JP2010518294A - Split vibration isolator and its application - Google Patents

Abstract

A split type vibration isolator comprising a connecting sleeve having a support block and a lifting block and a spring vibration isolator, wherein the connecting sleeve comprises an upper sleeve and a lower sleeve. A split type vibration isolator is provided, in which a separable connecting structure is employed between the sleeves, the lifting block is disposed on the upper sleeve, and the support block is disposed on the lower sleeve. Also, a mounting method is provided by lifting the split vibration isolator.
[Selection] Figure 1

Description

  The present invention belongs to the field of vibration and noise control, and more particularly to a vibration isolator capable of reducing adverse effects caused by vibration and noise generated during operation of a rail vehicle or vibrations of building members and equipment foundations.

  In a conventional track traffic structure, when a vehicle is operated, large vibrations and noises are generated, which may affect surrounding buildings and facilities and may cause harm to people. Therefore, for urban areas where population and buildings are relatively concentrated, reduction of vibration and noise due to orbital traffic is a particularly important issue. Currently, depending on the intervention node of each vibration damping measure, the vibration damping measures are divided into three types: vibration isolation under the track, vibration isolation under the sleepers, and vibration isolation under the road bed. According to the vibration isolation principle and structural dynamics, the greater the vibration participating mass of the vibration isolation system and the elasticity of the elastic element, the better the effect of vibration isolation. According to the structure of the track, the farther away the intervention node of the vibration isolation measure is from the rail, the greater the elasticity and vibration participating mass can be, the lower the natural frequency and the range of vibration isolation can be reduced. The effect is improved. However, with respect to strength and mass, there are predetermined objective limits at different nodes, and it cannot be arbitrarily enlarged or reduced. For example, if the elasticity of the spacing plate is arbitrarily increased under the track, the rail is deformed and the displacement is too large, which affects the safety of operation. Therefore, when the request for vibration isolation is 10 decibels or more, normally, the request cannot be satisfied unless measures for vibration isolation are taken under the roadbed. Patent Document 1 discloses a built-in vibration isolator, in which a connecting sleeve of the vibration isolator is disposed in a floating plate, and the height of the connecting sleeve and the thickness of the floating plate are the same. Since it needs to be lifted, the lifting block and the support block are arranged at an interval on the inner wall of the connecting sleeve. Since a space for accommodating a lifting tool is created between the lifting block and the support block, the height of the connecting sleeve is usually high. However, in actual applications, it is impossible to adopt a floating plate because a large connecting sleeve cannot be accommodated in the space created for the floating plate due to limitations of various factors such as space, cost and environment. . On the other hand, in the process design, the height of the floating plate is normally determined late, and the height and size of the connecting sleeve depends on the thickness of the floating plate. The time will be longer. In particular, when there is a design change during construction, since the period corresponding to the change is long, it is easy to affect the progress of construction.

Chinese Patent No. 2004100354411

  The object of the present invention is to overcome the above-mentioned problems, easily change the size of the mounting space for lifting, or do not need to prepare the mounting space for lifting in advance, can be delivered quickly by inventory production, and larger It is an object of the present invention to provide a split vibration isolator and its application that can be applied to a floating plate, a floor of a building, or a foundation of equipment having different thicknesses within a height range.

  Another object of the present invention is to provide a mounting method by lifting a split vibration isolator.

  The present invention further has the object of providing a lifting tool for a split vibration isolator.

  A split type vibration isolator according to the present invention is a split type vibration isolator comprising a connecting sleeve in which a support block and a lifting block are arranged, and a spring vibration isolator, wherein the connecting sleeve is an upper sleeve and a lower sleeve. And a separable connecting structure between the upper sleeve and the lower sleeve is employed, the lifting block is disposed on the upper sleeve, and the support block is disposed on the lower sleeve.

