RU2233366C1 - Method of vibration insulator installation in building or building structure - Google Patents

Abstract

FIELD: building, particularly creating vibration insulation into buildings and building structures for protecting people and equipment against vibration acting upon building or building structure through ground.

SUBSTANCE: method involves installing at least one vibration isolator and force-applying means with ends abutting base and upper structure temporary supported by base through supports such that vibration isolator and force-applying means are arranged in opened depressions created in upper structure facing base; bringing vibration insulator into operational position by compression thereof with the use of force-applying means arranging bearing members formed as set of pads between vibration insulator and base for vibration insulator securing in compressed state; removing force-applying means and removing supports after separating vibration insulators of upper structure from base due to elastic force action. Base has at least one depression opened from upper side thereof and at least one cavity communicating with depression and opened from one end of base. Edges of cavity are reinforced by angle elements. At least one support force-applying plate is placed into depression above cavity before vibration insulator installation. Vibratory insulator is placed on support force-applying plate and force-applying means are arranged in cavity under support force-applying plate. Parameters of force-applying plate are calculated from given relation.

EFFECT: increased safety and reliability, possibility of controlled vibration insulator installation.

16 cl, 30 dwg

Description

The invention relates to the field of construction and can be used to protect buildings and structures, both under construction and existing, as well as people in them from natural and man-made vibrations transmitted to the structure of buildings, structures from the outside, for example, on the ground or from internal sources .

The closest to the invention in terms of technical nature and the achieved result is a method of installing vibration isolators of a building, structure, including installing at least one vibration isolator and power devices in a row between the base and the upper structure temporarily resting on it in each of the formed in one of them from the side facing to the other, open niches, outside of which stops are placed between the upper structure and the base on the supporting platforms, and the vibration isolator is put into working condition in the niche it is carried out by compression, after which support elements in the form of blocks are placed between the vibration isolator and the base, which fix the vibration isolator in a compressed state, and power devices are removed, and after separation, the stops are removed from the base due to the elastic forces of the vibration isolators of the upper structure (see, for example, SU 1161660 A, 06/15/1985).

The disadvantages of the known method of installing vibration isolators are:

- the presence of a niche common for the vibration isolator and power devices, in which it is necessary to install massive and high locking support blocks commensurate with removable power devices, the installation or replacement of which is time-consuming and unsafe, and their reliability and stability under heavy loads, especially of a natural nature, are not controlled;

- the location of the part of power devices (for example, jacks) outside the wall plane on both sides of the vibration isolator or inside the wall in a common niche, which makes it impossible to install vibration isolators both in a limited space, for example, if necessary, devices have large additional openings in the walls for passing communications, and at high altitude - in the walls under the ceilings and on the capitals of the columns, and also, if necessary, only a one-sided approach to the vibration isolator, for example, when passing engineering networks with one hundred ones walls or in the case of external walls adjacent to the ground;

- the inevitability of the device of large niches necessary for the joint arrangement of vibration isolators and power devices, which leads to a significant complication of the structural solutions of the underground part of the building, ensuring its strength and, as a result, to the irrational organization of the internal space of this underground part of the building.

The objective of the present invention is to provide a method that allows for minimal material consumption and laboriousness to safely install vibration isolators in buildings and structures at any place of their placement, while ensuring the greatest reliability and cost-effectiveness of the building structure.

The problem is solved due to the fact that in a method that includes installing at least one vibration isolator and power devices in a row between the base and the upper structure temporarily resting on it in each of the open niches formed in one of them from the side facing the other, the limits of which between the upper structure and the base on the supporting platforms are placed stops, and bringing the vibration isolator into working condition, which is carried out in a niche by compressing it, and then between the vibration isolator and the base place support elements in the form of blocks, fixing the vibration isolator in a compressed state, and remove power devices, and after detaching due to the elastic forces of the vibration isolators of the upper structure, the stops are removed from the base, according to the invention, a base is used, in the upper part of which at least one open from above is arranged and at least one end of the niche in the lower part of which form at least one opening communicated with the niche and open from at least one end, the edges of which are reinforced with corner elements at least one support plate with a width B, determined by the dependence (2.0-4.0) C≤B≤ (0.6-0.9) D, before installing the vibration isolator in the recess above the opening coaxially with its longitudinal axis where D = A / N, A is the width of the niche, cm, N is the number of openings in communication with the niche, C is the width of the opening, cm, and the vibration isolator is installed on the base plate, while the power devices are placed in the base opening under the base plate a plate, and the supporting elements fixing the vibration isolator in a compressed state are made in the form of a set of gaskets that are placed They are located between the horizontal shelves of the elements of the corner profile and the supporting power plate.

