CN214657743U - Plug-in type modularized steel structure seismic isolation and reduction connecting node - Google Patents

Abstract

The utility model provides a plug-in type modular steel structure seismic isolation and reduction connecting node, wherein an upper cross plug-in and a lower cross plug-in are respectively and vertically connected with an upper sealing plate and a lower sealing plate of a lead core rubber seismic isolation support, the side walls of an upper steel pipe module column and a lower steel pipe module column are respectively connected with an H-shaped steel module beam, and the end parts of the upper steel pipe module column and the lower steel pipe module column are respectively sleeved outside the upper cross plug-in and the lower cross plug-in; the upper side cross-shaped plug-in components and the lower side cross-shaped plug-in components have the same structure and comprise cross-shaped components and connecting plates, the cross sections of the cross-shaped components are cross-shaped, the end parts of each side of each cross-shaped component are vertically connected with the connecting plates, and preset distances are reserved between the edges of the adjacent connecting plates; the cross-shaped components and the connecting plates of the upper and lower side cross-shaped plug-in units are respectively connected with the upper and lower side sealing plates; the side walls of the upper and lower steel pipe module columns are respectively connected with the connecting plates of the upper and lower side cross-shaped plug-in units through bolts. The utility model discloses simple structure, prefabrication rate are high, do not need too big operating space just can install fast and have good anti-seismic performance.

Description

Plug-in type modularized steel structure seismic isolation and reduction connecting node

Technical Field

The utility model relates to a building engineering technical field relates to prefabricated cabin antidetonation of modularization steel construction, antidetonation connected node structure between the box steel construction module, especially a bayonet modularization steel construction subtracts shock insulation connected node.

Background

The novel steel structure building has the advantages of high rigidity, light dead weight, short construction period, energy conservation, environmental protection and the like. With the rapid development of the assembly type modular steel structure, the node is the core of the modular building design of the steel structure, and the reliability of the node directly influences the overall safety of the module. Although scholars at home and abroad have already proposed the nodes about steel structure box body buildings or container buildings, the existing node forms need larger operation space and longer connection time, are biased to the connection problem, and do not consider the seismic performance of the connection nodes. Therefore, the connection node form which can be installed quickly and has good anti-seismic performance is adopted, and the key for solving the problems that the modularized steel structure connection node is small in operation space, long in installation time and weak in anti-seismic performance of the node is achieved.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming prior art's is not enough, provides a bayonet modularization steel construction subtracts isolation connected node, and this connected node simple structure, prefabrication rate are high, do not need too big operating space just can install fast and have good anti-seismic performance.

In order to achieve the above purpose, the utility model adopts the technical scheme that:

an inserted modular steel structure seismic mitigation and isolation connecting node comprises a lead rubber seismic isolation support, an upper cross-shaped plug-in, a lower cross-shaped plug-in, an upper steel pipe module column and a lower steel pipe module column, wherein the upper cross-shaped plug-in and the lower cross-shaped plug-in are respectively and vertically connected with an upper sealing plate and a lower sealing plate of the lead rubber seismic isolation support, the upper cross-shaped plug-in is opposite to the lower cross-shaped plug-in, the side walls of the upper steel pipe module column and the lower steel pipe module column are respectively connected with an H-shaped steel module beam, and the end parts of the upper steel pipe module column and the lower steel pipe module column are respectively sleeved outside the upper cross-shaped plug-in and the lower cross-shaped plug-in; the upper cross-shaped insert and the lower cross-shaped insert are identical in structure and comprise cross-shaped components and connecting plates, the cross sections of the cross-shaped components are cross-shaped, the end parts of each edge of each cross-shaped component are vertically connected with the connecting plates, and preset distances are reserved between the edges of the adjacent connecting plates; the cross-shaped components and the connecting plates of the upper cross-shaped plug-in and the lower cross-shaped plug-in are respectively connected with the upper sealing plate and the lower sealing plate; the side wall of the upper steel pipe module column is connected with the connecting plate of the upper cross plug-in unit through a bolt, and the side wall of the lower steel pipe module column is connected with the connecting plate of the lower cross plug-in unit through a bolt.