  Various connecting means can be adopted as the splittable connection between the upper sleeve and the lower sleeve. For example, a connecting flange or connecting ear plate may be disposed on the upper sleeve and the lower sleeve, respectively, and the upper sleeve and the lower sleeve may be connected via an axial bolt, pin, or ferrule. Further, pin holes, screw holes, or chains may be disposed on the side walls of the upper sleeve and the lower sleeve, and the upper sleeve and the lower sleeve may be connected via eye nails or bolts. Alternatively, the pins may be arranged so as to correspond to the side walls of the upper sleeve and the lower sleeve, and connected to each other via a chain fastener hung on the pins. Also, a radial ear plate is arranged on the side wall of the upper sleeve and the lower sleeve, and a pin hole or pin in the tangential direction is arranged on the ear plate, and the upper sleeve and the lower sleeve are interposed via the pin hole, eye nails or bolts. May be connected to each other, or may be connected to each other via a chain fastener hung on a pin. Furthermore, an engagement hawk that can swing up and down or swing in a tangential direction is arranged on one side wall of the upper sleeve and the lower sleeve, and an engagement hole or an engagement edge corresponds to the side wall of the other sleeve. The upper sleeve and the lower sleeve may be connected to each other via the engaging hawk. Alternatively, the upper sleeve and the lower sleeve are each provided with an opening and a stop edge that are adjusted in size and overlapped due to misalignment, and the stop edge passes through the opening, and then the contours of both are overlapped with each other. Is turned in the axial direction to realize the hook connection between the upper sleeve and the lower sleeve.

  The spring vibration isolator includes a spring case and a spring provided in the spring case, and as a spring, a coil spring having appropriate rigidity and elasticity in the vertical and horizontal directions, a disc spring, Even if a rubber metal composite spring or a disk rubber metal composite spring is included and an elastic supporting member or restricting member acting in the horizontal direction is not provided, the stability of the floating plate in each direction and the vibration shielding effect can be ensured. At least a part of the surface of the spring is provided with a restraining damping material, or at least a part of the spring is fitted into the damping material. A sealing structure is disposed in the spring case, a liquid system vibration material is disposed in the spring case, and a lower part of the spring is immersed in the liquid system vibration material. The spring vibration isolator is disposed inside the connecting sleeve and below the support block. A washer is provided between the spring vibration isolator and the support block, and a lifting hole is opened in the center of the washer. The opening and shape of the support block and the lifting block are matched with the size of the upper surface of the spring case and the washer, and are overlapped due to misalignment. The upper and lower surfaces of the spring vibration isolator are provided with a connecting device for preventing the horizontal movement thereof, and the upper and lower parts of the connecting device are connected to the connecting sleeve and the foundation, respectively. Non-slip spacing plate, bolt, or uneven structure.

  The mounting method by lifting the split vibration isolator according to the present invention includes the following steps. That is,

  (1) The connecting sleeve is cast into a floating plate or other member to be floated according to the specifications of the selected vibration isolator. When a temporary auxiliary sleeve for lifting the upper sleeve is used, only the lower sleeve is cast into a member to be floated.

  (2) When mounting as a temporary auxiliary sleeve for lifting the upper sleeve, the upper sleeve and the lower sleeve are first connected by a connecting structure.

  (3) Put the spring vibration isolator and washer into all the lower sleeves in order, and place the spring vibration isolator below the support block so that the upper surface of the spacing plate is slightly higher than the lower surface of the support block. Arrange as follows.

  (4) Put the hydraulic jack and jack support frame in the upper sleeve, put the piston rod or its extension into the lifting hole of the spacing plate, support the jack support frame by the lifting block, drive the jack, and the washer Compress the spring vibration isolator until it is slightly lower than the bottom of the sleeve support block.

  (5) Rotate the washer to realize that the washer and the support block are overlapped due to displacement.

  (6) When the pressure of the jack is released, the spring vibration isolator urges the washer against the support block of the lower sleeve, receives a load from the spring vibration isolator, and takes out the jack support frame and the jack.

  (7) Repeat in this manner, and sequentially apply a load to the spring vibration isolator in all the lower sleeves of the floating member until the floating member is separated from the foundation surface and finally reaches a predetermined height.

