt 31, and an outer cylinder 41 fixed to the attachment member Am are provided.

The vertical vibration isolator E is configured as follows.
The lower part of the foundation bolt 31 is fixed with a nut 35 through the foundation Ba or embedded. Further, an inner cylinder 32 is fixed by a nut 36 at a portion of the foundation bolt 31 protruding upward from the foundation Ba. The inner cylinder 32 includes a spring seat 37 and a circular upper plate 38 at its upper end, and a circular lower plate 39 at its lower end. The inner diameter of the inner cylinder 32 is larger than the outer diameter of the foundation bolt 31, and the inside is a spring insertion space. A coil spring 33 is inserted into the spring insertion space. The coil spring 33 has a lower end in contact with the upper surface of the foundation Ba and an upper end in contact with the spring seat 37 of the inner cylinder 32, and absorbs vertical vibrations by a bending action. The coil spring 33 absorbs vibration in the axial direction, but any type of spring may be used as long as it has a similar function.

The horizontal vibration isolator D is configured as follows.
The outer cylinder 41 is attached to the attachment member Am with a bolt 42 or the like. The outer cylinder 41 is a cylindrical member having an inner diameter larger than that of the inner cylinder 32, and has a lower plate 43 that is reduced in diameter from the lower end inward and an intermediate plate 44 that is reduced in diameter from an intermediate position. is doing.
The horizontal vibration isolator D is configured by inserting a vibration absorbing spring 3 into a pin 1 that is an inner member and a spring case 2 that is a surrounding member. The upper and lower ends of the pin 1 are connected to the lower plate 43 and the intermediate plate 44. It is attached by engaging. The outer periphery of the spring case 2 is in contact with the outer peripheral surface of the inner cylinder 32. The vibration absorbing spring 3 may be either a regular wound spring or a spiral wound spring.
As shown in FIG. 15, an appropriate number of horizontal vibration isolation parts D are put in an annular space in the outer cylinder 41. In this embodiment, six horizontal vibration isolation parts D1 to D6 are used at equal intervals in the circumferential direction, but may be 5 or less, or 7 or more. Of course, the greater the number, the higher the vibration absorption performance in the entire circumferential direction.

  A braking mechanism is provided between the inner cylinder 32 and the outer cylinder 41 separately for a lower part and an upper part. The lower braking mechanism includes a lower plate 39 of the inner cylinder 32, a lower plate 43 of the outer cylinder 41, a steel ball 24 therebetween, and a spring 25 that biases the steel ball. The upper braking mechanism includes an upper plate 38 of the inner cylinder 32, an intermediate plate 44 of the outer cylinder 41, a steel ball 24 therebetween, and a spring 25 that biases the steel ball. The plates 43 and 44 are preferably provided with guide grooves for guiding the steel balls 24. By these braking mechanisms, a braking action is generated between the inner cylinder 32 and the outer cylinder 41 so that it is not shaken by a slight vibration.

(10th Embodiment)
The tenth embodiment shown in FIGS. 16 and 17 is an example in which a building or a mechanical device is installed on a foundation Ba via a mounting member Am.
The vibration isolation mechanism of the present embodiment is also configured by combining a horizontal vibration isolation portion D that absorbs horizontal vibrations and a vertical vibration isolation portion E that absorbs vertical vibrations. As basic components of the vibration isolation mechanism, a base bolt 31 that is vertically attached to the base Ba, an inner cylinder 32 that is disposed around the foundation bolt 31, and an outer cylinder 41 that is fixed to the attachment member Am are provided.

The vertical vibration isolator E is configured as follows.
The lower part of the foundation bolt 31 is embedded in the foundation Ba or passed through and fixed with a nut. Further, an inner cylinder 32 is fixed by a nut 36 at a portion of the foundation bolt 31 protruding upward from the foundation Ba. The inner cylinder 32 is formed with a spring seat 37 at its upper end. The inner diameter of the inner cylinder 32 is larger than the outer diameter of the foundation bolt 31, and the inside is a spring insertion space. A coil spring 33 is inserted into the spring insertion space. The lower end of the coil spring 33 is in contact with the upper surface of the foundation Ba, and the upper end is in contact with the spring seat 37 of the inner cylinder 32, so that vertical vibration is absorbed by the bending action. The coil spring 33 absorbs vibration in the axial direction, but any type of spring may be used as long as it has a similar function. Note that the floor plate 46 may or may not be placed on the upper surface of the foundation Ba.