In this case, a base can be used in which one opening is formed, which is placed coaxially with the transverse axis of the niche, and one support plate is laid.

They can use a base, in the niche of which an even number of openings is formed, preferably two openings, which are placed symmetrically with respect to the transverse axis of the niche, and one support plate is placed above each of the openings.

They can use a base in the niche of which an odd number of openings is formed, preferably three openings, one of which is placed coaxially with the transverse axis of the niche, and the rest are symmetrical with respect to the transverse axis of the niche, and one support plate is placed over each of the openings.

They can use a base, in the niche of which one opening is formed, which is placed coaxially with the transverse axis of the niche, and two supporting force plates are laid one above the other one above the other, symmetrically with respect to the longitudinal axis of the niche.

They can use the base, in the niche of which more than one aperture is formed, and over each of the apertures two supporting force plates are laid one after the other, symmetrically with respect to the longitudinal axis of the niche.

They can use a base, including a foundation plate with a lower part of the wall protruding from it in the form of a rib, and the upper structure as the upper part of the wall, with at least one niche with at least one opening connected to it in the lower part of the wall.

They can use the base in the form of at least one column with a capital in the upper part and the upper structure in the form of an overlap located above the capital, while at least one niche is formed in the capitals and form at least one opening in communication with it.

They can use the capital, in which they arrange one niche, form one opening coaxially with the transverse axis of the niche and place supporting platforms outside the niche along the edges of the capital parallel to its transverse axis, while one support plate is laid over the opening, and stops are placed on the supporting platforms.

They can use the capital, in which they arrange one niche, form one opening coaxially with the transverse axis of the niche and place supporting platforms along the edges of the capital parallel to its transverse axis, while two supporting force plates are placed one above the other over the opening, and stops are placed on the supporting platforms.

They can use a capital in which two niches are arranged symmetrically relative to its longitudinal axis, each with three open sides, and the capitals are placed coaxially with the longitudinal axis between the niches, and in each niche they form one opening that is aligned with the transverse axis of the niche, a support plate is placed over each of the openings, and an emphasis is placed on the supporting platform between the upper structure and the base.

They can use a capital, in which two niches are arranged symmetrically with respect to its transverse axis, with three open sides each, place a support pad between the niches coaxially with the transverse axis of the capitals and form an aperture in each of the niches coaxially with each aperture; supporting power plate, and on the supporting platform place emphasis.

They can use a capital in which two niches are arranged symmetrically with respect to its transverse axis, with each side open with three sides open, a support area is placed between the niches coaxially with the transverse axis of the capitals and form an opening in each of the niches, symmetrically above each of the openings relative to the longitudinal axis of the capitals, two support plates are laid one after the other, and an emphasis is placed on the supporting platform.

They can use a capital in which two niches are arranged symmetrically relative to its longitudinal axis, with three open sides each, place a support pad between the niches of the capitals axially to the longitudinal axis and form two openings symmetrically with respect to its transverse axis in each of the niches, while above each of them apertures lay one supporting power plate, and an emphasis is placed on the supporting platform.

A capital can be used, in which four niches are arranged symmetrically with respect to its longitudinal and transverse axes and a cross-shaped support platform is placed between the niches, the rays of which are oriented along the longitudinal and transverse axes of the capital, and an opening communicating with the niche is formed coaxially with its transverse axis , while over each of the openings one support plate is laid, and an emphasis is placed on the reference platform.

They can use the base in the form of a column with two capitals, which are arranged at an angle to each other, while in each capitals coaxially with its transverse axis they arrange one niche with three open sides and form one opening coaxially with the transverse axis of the niche, and on the end plane of the column place a support platform between the niches, on which the emphasis is placed.