  (8) When using a temporary auxiliary sleeve for lifting the upper sleeve, loosen the connecting structure between the upper sleeve and the lower sleeve, take out the upper sleeve, and complete the lifting.

  The lifting tool for a split vibration isolator according to the present invention is equipped with a jack, and a jack support frame is disposed on the jack case, and is matched with the shape of the jack support frame and the size and shape of the opening of the lifting block of the split vibration isolator. After the jack support frame is put into the opening of the lifting block, the lifting block and the jack support frame are overlapped with each other by the displacement of the jack support frame. The diameter of the jack piston rod or its extension is smaller than the diameter of the washer lifting hole.

  The split type vibration isolator according to the present invention effectively expands the application range of the vibration isolator by arranging a separable upper sleeve and lower sleeve. If a floating board is demonstrated as an example, the specific application method is the following two points. That is, it is possible to standardize the lower sleeve and perform inventory production. The upper sleeves having different heights may be processed correspondingly to the floating plates having different thicknesses. Since the height alignment can be completed before delivery or when assembled on site, it can contribute to shortening the machining cycle and strengthening the ability to respond to needs. In this case, the upper sleeve is permanently fixed in the floating plate. On the other hand, regarding the problem that the height of the connecting sleeve caused by preparing the mounting space by lifting is too high and cannot be applied to the thin track floating plate, the height of the lower sleeve is set according to the floating plate and used Sometimes only the lower sleeve and the floating plate are cast integrally, the upper sleeve is used as a temporary auxiliary sleeve for lifting, and the upper sleeve is removed after lifting. Furthermore, the upper sleeve can be used repeatedly by standardization. Based on this principle, the present invention can be applied to the floor of a building or the foundation of equipment, and the effects of good buffering and vibration isolation are contained.

  The structure of the split-type vibration isolator according to the present invention is compact and reasonable, and the processing cycle is shortened on the premise that the effect of the vibration isolation is not affected, the material is saved, the cost is reduced, The application range of vibration isolator has been expanded, has high practicality, has both economic and environmental protection effects, and offers many choices for vibration and noise control during construction of track traffic and factory buildings. The mounting method of lifting is simple and convenient, and the effect is reliable. The lifting tool is highly practical, easy to use, and has the potential to expand and apply.

It is the 1st schematic diagram of the structure of the splitting type vibration isolator concerning the present invention. FIG. 2 is a top view of FIG. 1. It is the 1st schematic diagram of the mounting process by lifting of the division type vibration isolator concerning the present invention. It is the 1st schematic diagram of the operation state of the division type vibration isolator concerning the present invention. It is the 2nd schematic diagram of the mounting process by lifting of the division type vibration isolator which concerns on this invention. It is the 2nd schematic of the operating state of the splitting type vibration isolator which concerns on this invention. It is the 2nd schematic of the structure of the split-type vibration isolator which concerns on this invention. It is a 3rd schematic diagram of the structure of the split-type vibration isolator which concerns on this invention. It is the 4th schematic diagram of the structure of the division type vibration isolator concerning the present invention. FIG. 10 is a fifth schematic diagram of the structure of the split vibration isolator according to the present invention. It is a top view of FIG. It is the schematic of the structure of the lifting tool which concerns on this invention. FIG. 6 is a schematic view of an application of a lifting tool according to the present invention.

  As shown in FIG. 1, the split vibration isolator according to the present invention includes a lower sleeve 1, an upper sleeve 2, a spring vibration isolator 3, and a washer 4. A support block 5 is disposed on the upper portion of the lower sleeve 1. In order to simplify the structure, the support block 5 is integrally formed with the connection flange 6 at the upper end of the lower sleeve 1. A lifting block 7 is disposed on the upper sleeve 2. The lower sleeve 1 and the upper sleeve 2 are connected via a bolt 10 disposed between the connecting flange 6 at the upper end portion of the lower sleeve 1 and the connecting flange 8 at the lower end portion of the upper sleeve 2. The thickness of the lower sleeve 1 corresponds to the thickness of the floating plate 9.