The horizontal vibration isolator D is configured as follows.
The outer cylinder 41 is attached to the attachment member Am with a bolt 42 or the like. The outer cylinder 41 is a cylindrical member having an inner diameter larger than that of the inner cylinder 32.
The horizontal vibration isolation portion D is obtained by inserting the vibration absorbing spring 3 into the inside of the inner cylinder 32 corresponding to the inner member and the outer cylinder 41 corresponding to the surrounding member. Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used. Engaging grooves 47 are formed in the outer periphery of the inner cylinder 32 and the inner periphery of the outer cylinder 41 so that the vibration absorbing spring 3 is strongly fitted so that it does not come off even when vibration is applied.
In the present embodiment, the vibration absorbing spring 3 of the horizontal vibration absorbing part D absorbs vibration in the horizontal direction by bending, and vibration in the vertical direction can also be absorbed by bending. In addition to this, since the vertical vibration can also be absorbed by the vertical vibration absorber E, the structure is stronger against the vertical vibration.
In addition, if a hollow is formed in the foundation Ba to accommodate most of the vibration isolation mechanism, the vertical dimension of the gap between the foundation Ba and the mounting member Am can be reduced.

(Eleventh embodiment)
The eleventh embodiment shown in FIGS. 18 and 19 is an example in which a building or a mechanical device is installed on a foundation Ba via a mounting member Am.
The vibration isolation mechanism of the present embodiment is a combination of a horizontal vibration isolation part D that absorbs vibrations in a horizontal plane and a vertical vibration isolation part E that absorbs vibrations in a vertical plane. The horizontal vibration isolation part D and the vertical vibration isolation part E is the same as that of the tenth embodiment, and is different only in that a braking mechanism is provided. Accordingly, the same components are denoted by the same reference numerals, and the description thereof is omitted, and only the braking mechanism will be described.
The braking mechanism includes an annular portion 51 formed at the upper end of the inner cylinder 32, an annular portion 52 formed at the upper end of the outer cylinder 41, a steel ball 24 therebetween, and a spring 25 that biases the steel ball. . The spring 25 is placed in a recess formed in the annular part 51 and pushes the steel ball 24 toward the annular part 52. By this braking mechanism, a braking action is generated between the inner cylinder 32 and the outer cylinder 41 so that it is not shaken by a slight vibration.

(Twelfth embodiment)
The twelfth embodiment shown in FIGS. 20 to 22 is an example in which the fixing bracket F is attached to the foundation Ba, and the building or the mechanical device is installed on the attachment member Am.
The vibration isolation mechanism of the present embodiment is also configured by combining a horizontal vibration isolation portion D that absorbs horizontal vibrations and a vertical vibration isolation portion E that absorbs vertical vibrations. And as a basic component of the vibration isolation mechanism, a bolt 31 and two pins 1 are fixed vertically to the fixing bracket F. On the other hand, a spring frame 50 is attached to the attachment member Am. The spring frame 50 has a spring chamber 51 at the center, and the spring case 2 is attached to both sides thereof.

The vertical vibration isolator E is configured as follows.
The bolt 31 passes through a central spring chamber in the frame 50, and the inside of the spring chamber 51 is a spring insertion space. A coil spring 33 is inserted into the spring insertion space. The lower end of the coil spring 33 is in contact with the upper surface of the foundation Ba, and the upper end is in contact with the top wall 52 of the spring chamber 51, so that vertical vibration is absorbed by the bending action.

The horizontal vibration isolator D is configured as follows.
Two pins 1 are inserted into the two spring cases 2, and vibration absorbing springs 3 and 3 are inserted between the pins 1 and the spring case 2. The vibration in the horizontal direction is absorbed by the bending of the vibration absorbing spring 3. Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used.
The braking mechanism in the present embodiment includes a top wall of the spring chamber 51, an upper plate 38 held by a nut 35 at the upper end of the foundation bolt 31, a steel ball 24 therebetween, and a spring that biases the steel ball 24. 25. The steel ball 24 is urged by a spring 25 placed in a recess formed in the top wall 52 of the spring chamber 51 so that the steel ball 24 exhibits frictional resistance against the upper plate 38. By these braking mechanisms, a braking action is generated between the inner cylinder 32 and the outer cylinder 41 so that it is not shaken by a slight vibration.

(13th Embodiment)
The thirteenth embodiment shown in FIGS. 22 and 23 is an example in which a building or a mechanical device is installed on a foundation Ba via a mounting member Am.
The vibration isolation mechanism of the present embodiment is configured by combining a horizontal vibration isolation part D that absorbs horizontal vibrations and a vertical vibration isolation part E that absorbs vertical vibrations. As a basic part of the vibration isolation mechanism, a plurality of foundation bolts 1 and 31 vertically attached to the foundation Ba and a spring frame 50 fixed to the attachment member Am are provided. The spring frame 50 is provided with a plurality of spring cases 51 for the vertical vibration isolation part E and spring cases 2 for the horizontal vibration isolation part D so as to repeat in the horizontal direction. Further, the lower portions of the plurality of foundation bolts 1 and 31 are passed through the foundation Ba and fixed by a nut 35 or embedded. Although three are shown in the drawing, combinations of four or more are possible.