Preferably, clearance fit is adopted between the inner cavity of the upper steel tube module column and the structure of the enclosure of all the connecting plates of the upper cross-shaped plug-in unit, and clearance fit is adopted between the inner cavity of the lower steel tube module column and the structure of the enclosure of all the connecting plates of the lower cross-shaped plug-in unit.

Preferably, the side walls of the upper steel pipe module column and the lower steel pipe module column are welded with the H-shaped steel module beam.

Preferably, the side walls of the upper steel pipe module column and the lower steel pipe module column are welded with the flange and the web of the H-shaped steel module beam.

Preferably, the side walls of the upper steel pipe module column and the lower steel pipe module column are connected with the H-shaped steel module beam in an equal-strength mode through welding.

Preferably, the upper sealing plate and the lower sealing plate are both provided with extension parts, the end part of the H-shaped steel module beam connected with the upper steel tube module column is connected with the side wall of the upper steel tube module column, and the lower flange of the H-shaped steel module beam is connected with the extension parts of the upper sealing plate through bolts;

the end part of the H-shaped steel module beam connected with the lower steel tube module column is connected with the side wall of the lower steel tube module column, and the upper flange of the H-shaped steel module beam is connected with the extending part of the lower side sealing plate through a bolt.

Preferably, the lower flange of the H-shaped steel module beam connected with the upper steel pipe module column is connected with the extending part of the upper side sealing plate through a unilateral bolt; the upper flange of the end part of the H-shaped steel module beam connected with the lower steel pipe module column is connected with the extending part of the lower side sealing plate through a unilateral bolt.

Preferably, the cross-shaped components and the connecting plates of the upper cross-shaped plug-in and the lower cross-shaped plug-in are respectively welded with the upper sealing plate and the lower sealing plate in equal strength.

Preferably, the width of the connecting plate is less than the inner side length of the upper steel pipe module column and the lower steel pipe module column.

Preferably, the side wall of the upper steel pipe module column is connected with the connecting plate of the upper side cross plug-in unit through a single-side bolt, and the side wall of the lower steel pipe module column is connected with the connecting plate of the lower side cross plug-in unit through a single-side bolt.

Preferably, lead rubber shock insulation support still includes rubber steel plate damper, and last side and the downside shrouding of upside shrouding and downside shrouding are connected with the last side and the downside of rubber steel plate damper respectively.

Preferably, the rubber steel plate damper is located between the upper cross insert and the lower cross insert.

Compared with the prior art, the utility model discloses an advantage and beneficial effect as follows:

the utility model discloses an among the plug-in modularization steel construction seismic isolation and reduction connected node, through setting up upside cross plug-in components and downside cross plug-in components, top steel pipe module post and below steel pipe module post can be assembled through the mode of cover on upside cross plug-in components and downside cross plug-in components respectively, can realize quick installation, need not too big operating space during the installation; the side walls of the upper steel pipe module column and the lower steel pipe module column are respectively connected with an H-shaped steel module beam, so that the beam columns can be prefabricated in a factory, the upper cross-shaped plug-in and the lower cross-shaped plug-in are respectively vertically connected with the upper sealing plate and the lower sealing plate of the lead rubber shock insulation support, and the upper cross-shaped plug-in, the lower cross-shaped plug-in and the lead rubber shock insulation support can be prefabricated in the factory, so that the utility model has high prefabrication rate on the whole; in addition, the lead core rubber shock insulation support is arranged and is integrally positioned between the upper steel pipe module column and the lower steel pipe module column, so that a good shock resistance effect can be achieved; in addition upside cross plug-in components are the same with downside cross plug-in components structure, including cross member and connecting plate, cross member's cross section is the cross, and the equal perpendicular connecting plate that is connected with of every limit tip of cross member, leaves between the edge of adjacent connecting plate and predetermines the distance, consequently the utility model discloses an upside cross plug-in components and downside cross plug-in components are stable in structure on the whole, and anti bending capability is strong, and this structure can also make cross plug-in components have certain power consumption effect through the deformation of cross member and connecting plate simultaneously, has further improved the utility model discloses plug-in modularization steel construction subtracts shock insulation connected node's antidetonation effect.