  The spring vibration isolator 3 includes a spring case and a spring 21. The spring 21 is a coil spring, is located in the spring case 23, has an appropriate rigidity in the vertical direction and the horizontal direction, and does not have an extra elastic support member or position limiting member acting in the horizontal direction. The stability and vibration isolation effect in each direction of the floating plate can be guaranteed. A sealing structure 27 is disposed in the spring case 23, the liquid system vibration material 22 is disposed in the spring case, and the lower part of the spring 21 is immersed in the liquid system vibration material 22. As shown in FIG. 2, the spring vibration isolator 3 is disposed inside the lower sleeve 1 and below the support block 5. A washer 4 is provided between the spring vibration isolator 3 and the support block 5, and a lifting hole is opened at the center of the washer 4. The openings and shapes of the support block 5 and the lifting block 7 are matched with the upper surface of the spring case 3 and the size of the washer 4, and are overlapped by misalignment. A non-slip spacing plate 26 is provided on the upper surface of the spring vibration isolator 3 to prevent its horizontal movement, and an uneven structure 24 is provided on its lower surface to prevent its horizontal movement.

  As shown in FIG. 3, before mounting, the lower sleeve 1 is cast into a floating plate 9 to solidify it, and after the lifting strength is achieved, the upper sleeve 2 is fixed to the lower sleeve 1 with bolts 10. assemble. When mounting, the spring vibration isolator 3 and the washer 4 are sequentially placed at the corresponding positions of the lower sleeve 1 so that the upper surface of the washer 4 is slightly higher than the lower surface of the support block 5. Then, the jack 11 and the jack support frame 12 are inserted, the jack 11 is driven, and the spring vibration isolator 3 is compressed while being supported by the lifting block 7 using the jack 11 and the jack support frame 12. When the washer 4 is lower than the lower surface of the support block 5, the washer 4 is rotated, and the washer 4 and the support block 5 are superposed due to displacement. After the pressure of the jack 11 is released, the jack support frame 12 and the jack 11 are taken out. At this time, the spring vibration isolator 3 springs back and urges the washer 4 to be pressed against the support block 5 of the lower sleeve 1. Repeatedly in this manner, for all the spring vibration isolator in the lower sleeve of the floating plate 9, the floating plate 9 moves away from the base surface 13 (see FIG. 4) and finally reaches a predetermined height. I will apply a load. Finally, the bolt 10 is loosened and the upper sleeve 2 is removed. By adjusting the number of washers and the overall thickness, the height and inclination of the floating plate 9 separating from the base surface can be adjusted. As shown in FIG. 4, a dust cap 14 and a sealing washer 15 are further disposed above the lower sleeve 1 to prevent dust, dirty water, or other foreign matters from entering the lower sleeve 1. The dust cap 14 may be disposed so as to be completely fitted into the lower sleeve 1.

  By standardizing the corresponding holes in the screw holes and the upper sleeve 2 or the position and size of the screw holes, the upper sleeve 2 can be shared and the upper sleeve 2 can be used repeatedly. Therefore, material and time required can be saved greatly, and the cost of the product can be reduced.

  Even if the connecting flange 6 and the connecting flange 8 are respectively disposed inside the lower sleeve 1 and the upper sleeve 2 and the lower sleeve 1 and the upper sleeve 2 are connected inside by a fastener, the same effect can be realized. In addition, such a connection structure can contribute to further reducing the volume of the vibration isolator and save material. In addition to the entire connection flange, a plurality of connection ear plates may be used.

  By adjusting the height of the lower sleeve and at least one of the washer and the spring vibration isolation, the vibration isolation device according to the present invention can be applied to floating plates having different thicknesses. Of course, based on the above principle, the vibration isolator according to the present invention can also be applied to places such as the floor of buildings and the foundations of equipment, and can provide good buffering and vibration isolating effects.