The vertical vibration isolator E is configured as follows.
A spring case 51 is fixed to a portion of each foundation bolt 31 protruding upward from the foundation Ba, and is held by a nut 36 so as not to come out. The spring case 51 is provided with a spring seat 52 at the upper end, and the lower end is opened. The inner diameter of the spring case 51 is larger than the outer diameter of the foundation bolt 31, and the inside is a spring insertion space. A coil spring 33 is inserted into the spring insertion space. The lower end of the coil spring 33 is in contact with the upper surface of the foundation Ba, and the upper end is in contact with the spring seat 52 of the spring case 51, so that the vertical vibration is absorbed by the bending action.
The braking mechanism includes a top wall 53 of the spring case 51 and a plate 54 fixed to the upper end of the foundation bolt 31 with a nut 36, and a steel ball 24 and an urging spring 25 therebetween. The spring 25 is placed in a recess formed in the top wall 53 and presses the steel ball 24 against the plate 54 side. It is preferable to provide a guide groove for guiding the steel ball 24 on the upper surface of the spring chamber 52. With these braking mechanisms, a braking action is generated between the foundation Ba and the spring case 50.

The horizontal vibration isolator D is configured as follows.
A portion of the foundation bolt 1 protruding above the foundation Ba is inserted into the spring case 2, and a vibration absorbing spring 3 is inserted between the foundation bolt 1 and the spring case 2. Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used. The vibration in the horizontal direction is absorbed by the bending of the vibration absorbing spring 3.

(14th Embodiment)
The fourteenth embodiment shown in FIGS. 24 and 25 is an example in which a building or a mechanical device is installed on a foundation Ba via a mounting member Am.
The vibration isolation mechanism of the present embodiment is configured by combining a horizontal vibration isolation part D that absorbs horizontal vibrations and a vertical vibration isolation part E that absorbs vertical vibrations.
First, as basic parts of the vibration isolation mechanism, a center bar 61 attached perpendicularly to the foundation Ba and an outer cylinder 62 fixed to the attachment member Am are provided.

The vertical vibration isolator E is configured as follows.
The center bar 61 is fixed to the foundation Ba by any means. An outer cylinder 62 is concentrically disposed on the outer periphery of the center rod 61, and the outer cylinder 62 is fixed to the attachment member Am with a bolt or the like.
In addition, annular spring grooves 63 and 64 are formed in the vertical direction in several stages on the outer periphery of the center rod 61 and the inner periphery of the outer cylinder 62. The vibration absorbing spring 3 is an elliptical shape or a long rectangular shape with rounded corners, and the springs 3 at each step are independent of each other.
The vibration absorbing springs 3 are fitted in the spring grooves 63 and 64 by changing the longitudinal direction in the plane at equal intervals.
In the present embodiment, the vibration in the horizontal direction is absorbed by the two long axis portions of the vibration absorbing spring 3 being bent outward, and the vibration in the vertical direction is generated by bending the two long axis portions of the spring 3 in the vertical direction. Will be absorbed.

The following fifteenth to seventeenth embodiments are vibration isolation devices suitable for wheels.
(Fifteenth embodiment)
The fifteenth embodiment shown in FIG. 26 and FIG. 27 is provided with a vibration isolator D that absorbs vibration applied to the wheels S.
26-27, 71 is an axle and corresponds to an inner member. Both ends of the axle 71 are attached to a fork 73 via bearings 72. The boss portion 75 of the wheel S is passed through the outside of the axle 71. The boss portion 75 corresponds to a surrounding member and has a cylindrical spring chamber 76, and the inner diameter of the spring chamber 76 is larger than the outer diameter of the axle 71. The vibration absorbing spring 3 is inserted into the space of the spring chamber 76.
Although the vibration absorbing spring 3 is shown in a simplified manner, a spiral wound spring whose winding shape changes is used.
In this embodiment, the shock applied to the wheel S can be absorbed by the vibration absorbing spring 3 being bent.

(Sixteenth embodiment)
The sixteenth embodiment shown in FIGS. 28 and 29 is provided with a vibration isolator D that absorbs vibrations applied to the wheels S, but the bearing 72 is omitted, and the axle 71 includes a fork 73, a bolt 77, and the like. It is fixed with. The rest is the same as in the fifteenth embodiment.
In the present embodiment, since the vibration absorbing spring 3 is always in contact with the inner peripheral surface of the boss portion 75 and functions as a bearing that supports the wheel S, it is preferable to use a material with good slipperiness.

