CN113431184B

CN113431184B - Safe antidetonation multilayer buffering building structure

Info

Publication number: CN113431184B
Application number: CN202110913661.3A
Authority: CN
Inventors: 郑徐平; 郑徐梅; 陈玉潮; 朱光佳; 吴汉辉; 陈郁文; 林智宜; 郑其炼; 杨梁墁; 孙猛; 张强; 年四假; 杨蕾; 张逸伦; 曹锦�
Original assignee: Individual
Current assignee: Individual
Priority date: 2021-08-10
Filing date: 2021-08-10
Publication date: 2022-05-27
Anticipated expiration: 2041-08-10
Also published as: CN113431184A

Abstract

The invention discloses a safe anti-seismic multi-layer buffering building structure, which relates to the technical field of buildings and comprises a fixed bottom plate, wherein the periphery of the top end of the fixed bottom plate is connected with a grounding assembly through threads, the top end of the fixed bottom plate is fixedly connected with a buffering and stabilizing component, one end of the buffering and stabilizing component, which is opposite to the fixed bottom plate, is fixedly connected with a bearing plate, one end of the bearing plate, which is opposite to the buffering and stabilizing component, is fixedly connected with evenly distributed hydraulic shock absorbers, the top end of the hydraulic shock absorber is fixedly connected with a stress assembly, and the top end of the stress assembly is fixedly connected with a stress plate, the integrally formed multiple buffer structure has special function when meeting special conditions such as earthquake and the like, so that the stability of the upper building is better, can effectively prolong the escape time or reduce the damage degree of the building caused by earthquake waves, and is suitable for residents on earthquake zones.

Description

Safe antidetonation multilayer buffering building structure

Technical Field

The invention relates to the field of buildings, in particular to a safe anti-seismic multi-layer buffering building structure.

Background

The building refers to an asset formed by artificial construction, belongs to the category of fixed assets, and comprises two categories of houses and structures. A house is an engineered building for people to live, work, study, produce, manage, entertain, store goods, and perform other social activities. The difference from buildings is structures, which refer to engineering buildings other than houses, such as enclosing walls, roads, dams, wells, tunnels, water towers, bridges, chimneys, and the like. The foundation refers to a bearing structure below the ground of a building, such as a foundation pit, a bearing platform, a frame column, a ground beam and the like, is an enlarged part of a wall or a column of the building underground, and is used for bearing loads transmitted by an upper structure of the building and transmitting the loads and the self-weight to a foundation, and in the building construction, a building foundation anti-seismic bearing structure is usually required to be arranged to maintain the stability of a house.

The most direct concrete placement is around the post in order to reach fixed effect among traditional house construction process, does so and only can play preliminary stable effect, and the effect is relatively poor when special conditions such as earthquake are faced in this kind of mode, and the post is the condition such as buckling easily appears, causes unnecessary economic loss and life danger to appear.

When the earthquake takes place, shear wave and longitudinal wave in the earthquake can lead to the fact huge influence to the building, this moment under the influence of earthquake wave, the building can appear and rock the circumstances such as about and about, traditional bearing structure can't alleviate about and the range of rocking about, cause the quick damage under the influence of earthquake wave of top building, in the earthquake, the house collapses and can lead to the fact fatal injury to personnel in the room, and the house collapses and can influence personnel's in the room flee and the expansion of follow-up rescue work.

Disclosure of Invention

The invention provides a safe anti-seismic multi-layer buffering building structure, which solves the technical problems mentioned above.

In order to solve the technical problems, the safe anti-seismic multilayer buffering building structure provided by the invention comprises a fixed bottom plate, wherein the periphery of the top end of the fixed bottom plate is connected with a grounding assembly through threads, the top end of the fixed bottom plate is fixedly connected with a buffering and stabilizing assembly, one end, back to the fixed bottom plate, of the buffering and stabilizing assembly is fixedly connected with a bearing plate, one end, back to the buffering and stabilizing assembly, of the bearing plate is fixedly connected with hydraulic shock absorbers which are uniformly distributed, the top end of each hydraulic shock absorber is fixedly connected with a stress assembly, the top end of each stress assembly is fixedly connected with a stress plate, the top end of each stress plate is fixedly connected with a frosted buffer cushion which is uniformly distributed, two sides of the bottom end of each stress plate are fixedly connected with expansion plates which are symmetrically distributed, and one ends, back to the stress plates, of the expansion plates are inserted into a supporting sleeve plate.

Preferably, the top end of the sanding buffer pad is higher than the top end of the stress plate, and the side end of the stress assembly and the side end of the bearing plate are in the same vertical plane.

Preferably, the bottom of the inner surface of the supporting sleeve plate is provided with compression springs which are uniformly distributed, and the compression springs are fixedly connected with the bottom end of the telescopic plate.

Preferably, the buffering stabilizing assembly comprises a buffering stress block, a first auxiliary support plate, a top plate, a connecting base, a spring sleeve, a first damping spring, a buffering assembly, a limiting plate and a second damping spring, wherein the buffering stress block is close to the front end fixed connection limiting plate, the top end fixed connection top plate of the buffering stress block is buffered, the bottom end of the top plate is fixedly connected with the auxiliary support plate at the periphery, the top end of the top plate is fixedly connected with the spring sleeve at the periphery, the top end of the top plate is movably connected with the buffering assembly in an inserting mode, the top end of the buffering assembly is fixedly connected with the first damping spring, the first damping spring and the buffering assembly are fixedly connected with the other end of the base in a back mode, and the bottom of the inner surface of the buffering stress block is fixedly connected with the second damping spring.