  In the second embodiment of the present invention, as shown in FIGS. 1, 5 and 6, the upper sleeve 2 and the lower sleeve 1 are fixedly connected and placed together in the floating plate 9 and lifted up. The second embodiment is different from the first embodiment in that the dust cap 14 and the sealing washer 15 are disposed correspondingly above the upper sleeve 2. Of course, the dust cap 14 may be disposed so as to completely fit into the upper sleeve 2. That way, the aesthetics will be better.

  When used, the upper sleeve may be processed according to the actual thickness of the floating plate 9 before standardizing the lower sleeve 1, performing inventory-type production, and delivering it. Since the height of the connecting sleeve can be quickly adjusted at the factory or construction site, it can contribute to shortening the machining cycle and improving the construction efficiency. Meet vibration isolation requirements better. In addition to bolt connection, the upper sleeve 2 and the lower sleeve 1 may be integrally connected by welding or adhesion. By doing so, it is possible to omit the connecting flange structure, further save material, enhance the strength of the connection, and contribute to reducing the product cost.

  In the third embodiment of the present invention, as shown in FIG. 7, without using a connecting flange at the bottom of the upper sleeve 2, a pin hole disposed on the side wall of the lower sleeve 1 and the upper sleeve 2 is used to Example 1 is different from Example 1 in that both are connected to each other.

  By this connection method, the structure of the upper sleeve 2 becomes simpler, less material is used, and the cost is correspondingly cheaper. After removing the upper sleeve, a dust cap can be placed in the space above the support block 5 of the lower sleeve 1 (not shown), making space utilization more compact and more rational. Of course, screw holes may be arranged, and the connection may be realized by bolts instead of eye nails.

  In addition to the method of connecting the pin hole and the pin together, the pins are arranged so as to correspond to the side walls of the upper sleeve 2 and the lower sleeve 1, respectively, and the upper sleeve 2 and the lower sleeve 1 are connected to each other through a chain fastener hung on the pin. You may connect mutually.

  In addition, the spring 21 in this embodiment is a metal rubber composite spring, and the rubber is a hollow cylindrical shape. In order to increase the vibration damping effect of the vibration isolator, the solid vibration damping material, which is a high vibration damping polyurethane, is hollow. Placed in the part. A plurality of conical metal rings are arranged on the rubber, and by adjusting the taper and the thickness of the rubber layer, the rigidity ratio between the vertical direction and the horizontal direction of the rubber spring can be adjusted.

  In the fourth embodiment of the present invention, as shown in FIG. 8, a suspension ring 18 is disposed on the lower sleeve 1, a lifting lug 17 is disposed on the upper sleeve 2, and a pin hole is disposed on the lifting lug 17. The assembly differs from the third embodiment in that the lug 17 and the suspension ring 18 are assembled and the lower sleeve 1 and the upper sleeve 2 are connected via the bolt 10.

  Of course, the same connection effect can be obtained by arranging the lifting lugs 17 in the upper sleeve 2 and the lower sleeve 1 at the same time and aligning the pin holes and the eye nails in the lifting lugs 17. Further, a highly reliable connection between the upper sleeve 2 and the lower sleeve 1 can be realized even by arranging a pin on the lifting lug 17 and via a chain fastener hung on the pin.

  In the fifth embodiment of the present invention, as shown in FIG. 9, the engaging fork 25 is hinged to the upper sleeve 2 and the engaging flange 25 and the connecting flange 6 provided at the upper end of the lower sleeve 1 are engaged. Thus, the fourth embodiment differs from the fourth embodiment in that the upper sleeve 2 and the lower sleeve 1 are fastened.

  Of course, the same effect can be realized by disposing another fastening device for engaging with the engaging hawk 25 on the upper surface of the connecting flange 6 or disposing the engaging hole corresponding to the lower sleeve 1.