Furthermore, clearance fit is adopted between the inner cavity of the upper steel pipe module column and the structure of the city enclosed by all the connecting plates of the upper cross plug-in unit, clearance fit is adopted between the inner cavity of the lower steel pipe module column and the structure of the city enclosed by all the connecting plates of the lower cross plug-in unit, and the positioning and installation of the upper steel pipe module column and the lower steel pipe module column can be conveniently realized.

Drawings

FIG. 1: the utility model discloses spatial structure schematic under the decomposition state.

FIG. 2: the utility model discloses spatial structure schematic diagram.

FIG. 3: the utility model discloses the structural schematic of cross lead core rubber shock insulation support plug-in components.

FIG. 4: the utility model discloses lead core rubber shock insulation support's structural schematic.

The steel pipe vibration isolation support comprises an upper steel pipe module column 1, a lower steel pipe module column 2, an upper H-shaped steel module beam 3, a lower H-shaped steel module beam 4, an upper side cross plug-in unit 5, a 5-1 cross component 5-2 connecting plate 6, a lower side cross plug-in unit 7, an upper side sealing plate 8, a lower side sealing plate 78-extending portion 9, a rubber steel plate damper 9, a first single-side bolt 10, a second single-side bolt 11, a lead core rubber vibration isolation support 12, a first bolt hole 13, a second bolt hole 14, a third bolt hole 15, a fourth bolt hole 16, a fifth bolt hole 17, a sixth bolt hole 18, a seventh bolt hole 19, an eighth bolt hole 20 and a cross lead core rubber vibration isolation support plug-in unit 21.

Detailed Description

To further understand the contents and features of the present invention, the following embodiments are listed for the specific explanation of the present invention:

in the description of the present invention, the terms "upper", "lower", "inner", "outer", etc. indicate the orientation and positional relationship based on fig. 1, and are only for convenience of description of the present invention, and it is not necessary that the described devices or members follow the specific orientation and positional relationship. Furthermore, the terms "first," "second," "third," "fourth," "fifth," "sixth," "seventh," "eighth," and the like are merely representative for the purpose of making the described assembly or components more clear and unambiguous, and do not indicate or imply a relative importance relationship between the devices or components.

Referring to fig. 1-3, the utility model discloses plug-in modular steel structure seismic isolation connection node, including lead core rubber seismic isolation support 12, upside cross plug-in 5, downside cross plug-in 6, top steel pipe module post 1 and lower steel pipe module post 2, upside cross plug-in 5 and downside cross plug-in 6 are respectively with lead core rubber seismic isolation support 12 on upside shrouding 7 and downside shrouding 8 all perpendicular connection, upside cross plug-in 5 is just right to downside cross plug-in 6, all be connected with H shaped steel module roof beam on the lateral wall of top steel pipe module post 1 and lower steel pipe module post 2, the tip of top steel pipe module post 1 and lower steel pipe module post 2 is respectively overlapped outside upside cross plug-in 5 and downside cross plug-in 6; the upper cross-shaped plug-in component 5 and the lower cross-shaped plug-in component 6 are identical in structure and comprise cross-shaped components 5-1 and connecting plates 5-2, the cross section of each cross-shaped component 5-1 is cross-shaped, the end part of each edge of each cross-shaped component 5-1 is vertically connected with the connecting plate 5-2, and a preset distance is reserved between the edges of the adjacent connecting plates 5-2; the cross-shaped components 5-1 and the connecting plates 5-2 of the upper cross-shaped insert 5 and the lower cross-shaped insert 6 are respectively connected with an upper sealing plate 7 and a lower sealing plate 8; the side wall of the upper steel pipe module column 1 is connected with the connecting plate 5-2 of the upper cross-shaped plug-in 5 through a bolt, and the side wall of the lower steel pipe module column 2 is connected with the connecting plate 5-2 of the lower cross-shaped plug-in 6 through a bolt.

As the utility model discloses preferred embodiment, be clearance fit between the structure in the city is enclosed to the inner chamber of top steel pipe module post 1 and all connecting plates 5-2 of upside cross plug-in components 5, be clearance fit between the structure in the city is enclosed to the inner chamber of below steel pipe module post 2 and all connecting plates 5-2 of downside cross plug-in components 6.