The technical result provided by the above set of essential features consists in creating a safe, reliable and controlled method of installing vibration isolators, due to which

- the placement of vibration isolators is ensured both by supporting the edges of the aperture supported by elements of the angular profile, and by compact devices for fixing vibration isolators in a compressed state, which allow quickly and safely replacing the vibration isolator at any time during operation of the building, structure, especially with force majeure exit of the vibration isolators out of order (explosion, fire);

- it makes it possible to install vibration isolators in difficult conditions, for example, with limited one-sided access to power devices, or in walls adjacent to external soil or other internal walls, or when installing vibration isolators at a considerable height from the floor level, on column capitals or in walls under overlappings;

- an additional wall space free from vibration isolators is formed, which is necessary for the internal layout of utilities, highways and devices and the placement of their inputs into the building;

- minimizes the area of niches and openings required to accommodate power devices and vibration isolators, which reduces the additional costs of ensuring the overall strength of the building structure, structures, weakened by the holes needed to install vibration isolators.

The invention is illustrated by drawings in figures 1-30, where X-X is the longitudinal axis of the column, capitals and niches, U ₁ -U ₁ U ₂ -U ₂ , U ₃ -U ₃ are the transverse axis of the niche, columns and capitals, S _1- S ₁ - the longitudinal axis of the openings.

Figure 1 shows a vibration isolator in a niche of the base, in which one opening is connected coaxially with its transverse axis, with one support plate placed under the vibration isolator above the opening coaxially with the longitudinal axis of the opening, a longitudinal section;

figure 2 is a section along aa;

figure 3 shows the vibration isolators in the niche of the base, in which 2 openings are formed, symmetrical with respect to the transverse axis of the niche, and with one supporting power plate laid over each of the openings, a longitudinal section;

figure 4 is a section along BB;

figure 5 shows the vibration isolators in the niche of the base, in which 3 openings are formed, one of which is placed coaxially to the transverse axis of the niche, and the rest is symmetrical to the transverse axis of the niche, and with one supporting power plate laid over each of the openings, a longitudinal section;

figure 6 is a section along BB.

7 shows vibration isolators in a niche of the base, in which one opening is formed, placed coaxially with the transverse axis of the niche, with two supporting force plates laid one above the other symmetrically relative to the longitudinal axis of the niche, a longitudinal section.

In Fig.8 is a section along G-G.

Figure 9 shows the vibration isolators in the niche of the base, in which more than one aperture is formed, with two supporting force plates stacked above each of the apertures, one after the other, symmetrically relative to the longitudinal axis of the niche, a longitudinal section.

Figure 10 is a section along DD.

11 shows a vibration isolator in a recess above an opening communicated with it in the lower section of the wall, having the form of a rib protruding from the base plate of the base, a longitudinal section.

On Fig - section along EE.

On Fig depicts a vibration isolator on a support plate, laid in a niche of the column capitals with one opening formed coaxially with the transverse axis of the niche, with stops on the bearing pads along the edges of the capitals parallel to its transverse axis, a longitudinal section.

On Fig - section along F.

On Fig depicts two vibration isolators on the supporting force plates, stacked one after another in a niche of the column capitals above the opening formed coaxially with the transverse axis of the niche, with stops on the supporting platforms along the edges of the capitals parallel to its transverse axis, a longitudinal section.

In Fig.16 is a section along the II.

17 shows two vibration isolators on supporting power plates laid in two capitals niches, symmetrical with respect to its longitudinal axis, above the openings formed coaxially with the transverse axis of the capitals, with a focus on the supporting platform between the niches placed coaxially with the longitudinal axis of the capitals, longitudinal section.

In Fig.18 is a section along KK.

In Fig.19 is a section along LL.

Figure 20 shows two vibration isolators on supporting power plates laid in two niches, symmetrical with respect to the transverse axis of the capitals, above the openings formed coaxially with the transverse axes of the corresponding niches, with a focus on the supporting platform between the niches, placed coaxially with the transverse axis of the capitals, a longitudinal section.

In Fig.21 is a section along MM.