  In Embodiment 6 of the present invention, as shown in FIGS. 10 and 11, a stop edge 19 is disposed on the lower sleeve 1, a stop edge 20 is disposed on the upper sleeve 2, and the stop edge 20 is disposed on the lower sleeve 1. In the embodiment, after being put in the lower sleeve 1 through the opening whose size and shape are matched, it is rotated around the axial direction, overlapped with the stop edge 19 by positional displacement, and the upper sleeve 2 and the lower sleeve 1 are connected. Different from 3.

  Example 7 of the present invention relates to a lifting tool according to the present invention as shown in FIGS. The lifting tool of the present invention includes a jack 11, and a jack support frame 12 is disposed in a case of the jack 11 by a screw structure, and the shape of the jack support frame 12 is matched with the shape of the opening of the vibration isolator, and is inserted into the opening. After that, it is possible to superimpose due to misalignment by rotation. The diameter of the jack / piston rod 31 is smaller than the diameter of the lifting hole at the center of the washer 5. Using the lifting tool according to the present invention, the lifting operation of the vibration isolator can be quickly realized by the mounting method by lifting.

  The structure of the split vibration isolator according to the present invention is simple, the design is reasonable, the production cost is low, the replacement and repair are convenient, the economic effect and the environmental protection effect are good, the floating plate, the building It can be applied to the vibration isolation of railway floors or the foundations of equipment, particularly subway tracks, and naturally can also be widely applied to vibration isolation in the rail traffic field such as railways, urban railways, elevated railways, restraint railways.

DESCRIPTION OF SYMBOLS 1 Lower sleeve 2 Upper sleeve 3 Spring vibration isolator 4 Washer 5 Support block 6 Connection flange 7 Lifting block 8 Connection flange 9 Floating plate 10 Bolt 11 Jack 12 Jack support frame 13 Base surface 14 Dust-proof cap 15 Sealing washer 16 Nails 17 Lifting Lug 18 Suspension ring 19 Stopping edge 20 Stopping edge 21 Spring 22 Liquid system vibration material 23 Spring case 24 Uneven structure 25 Engaging fork 26 Non-slip spacing plate 27 Sealing structure 31 Jack / piston rod

Claims (16)