As the utility model discloses preferred embodiment, weld between the lateral wall of top steel pipe module post 1 and below steel pipe module post 2 and the H shaped steel module roof beam.

As the utility model discloses preferred embodiment, the lateral wall of top steel pipe module post 1 and below steel pipe module post 2 welds with the edge of a wing and the web of H shaped steel module roof beam.

As the utility model discloses preferred embodiment, the equal strength welding between the lateral wall of top steel pipe module post 1 and below steel pipe module post 2 and the H shaped steel module roof beam.

As a preferred embodiment of the present invention, the upper sealing plate 7 and the lower sealing plate 8 are both provided with an extension 78, the end of the H-shaped steel module beam connected to the upper steel tube module column 1 is connected to the side wall of the upper steel tube module column 1, and the lower flange of the H-shaped steel module beam is connected to the extension 78 of the upper sealing plate 7 by a bolt;

the end part of the H-shaped steel module beam connected with the lower steel tube module column 2 is connected with the side wall of the lower steel tube module column 2, and the upper flange of the H-shaped steel module beam is connected with the extending part 78 of the lower side sealing plate 8 through a bolt.

As a preferred embodiment of the present invention, the lower flange of the H-beam module beam connected to the upper steel pipe module column 1 is connected to the extension of the upper side sealing plate 7 by a single-side bolt; the upper flange of the end part of the H-shaped steel module beam connected with the lower steel pipe module column 2 is connected with the extending part of the lower side sealing plate 8 through a unilateral bolt.

As the preferred embodiment of the utility model, the cross-shaped components 5-1 and the connecting plate 5-2 of the upper cross-shaped plug-in 5 and the lower cross-shaped plug-in 6 are equally welded with the upper sealing plate 7 and the lower sealing plate 8 respectively in equal strength.

As the preferred embodiment of the present invention, the width of the connecting plate 5-2 is less than the inner length of the upper steel pipe module column 1 and the lower steel pipe module column 2.

As the utility model discloses preferred embodiment, the lateral wall of top steel pipe module post 1 passes through unilateral bolted connection with connecting plate 5-2 of upside cross plug-in components 5, and the lateral wall of below steel pipe module post 2 passes through unilateral bolted connection with connecting plate 5-2 of downside cross plug-in components 6.

As the preferred embodiment of the present invention, referring to fig. 4, the lead rubber isolation bearing 12 further includes a rubber steel plate damper 9, and the upper side sealing plate 7 and the lower side sealing plate 8 are respectively connected to the upper side and the lower side of the rubber steel plate damper 9.

As a preferred embodiment of the present invention, the rubber steel plate damper 9 is located between the upper cross insert 5 and the lower cross insert 6.

Examples

Fig. 1 is a schematic perspective view of a disassembled state of the present embodiment, fig. 2 is a schematic perspective view of the present embodiment, fig. 3 is a schematic structural view of a cross-shaped lead rubber-vibration-isolating support insert 21 of the present embodiment, and fig. 4 is a schematic view of the lead rubber-vibration-isolating support 12 of the present embodiment. Specifically, as shown in fig. 1 to 2, this embodiment provides an inserted unilateral bolted connection node structure of modularization steel construction, including top steel pipe module post 1, below steel pipe module post 2, go up H shaped steel module roof beam 3, lower H shaped steel module roof beam 4, upside cross plug-in components 5, downside cross plug-in components 6, upside shrouding 7, downside shrouding 8 and rubber steel sheet attenuator 9, on, lower cross plug-in components (5, 6) respectively with last, first unilateral bolt 10 that below steel pipe module post (1, 2) is connected, on, the lower of lower H shaped steel module roof beam (3, 4), go up the flange and last, second unilateral bolt 11 that downside shrouding (7, 8) is connected, lead core rubber isolation bearing 12, cross lead core rubber isolation bearing plug-in components 21. Wherein, top steel pipe module post 1, below steel pipe module post 2, upside cross plug-in components 5, the coaxial setting of downside cross plug-in components 6, as shown in fig. 1, top steel pipe module post 1 is located the top of below steel pipe module 2 post to with upper and lower side cross plug-in components clearance fit, satisfy the construction installation requirement, through first unilateral bolt 10 with upper and lower steel pipe module post (1, 2) and upper and lower downside cross plug-in components (5, 6) fixed connection, wherein upper and lower cross plug-in components (5, 6) are equipped with upper and lower steel pipe module post (1, 2) one-to-one, be used for the bolt hole that first unilateral bolt 10 is connected. As shown in fig. 1, the outer walls of the upper and lower ends of the upper and lower steel pipe module columns (1, 2) are welded to the end portions of the flange webs of the upper and lower H-shaped steel module beams (3, 4), the lower flange of the upper H-shaped steel module beam 3 is fixedly connected to the upper side sealing plate 7 of the lead core rubber vibration isolation support through a second unilateral bolt 11, the upper flange of the lower H-shaped steel module beam 4 is fixedly connected to the lower side sealing plate 8 of the lead core rubber vibration isolation support through a second unilateral bolt 11, wherein the upper and lower side sealing plates (7, 8) of the lead core rubber vibration isolation support 12 are provided with bolt holes which correspond to the flanges of the upper and lower H-shaped steel module beams (3, 4) one by one and are used for connection of the second unilateral bolt 11. The sizes of the first single-sided bolt 10 and the second single-sided bolt 11 and the sizes, the intervals and the number of the arranged bolt holes all meet the relevant standard regulation and the structural requirements of the steel structure design standard GB 50017-2017.