On Fig depicts four vibration isolators, each on a supporting power plate, installed two in two niches of the capitals, symmetrical about its transverse axis, above the opening in each niche, formed coaxially with its transverse axis and symmetrically about the longitudinal axis of the capitals, with emphasis on the supporting the area between the niches, coaxial transverse axis of the capital, a longitudinal section.

In Fig.23 is a section along N-H.

24 shows four vibration isolators, each on a support plate, mounted in two niches of a capital, symmetrical about its longitudinal axis, above each of the two openings in each niche, symmetrical about its transverse axis, and with an emphasis on the supporting platform between the niches, placed coaxially with the longitudinal axis of the capital, a longitudinal section.

On Fig - section along PP.

On Fig depicts four vibration isolators, each on a supporting power plate, mounted in four niches of the capitals, symmetrical with respect to its longitudinal and transverse axes, above the openings formed coaxially to the transverse axes of the respective niches, with emphasis on the cross-shaped supporting plane between the niches, rays which are oriented along the longitudinal and transverse axes of the capitals, a longitudinal section.

On Fig is a section along the RR.

On Fig depicts two vibration isolators, each on a supporting power plate installed in the respective niches of two capitals of one column located at an angle to each other, above the openings formed coaxially to the transverse axes of the niches, with emphasis on the supporting platform on the end plane of the column between the niches, longitudinal section along CC.

In Fig.29 is a section along the TT.

In Fig.30 is a section along the f-f.

The installation method of vibration isolators is as follows. At the base 1, with at least one niche 2 formed therein, located between the supporting platforms 3, and communicating with its lower part with at least one opening 4, the edges of which are reinforced by the elements of the corner profile 5, stops 6 are installed on the supporting platforms 3, on which erect the upper structure 7. After the erection of the upper structure 7 on the horizontal shelves of the elements of the corner profile 5 coaxially with the longitudinal axis of the opening 4, lay the support plate 8, on which the vibration isolator 9 is placed. In the opening 4 under the support plate 8 of the factory power devices 10 are brought into action, and they compress the vibration isolator 9. After compressing the vibration isolator 9, the supporting elements 11 are installed in the gap between the support power plate 8 and the horizontal shelves of the corner profile elements 5 in the form of a set of gaskets that fix the vibration isolator 9 in a compressed state, after which power devices 10 are removed. After the compression of all vibration isolators 9 of the building, structure, the upper structure 7 by the elastic forces of the vibration isolators 9 is detached from the stops 6, after which the stops 6 are removed, forming a gap between the base 1 and the upper structure 7. On this installation of vibration isolators in the building, structure is considered completed.

At the base 1, a single opening 4 can be formed in the niche 2, which is placed coaxially with the transverse axis of the niche 2, while one support plate 8 is laid over the opening 4.

In the base 1, an even number of openings 4 can be formed in the niche 2, preferably two openings that are placed symmetrically with respect to the transverse axis of the niche 2, while the supporting force plates 8 are laid over each of the openings 4.

At the base 1, an odd number of openings 4 can be formed in the niche 2, preferably three openings, one of which is placed coaxially with the transverse axis of the niche, and the rest are symmetrically with respect to the transverse axis of the niche 2, while the supporting force plates 8 are laid over each of the openings 4.

At the base 1, one opening 4 can be formed in the niche 2, which is placed coaxially with the transverse axis of the niche 2, while two support plates 8 are placed above the opening 4, one after the other, symmetrically with respect to the longitudinal axis of the niche 2.

At the base 1, more than one opening 4 can be formed in the niche 2, and two supporting force plates 8 are placed above each of the openings 4, one after the other, symmetrically with respect to the longitudinal axis of the niche 2.

At the base 1, including the base plate 12 with the lower portion of the wall 13 protruding from it in the form of a rib, at least one niche 2 can be formed with at least one opening 4 connected to it.

In capitals 14 of at least one column 15, which is in the form of an upper part in the base 1, can form at least one niche 2 and at least one opening 4 connected to it.

In the capitals 14, they can form one opening 4 coaxially with the transverse axis of the niche 2 and place supporting pads 3 along the edges of the capitals 14 parallel to its transverse axis, while one support plate 8 is laid over the opening 4, and stops 6 are placed on the supporting pads 3.