A split type vibration isolator comprising a connecting sleeve in which a support block and a lifting block are arranged, and a spring vibration isolator,
The connection sleeve comprises an upper sleeve and a lower sleeve, and a connection structure that can be divided between the upper sleeve and the lower sleeve is adopted,
The lifting block is disposed on the upper sleeve;
The split vibration isolator according to claim 1, wherein the support block is disposed on the lower sleeve.   2. The split type according to claim 1, wherein a coupling flange or a coupling ear plate is disposed on each of the upper sleeve and the lower sleeve, and the upper sleeve and the lower sleeve are coupled to each other via an axial bolt, pin, or ferrule. Vibration isolation device.   Pin holes, screw holes, or chains are arranged on the side walls of the upper sleeve and the lower sleeve so as to correspond to each other, and the upper sleeve and the lower sleeve are connected to each other via eye nails or bolts, or the upper sleeve and the lower sleeve 2. The split type vibration isolator according to claim 1, wherein a pin is disposed so as to correspond to a side wall of the first and second sleeves and the upper sleeve and the lower sleeve are connected to each other via a chain fastener hung on the pin.   A radial ear plate is arranged on the side wall of the upper sleeve and the lower sleeve, a pin hole or a pin is arranged tangentially on the ear plate, and the upper sleeve and the lower sleeve are arranged via the pin hole, eye nails or bolts. 2. The split vibration isolator according to claim 1, wherein the upper sleeve and the lower sleeve are connected to each other via a chain fastener attached to a pin.   An engagement fork that can swing up and down or swing in a tangential direction is disposed on one side wall of the upper sleeve and the lower sleeve, and an engagement hole or engagement edge is disposed on the side wall of the other sleeve. The split vibration isolator according to claim 1, wherein the upper sleeve and the lower sleeve are connected to each other via an engagement hawk.   The upper sleeve and the lower sleeve are each provided with an opening and a stop edge that are matched in size and overlapped due to misalignment, and after the stop edge penetrates the opening, the sleeve is pivoted so that the contours of both are overlapped. The split vibration isolator according to claim 1, wherein the split vibration isolator is turned around in a direction to realize a hanging connection between the upper sleeve and the lower sleeve. Spring vibration isolator
A spring case,
A coil spring, a disk spring, a rubber metal composite spring, or a spring including a disk rubber metal composite spring, which is located in the spring case and has appropriate rigidity and elasticity in the vertical and horizontal directions. 2. The split vibration isolator according to 1.   The split vibration isolator according to claim 7, wherein at least a part of the surface of the spring is provided with a restricted vibration damping material, or at least a part of the spring is fitted into the vibration damping material.   The split vibration isolator according to claim 7, wherein a sealing structure is disposed in the spring case, a liquid system vibration material is disposed in the spring case, and a lower part of the spring is immersed in the liquid system vibration material.   The spring vibration isolator is disposed inside the connecting sleeve and below the support block, a washer is disposed between the spring vibration isolator and the support block, and a lifting hole is opened in the center of the washer. The split vibration isolator according to any one of 7 to 9.   The split vibration isolator according to claim 10, wherein the support block and the lifting block have openings and shapes that are matched with the sizes of the upper surface of the spring case and the washer, and are superposed by displacement.   A connecting device for preventing the horizontal movement of the spring vibration isolator is provided on the upper and lower surfaces, and the upper and lower parts of the connecting device are connected to each other on the basis of a connecting sleeve. The split vibration isolator according to any one of claims 7 to 9, which is a non-slip spacing plate, a bolt, or an uneven structure. A method of lifting and mounting a split vibration isolator,
(1) Depending on the specifications of the selected vibration isolator, when the connecting sleeve is cast into a floating plate or other member to be floated and the upper sleeve is used as a temporary auxiliary sleeve for lifting, the lower sleeve is floated Casting into a member to be made,
(2) When mounting, when the upper sleeve is a temporary auxiliary sleeve for lifting, a step of first connecting the upper sleeve and the lower sleeve by a connection structure;
(3) A step of sequentially placing a spring vibration isolator and a washer into the lower sleeve, positioning the spring vibration isolator below the support block, and making the upper surface of the spacing plate slightly higher than the lower surface of the support block; ,
(4) A jack and a jack support frame are placed in the upper sleeve, a piston rod or an extension thereof is placed in a lifting hole of a spacing plate, support is given to the jack support frame by a lifting block, and the jack is driven. Compressing the spring vibration isolator until a washer is slightly lower than the bottom surface of the lower sleeve support block;
(5) Rotating the washer to realize that the washer and the support block are overlapped due to displacement;
(6) The pressure is released to the jack, and at this time, the spring vibration isolator urges the washer against the support block of the lower sleeve and receives a load from the spring vibration isolator. Removing the jack support frame and the jack;
(7) Repeat in this manner, and sequentially apply loads to the spring vibration isolator in all the lower sleeves in the floating member until the floating member is separated from the foundation surface and finally reaches a predetermined height. Adding steps,
(8) In the case of using a temporary auxiliary sleeve for lifting the upper sleeve, there is a step of loosening a connection structure between the upper sleeve and the lower sleeve, taking out the upper sleeve, and completing lifting. A method of lifting and mounting the split vibration isolator.   The division | segmentation type vibration isolator in any one of Claim 1 to 12 applied to a floating road floor, the floor of a building, or an installation foundation. A lifting tool for a split vibration isolator including a jack,
After the jack support frame is arranged in the jack case, and matched to the shape of the jack support frame and the size and shape of the opening of the lifting block of the split vibration isolator, the jack supporting frame is put into the opening of the block A lifting tool for a split-type vibration isolating device, wherein the lifting block and the jack supporting frame are overlapped with each other due to a displacement by rotation of the jack supporting frame.   The lifting tool for a split vibration isolator according to claim 15, wherein the diameter of the piston rod of the jack or its extension is smaller than the diameter of the lifting hole of the washer.