The upper sealing plate 7, the lower sealing plate 8 and the rubber steel plate damper 9 are subjected to high-temperature vulcanization and then lead core pouring to form the lead core rubber vibration isolation support 12 integrally. The upper cross-shaped insert 5 and the lower cross-shaped insert 6 are cast by a factory mold. The lower extreme of upside cross plug-in components 5 welds with 7 upper ends of upside shrouding of lead core rubber isolation bearing 12, and 8 lower extreme weldings of downside shrouding of the upper end lead core rubber isolation bearing 12 of downside cross plug-in components 6, and cross lead core rubber isolation bearing plug-in components are made jointly to upside cross plug-in components, downside cross plug-in components and lead core isolation bearing. The component has simple structure and can be completely prefabricated in a factory.

The outer side lengths (namely the widths of the connecting plates 5-2) of the upper side cross plug-in piece 5 and the lower side cross plug-in piece 6 are respectively smaller than the inner side lengths of the upper steel pipe module column 1 and the lower steel pipe module column 2, so that construction errors are prevented from influencing node installation.

Specifically, the lower end of the upper cross-shaped plug-in piece 5 is in strong connection with the upper end of the upper sealing plate 7 of the lead rubber isolation bearing 12 through welding and the like, and the upper end of the lower cross-shaped plug-in piece 6 is in strong connection with the lower end of the lower sealing plate 9 of the lead rubber isolation bearing 12 through welding and the like. The four walls of the upper cross-shaped insert 5 are provided with first bolt holes 13 through which a plurality of unilateral bolts 10 can pass, the four walls of the lower end of the upper steel pipe module column 1 are provided with second bolt holes 14 corresponding to the first bolt holes 13, and the unilateral bolts 10 penetrate through the first bolt holes 13 and the second bolt holes 14 to fixedly connect the upper cross-shaped insert 5 with the upper steel pipe column 1. The fourth wall of downside cross plug-in components 6 is equipped with and to pass a plurality ofly unilateral bolt 10's third bolt hole 15, 2 upper end four walls of below steel pipe module post set up with the corresponding fourth bolt hole 16 of third bolt hole 15, unilateral bolt 10 runs through third bolt hole 15 and fourth bolt hole 16 with upside cross plug-in components 6 and below steel pipe column 2 fixed connection. The flange and web end of the upper H-shaped steel module beam 3 are welded with the outer wall of the lower end of the upper steel tube module column 1, and the flange and web end of the lower H-shaped steel module beam 4 are welded with the outer wall of the upper end of the lower steel tube module column 2. The upper side sealing plate 7 of the lead rubber isolation support 12 is provided with a plurality of fifth bolt holes 17, the lower flange of the upper H-shaped steel module beam 3 is provided with a plurality of sixth bolt holes 18 opposite to the positions of the fifth bolt holes 17, and the unilateral bolts 11 penetrate through the fifth bolt holes 17 and the sixth bolt holes 18 to fixedly connect the upper side sealing plate 7 of the lead rubber isolation support 12 with the lower flange of the upper H-shaped steel module beam 3. The lower side sealing plate 8 of the lead rubber isolation bearing 12 is provided with a plurality of seventh bolt holes 19, the upper flange of the lower H-shaped steel module beam 4 is provided with a plurality of eighth bolt holes 20 opposite to the seventh bolt holes 19, and the unilateral bolts 11 penetrate through the seventh bolt holes 19 and the eighth bolt holes 20 to fixedly connect the lower side sealing plate 8 of the lead rubber isolation bearing 12 with the upper flange of the lower H-shaped steel module beam 4.