In the capitals 14, they can form one aperture 4 coaxially with the transverse axis of the niche 2, while supporting platforms 3 are placed along the edges of the capitals 14 parallel to its transverse axis, two supporting force plates 8 are placed one above the other over the opening 4, and stops are placed on the supporting platforms 3 6.

In the capitals 14, two niches 2 can be arranged symmetrically relative to its longitudinal axis 2 with three open sides each, while a support pad 3 is placed between the niches 2 coaxially to the longitudinal axis of the capitals 3, in each of the niches 2 they form one opening 4, which is arranged coaxially to the transverse axis niches 2, one support plate 8 is placed over each of the openings 4, and an emphasis 6 is placed on the supporting platform 3 between the overlap 16 and the capitals 14.

In the capitals 14, two niches 2 can be arranged symmetrically with respect to its transverse axis 2 with three open sides each, while a support pad 3 is placed between the niches 2 coaxially to the transverse axis of the capitals 14 and form an opening 4 in each of the niches 2, in this case Above each of the openings 4, one support plate 8 is laid, and an emphasis 6 is placed on the support platform 3.

Two niches 2 can be arranged in the capitals 14 symmetrically with respect to its transverse axis 2, each with three open sides, and a support pad 3 is placed between the niches 2 coaxially to the transverse axis of the capitals 14 and form an opening 4 in each of the niches coaxially with its transverse axis, above each the openings 4 coaxially with its longitudinal axis and symmetrically with respect to the longitudinal axis of the capitals 14 lay two supporting force plates 8 one after another, and an emphasis 6 is placed on the supporting platform 3.

In the capitals 14, two niches 2 can be arranged symmetrically with respect to its longitudinal axis 2 with three open sides each, while a niche 3 is placed between the niches 2 coaxially with the longitudinal axis of the capitals 14 and form two openings 4 symmetrically with respect to its transverse axis in each of the niches 2, at the same time, one support plate 8 is laid over each of the openings 4, and an emphasis 6 is placed on the supporting platform 3.

Four niches 2 can be arranged symmetrically with respect to its longitudinal and transverse axes 14 in the capitals 14, while a niche 3 is placed between the niches 2, the cross-shaped support platform 3, the rays of which are oriented along the longitudinal and transverse axes of the capitals 14, and form in each of the niches coaxially with its transverse axis the opening 4, while over each of the openings 4, one support plate 8 is laid, and an emphasis 6 is placed on the supporting platform 3.

In the base 1, in the form of a column 15, two capitals 14 can be arranged, which are arranged at an angle to each other, while in each capitals 14, one niche 2 with three open sides is arranged coaxially with its transverse axis and form one opening coaxially with the transverse axis of the niche 2 4, and on the end plane of the column 15, a support platform 3 is placed between the niches 2, on which the stop 6 is placed.

Claims (16)