(17th Embodiment)
The seventeenth embodiment shown in FIG. 30 and FIG. 31 is provided with a vibration isolator D that absorbs vibration applied to the wheels S.
In the present embodiment, the vibration absorbing spring 3 is the same as that shown in FIG. That is, annular spring grooves 63 and 64 are formed in parallel on the outer periphery of the axle 71 and the inner periphery of the boss portion 75 in parallel. The vibration absorbing spring 3 is an elliptical shape or a long rectangular shape with rounded corners, and the springs 3 at each step are independent of each other.
The vibration absorbing springs 3 are fitted in the spring grooves 63 and 64 by changing the longitudinal direction in the plane at equal intervals.
In the present embodiment, the vibration applied to the wheel S is absorbed by the long axis portion of the vibration absorbing spring 3 being bent. Further, the vibration absorbing spring 3 is always connected to the spring grooves 63 and 64 and can also function as a bearing for supporting the wheel S.
Also in this embodiment, the vibration applied to the wheel 74 can be absorbed by the vibration absorbing spring 3 to reduce the vibration.

  INDUSTRIAL APPLICABILITY The present invention can be used for vibration resistance of buildings such as buildings and tanks, civil engineering machines, precision equipment, machine tools, railways, automobiles, and the like. In particular, when an earthquake or vibration occurs in an electric wire, a signal line, a gas pipe, a water pipe, a computer cable, a petroleum pipe, a tank, etc., it can be used for absorbing vibration energy including aerial installation and general installation as well as underground installation. Moreover, it can apply to the attachment part of a vibrating body and can absorb the vibration energy from a vibration source. Furthermore, the present invention can be applied to wheels and used for absorbing vibrations of wheels and traveling vehicles.

It is principle explanatory drawing of the vibration isolator of this invention. Fig. i is an explanatory diagram of a vibration isolator using a regular wound spring, and Fig. ii is an explanatory diagram of a vibration isolator using a helical spring. It is explanatory drawing of the vibration isolator using an elliptical spring. It is an attachment state sectional view of the vibration isolator which concerns on 1st Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 2nd Embodiment of this invention. It is an attachment state sectional view of the vibration isolator which concerns on 3rd Embodiment of this invention. FIG. 7 is an explanatory diagram of a mounting state of the vibration isolator of FIG. 6. It is attachment state sectional drawing of the vibration isolator which concerns on 4th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 5th Embodiment of this invention. It is an attachment state sectional view of the vibration isolator which concerns on 6th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 7th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 8th Embodiment of this invention. It is the elements on larger scale of FIG. It is attachment state sectional drawing of the vibration isolator which concerns on 9th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 9th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 10th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 10th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 11th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 12th Embodiment of this invention. It is a side view of the vibration isolator which concerns on 12th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 12th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 13th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 13th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 14th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 14th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 15th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 15th Embodiment of this invention. It is an attachment state sectional view of the vibration isolator which concerns on 16th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 16th Embodiment of this invention. It is attachment state sectional drawing of the vibration isolator which concerns on 17th Embodiment of this invention. It is a plane sectional view of the vibration isolator which concerns on 17th Embodiment of this invention. It is explanatory drawing of the conventional rubber mount type vibration proof structure. It is explanatory drawing of the conventional uncassette. It is explanatory drawing of the conventional piping attachment structure.

1 inner member 2 surrounding member 3 vibration absorbing spring

Claims (4)

An inner member attached to the vibration source side member or the vibration body side member;
An enclosure member attached to the vibration member side member or the vibration source side member;
It consists of a vibration absorbing spring that is extrapolated to the inner member and that is intercalated to the surrounding member,
The vibration absorbing spring is a coil spring in which the wound shape in a non-circular, in contact with the circumferential direction of the plurality of positions with respect to the outer circumferential surface of the inner member, and a circumferential direction with respect to the inner peripheral surface of the enclosing member A vibration isolator characterized by being a spiral wound spring that contacts at a plurality of locations and whose winding shape changes spirally in the longitudinal direction. An inner member attached to the vibration source side member or the vibration body side member;
An enclosure member attached to the vibration member side member or the vibration source side member;
It consists of a vibration absorbing spring that is extrapolated to the inner member and that is intercalated to the surrounding member,
The vibration absorbing spring is a coil spring in which the wound shape in a non-circular, in contact with the circumferential direction of the plurality of positions with respect to the outer circumferential surface of the inner member, and a circumferential direction with respect to the inner peripheral surface of the enclosing member of is intended to contact at a plurality of locations, Ri Oh spiral coil spring whose winding shape is changed spirally in the longitudinal direction,
The vibration isolator, wherein the surrounding member and the vibration absorbing spring are both concentrically and multiply provided. The vibration isolator according to claim 1 or 2, wherein an engagement groove for engaging the vibration absorbing spring is formed on an outer peripheral surface of the inner member and an inner peripheral surface of the surrounding member. In addition to the vibration isolator according to claim 1 or 2,
A vibration isolator comprising a spring that absorbs vibration in a direction orthogonal to the vibration absorption direction of the vibration isolator.

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