The plug-in type modularized steel structure seismic isolation and reduction connecting node has the following characteristics:

the utility model provides a modularization steel construction connected node, the cross lead core rubber shock insulation support plug-in components 21 that upper and lower side cross plug-in components (5, 6) and lead core rubber shock insulation support 12 are constituteed, but the whole factory is prefabricated, only needs to insert cross lead core rubber shock insulation support plug-in components 21 in the square steel pipe module post from top to bottom, through unilateral bolt in the construction of the module post outside, construction operation space is unrestricted, and construction installation steps is convenient succinct. Because the plug-in components are simple in structure and can be completely prefabricated in factories, the plug-in components can be installed after being transported to the site, the construction process is convenient, and the quick and efficient installation can be realized.

The cross lead core rubber shock insulation support plug-in components 21 are connected with the upper and lower steel pipe module columns (1 and 2) through the unilateral bolts, the overall performance is good, the stability is high, the sizes and the shapes of all the components of the nodes are uniform, the prefabrication rate and the precision are high, and the industrialization degree is high.

This modularization steel construction node considers the anti-seismic performance of node, sets up lead core rubber shock insulation support 12 to with upper and lower side cross plug-in components (5, 6) welding, and then reliably be connected through first, the unilateral bolt of second (10, 11) and upper and lower steel pipe module post (1, 2), upper and lower H shaped steel (3, 4), the node wholeness can be good, and have good anti-seismic performance.

In conclusion, in the plug-in type modular steel structure seismic isolation and reduction connecting node, the upper cross-shaped plug-in piece and the lower cross-shaped plug-in piece are respectively connected with the upper sealing plate and the lower sealing plate of the lead core rubber seismic isolation support in an equal-strength welding mode to form the cross-shaped lead core rubber seismic isolation support plug-in piece which can be prefabricated in a factory, the prefabrication rate is high, the lower module is hoisted in place before connection, then the cross-shaped lead core rubber seismic isolation support plug-in piece is placed, and then the upper module is hoisted; the upper and lower plug-in components of the cross-shaped shock insulation support are connected with the upper and lower steel pipe module columns through the single-sided bolts, the upper and lower H-shaped lower upper steel flanges are connected with the upper and lower side sealing plates of the lead core shock insulation support through the single-sided bolts, the reliable connection of the modules and the plug-in components can be realized through the above measures, the construction can be carried out outside the module columns, the operation space is not limited, the node structure is simple, the rapid construction can be realized, and the good anti-seismic performance is realized.

Although some examples of the present invention have been described in detail, the present invention is not limited to the above-described embodiments. All the equivalent changes and improvements made according to the application scope of the present invention are within the protection scope of the patent covered by the present invention.

Claims (10)