1. A method of installing vibration isolators of a building, structure, including installing at least one vibration isolator and power devices in a row between the base and the upper structure temporarily resting on it in each of the open niches formed in one of them from the side facing the other, outside of which stops are placed between the upper structure and the base on the supporting platforms, the vibration isolator is brought into working condition in the niche by compressing it, after which the op is placed between the vibration isolator and the base the components fixing the vibration isolator in a compressed state and remove power devices, and after detaching due to the elastic forces of the vibration isolators of the upper structure, the stops are removed from the base, characterized in that they use a base in the upper part of which at least one open at the top and at least at least one end of the niche, in the lower part of which form at least one opening communicated with the niche and open from at least one end, the edges of which are reinforced with corner profile elements, before at least one support plate with a width B, defined by the dependence (2.0-4.0) C≤B ≤ (0.6-0.9) D, where D = A / N, A - niche width, cm; N is the number of openings communicated with a niche; C is the width of the opening, cm, and the vibration isolator is installed on the base plate, while the power devices are placed in the opening of the base under the base plate, and the supporting elements that fix the vibration isolator in a compressed state are made in the form of a set of gaskets that are placed between the horizontal shelves of the elements corner profile and support power plate. 2. The method according to claim 1, characterized in that they use a base in which one opening is formed, which is placed coaxially with the transverse axis of the niche, and one support plate is laid. 3. The method according to claim 1, characterized in that a base is used in the niche of which an even number of openings is formed, preferably two openings that are placed symmetrically with respect to the transverse axis of the niche, and one support plate is placed over each of the openings. 4. The method according to claim 1, characterized in that a base is used in the niche of which an odd number of openings is formed, preferably three openings, one of which is placed coaxially with the transverse axis of the niche, and the rest are symmetrically relative to the transverse axis of the niche, and above each openings stack one support plate. 5. The method according to any one of claims 1 and 2, characterized in that the base is used, in the niche of which one opening is formed, which is placed coaxially with the transverse axis of the niche, and two supporting force plates are stacked one above the other symmetrically with respect to the longitudinal axis of the niche . 6. The method according to any one of claims 1, 3 and 4, characterized in that two support force plates are stacked one after another symmetrically with respect to the longitudinal axis of the niche above each of the openings. 7. The method according to any one of claims 1 to 6, characterized in that the base is used, including a foundation plate with a lower portion of the wall protruding from it in the form of a rib, and the upper structure in the form of an upper portion of the wall, while arranging in the lower portion of the wall at least one niche with at least one opening connected to it. 8. The method according to any one of claims 1 to 6, characterized in that the base is used in the form of at least one column with a capital in the upper part and the upper structure in the form of an overlap located above the capital, with at least one niche and form at least one opening communicated with it. 9. The method according to claim 8, characterized in that the capitals arrange one niche, form a single opening coaxially with the transverse axis of the niche and place supporting platforms outside the niche along the edges of the capital parallel to its transverse axis, while one support plate is laid over the opening , and on the supporting sites place stops. 10. The method according to claim 8, characterized in that the capitals arrange one niche, form one opening coaxially with the transverse axis of the niche, and place supporting platforms along the edges of the capital parallel to its transverse axis, while two support plates are placed above the opening one after another, and on the supporting sites place stops. 11. The method according to claim 8, characterized in that the capitals arrange two niches symmetrically with respect to its longitudinal axis with three open sides each and coaxially with the longitudinal axis of the capitals place a support platform between the niches, while in each of the niches form one opening, which are arranged coaxially with the transverse axis of the niche, one supporting power plate is placed over each of the openings, and an emphasis is placed on the supporting platform between the upper structure and the base. 12. The method according to claim 8, characterized in that the capitals arrange two niches symmetrically with respect to its transverse axis with three open sides each, place a support pad between the niches coaxially with the transverse axis of the capitals and form in each of the niches coaxially with its transverse axis an aperture, with each of the apertures laying one support plate, and an emphasis is placed on the supporting platform. 13. The method according to claim 8, characterized in that the capitals arrange two niches symmetrically with respect to its transverse axis with three open sides each, place a support pad coaxially with the transverse axis of the capitals between the niches and form a support platform coaxially with each of its niches an opening, while above each of the openings symmetrically with respect to the longitudinal axis of the capitals, two supporting force plates are laid one after the other, and an emphasis is placed on the supporting platform. 14. The method according to claim 8, characterized in that the capitals arrange two niches symmetrically with respect to its longitudinal axis with three open sides each, place a support pad coaxially with the longitudinal axis of the capitals between the niches and form a support platform in each of the niches symmetrically with respect to its transverse axis two openings, while over each of the openings one support plate is laid, and an emphasis is placed on the reference platform. 15. The method according to claim 8, characterized in that the capitals arrange four niches symmetrically with respect to its longitudinal and transverse axes and place a cruciform support plane between the niches, the rays of which are oriented along the longitudinal and transverse axes of the capitals, and coaxially under each of the niches with its transverse axis, an opening is communicated with the niche, while one support plate is laid over each of the openings, and an emphasis is placed on the supporting platform. 16. The method according to any one of claims 1 to 6, characterized in that the base is used in the form of a column with two capitals, which are arranged at an angle to each other, while each capitals coaxially with its transverse axis arrange one niche with three open the lateral sides and form a single opening coaxially with the transverse axis of the niche, and on the end plane of the column, a support platform is placed between the niches, on which the emphasis is placed.

Images