1. The plug-in type modularized steel structure seismic mitigation and isolation connection node is characterized by comprising a lead core rubber seismic isolation support (12), an upper side cross plug-in (5), a lower side cross plug-in (6), an upper steel pipe module column (1) and a lower steel pipe module column (2), wherein the upper side cross plug-in (5) and the lower side cross plug-in (6) are respectively and vertically connected with an upper side sealing plate (7) and a lower side sealing plate (8) of the lead core rubber seismic isolation support (12), the upper side cross plug-in (5) is opposite to the lower side cross plug-in (6), the side walls of the upper steel pipe module column (1) and the lower steel pipe module column (2) are respectively connected with an H-shaped steel module beam, and the end parts of the upper steel pipe module column (1) and the lower steel pipe module column (2) are respectively sleeved outside the upper side cross plug-in (5) and the lower side cross plug-in (6); the upper cross-shaped plug-in (5) and the lower cross-shaped plug-in (6) are identical in structure and comprise cross-shaped components (5-1) and connecting plates (5-2), the cross sections of the cross-shaped components (5-1) are cross-shaped, the end parts of each edge of each cross-shaped component (5-1) are vertically connected with the connecting plates (5-2), and preset distances are reserved between the edges of the adjacent connecting plates (5-2); the cross-shaped components (5-1) and the connecting plates (5-2) of the upper cross-shaped plug-in (5) and the lower cross-shaped plug-in (6) are respectively connected with an upper sealing plate (7) and a lower sealing plate (8); the side wall of the upper steel pipe module column (1) is connected with the connecting plate (5-2) of the upper cross plug-in (5) through a bolt, and the side wall of the lower steel pipe module column (2) is connected with the connecting plate (5-2) of the lower cross plug-in (6) through a bolt.

2. The inserted type modular steel structure seismic isolation and reduction connecting node according to claim 1, characterized in that the inner cavity of the upper steel tube module column (1) is in clearance fit with the structures surrounded by all the connecting plates (5-2) of the upper cross-shaped insert (5), and the inner cavity of the lower steel tube module column (2) is in clearance fit with the structures surrounded by all the connecting plates (5-2) of the lower cross-shaped insert (6).

3. The inserted type modular steel structure seismic isolation and reduction connecting node as claimed in claim 1, wherein the side walls of the upper steel pipe module column (1) and the lower steel pipe module column (2) are welded with the H-shaped steel module beam.

4. The inserted type modular steel structure seismic isolation and reduction connecting node as claimed in claim 3, wherein the side walls of the upper steel pipe module column (1) and the lower steel pipe module column (2) are welded with flanges and webs of the H-shaped steel module beam.

5. The plug-in type modular steel structure seismic isolation and reduction connecting node according to claim 3 or 4, characterized in that the side walls of the upper steel pipe module column (1) and the lower steel pipe module column (2) are connected with the H-shaped steel module beam in an equal strength manner by welding.

6. The inserted type modular steel structure seismic mitigation and isolation connection node as claimed in claim 1 or 3, wherein the upper sealing plate (7) and the lower sealing plate (8) are provided with extension parts, the end part of the H-shaped steel module beam connected with the upper steel pipe module column (1) is connected with the side wall of the upper steel pipe module column (1), and the lower flange of the H-shaped steel module beam is connected with the extension parts of the upper sealing plate (7) through bolts;

the end part of the H-shaped steel module beam connected with the lower steel tube module column (2) is connected with the side wall of the lower steel tube module column (2), and the upper flange of the H-shaped steel module beam is connected with the extending part of the lower side sealing plate (8) through a bolt.

7. The inserted type modular steel structure seismic isolation and reduction connecting node as claimed in claim 6, wherein the lower flange of the H-shaped steel module beam connected with the upper steel pipe module column (1) is connected with the extension part of the upper side sealing plate (7) through a single-side bolt; the upper flange of the end part of the H-shaped steel module beam connected with the lower steel pipe module column (2) is connected with the extension part of the lower side sealing plate (8) through a unilateral bolt.

8. The inserted type modular steel structure seismic isolation and reduction connecting node as claimed in claim 1, wherein the cross-shaped components (5-1) and the connecting plates (5-2) of the upper cross-shaped insert (5) and the lower cross-shaped insert (6) are welded with the upper sealing plate (7) and the lower sealing plate (8) respectively in equal strength.

9. The inserted type modular steel structure seismic isolation and reduction connecting node as claimed in claim 1, wherein the width of the connecting plate (5-2) is smaller than the inner side length of the upper steel pipe module column (1) and the lower steel pipe module column (2).

10. The plug-in type modular steel structure seismic isolation and reduction connecting node as claimed in claim 1, characterized in that the side wall of the upper steel pipe module column (1) is connected with the connecting plate (5-2) of the upper cross-shaped plug-in (5) through a single-side bolt, and the side wall of the lower steel pipe module column (2) is connected with the connecting plate (5-2) of the lower cross-shaped plug-in (6) through a single-side bolt.

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