Preferably, the bottom end of the buffering stress block is fixedly connected with the top end of the fixed bottom plate, the spring sleeve is located right above the auxiliary support plate, and the spring sleeve and the auxiliary support plate are distributed in the same number.

Preferably, one end of the auxiliary support plate is fixedly connected with the top plate, the other end of the auxiliary support plate is fixedly connected with the buffering stress block, and a plurality of groups of damping springs II which are symmetrically distributed are arranged at the bottom of the inner surface of the buffering stress block.

Preferably, the buffer component comprises a supporting block, a movable groove and a stress supporting block, wherein the movable groove is formed at one end of the supporting block close to the front end, and the bottom end of the supporting block is fixedly connected with the stress supporting blocks which are symmetrically distributed.

Preferably, the inner surface of the movable groove is inserted with a limiting plate, and the bottom end of the stress supporting block is fixedly connected with a damping spring II at the bottom of the inner surface of the buffering stress block.

Preferably, the ground connection subassembly is including connecting plate, connecting rod, cavity sleeve, clamping screw, barb, connection ring and threaded rod, wherein the top fixed connection cavity sleeve of connecting plate, the telescopic top of cavity is pegged graft the swing joint connecting rod, the below of connecting plate sets up clamping screw, clamping screw's bottom fixed connection ring, connect the two sets of barbs of the vertical distribution of surface fixed connection of ring, and connect ring and clamping screw one end fixed connection threaded rod mutually back of the body mutually.

Preferably, the connecting plate is keeping away from hollow sleeve one end and supplementary extension board fixed connection, hollow sleeve's internal surface fixedly connected with compression spring, the barb is the equidistant setting that distributes.

Compared with the related art, the safe anti-seismic multi-layer buffering building structure provided by the invention has the following beneficial effects:

the invention provides a safe anti-seismic multilayer buffering building structure, and the integrally formed multiple buffering structure has a special effect when meeting special conditions such as an earthquake and the like, so that the stability of a building above the structure is better, the escape time can be effectively prolonged or the damage degree of the building caused by earthquake waves can be effectively reduced, and the safe anti-seismic multilayer buffering building structure is suitable for residents on an earthquake zone.

The invention provides a safe anti-seismic multi-layer buffering building structure.A buffering stabilizing component is used as a main buffering structure for bearing upper vibration, plays a great role in buffering and damping, plays a role in supporting and stabilizing the whole body, is a whole gravity center point, and has a certain buffering effect when facing different degrees of vibration if the gravity center point has a problem, so that the buffering stabilizing component cannot play a role in buffering and damping and is easy to shake.

The invention provides a safe anti-seismic multilayer buffering building structure, wherein a grounding component can penetrate into the soil layer to play an additional role in reinforcing and supporting the multilayer buffering building structure, a fixing screw rod can penetrate into the soil layer more and more to play a role in reinforcing when the pressure above the fixing screw rod is higher, and after a buffering stabilizing component with a downward force disappeared moves downwards, the bottom end of a hollow sleeve is separated from the top end of the fixing screw rod and keeps a proper distance.

Drawings

FIG. 1 is a schematic view of the overall structure of a safe earthquake-resistant multi-storey buffering building structure;

FIG. 2 is a schematic structural view of a safe earthquake-resistant multi-storey buffering building structure in elevation;

FIG. 3 is a schematic structural view of a buffering and stabilizing component of a safe earthquake-resistant multi-story buffering building structure;

FIG. 4 is a schematic sectional view of a structural stabilizing component of a safe earthquake-resistant multi-story buffering building;

FIG. 5 is a schematic view of a structural buffer assembly of a safe earthquake-resistant multi-story buffer building structure;

fig. 6 is a schematic structural view of a grounding assembly of a safe earthquake-resistant multi-layer buffering building structure.

Reference numbers in the figures: 1. a stress plate; 2. a frosted buffer pad; 3. a force-bearing component; 4. a hydraulic shock absorber; 5. a bearing plate; 6. a buffer stabilizing assembly; 7. fixing the bottom plate; 8. a ground component; 9. a support sleeve plate; 10. a retractable plate; 61. a buffer stress block; 62. an auxiliary support plate; 63. a top plate; 64. connecting a base; 65. a spring sleeve; 66. a first damping spring; 67. a buffer assembly; 68. a limiting plate; 69. a second damping spring; 671. a support block; 672. a movable groove; 673. a stressed support block; 81. a connecting plate; 82. a connecting rod; 83. a hollow sleeve; 84. fixing the screw rod; 85. a barb; 86. connecting the circular rings; 87. a threaded rod.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments; all other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

In the first embodiment, as shown in fig. 1-2, the safe earthquake-resistant multi-layer buffer building structure of the invention comprises a fixed bottom plate 7, a grounding component 8 is connected with the periphery of the top end of the fixed bottom plate 7 through threads, and the top end of the fixed bottom plate 7 is fixedly connected with a buffering and stabilizing component 6, one end of the buffering and stabilizing component 6, which is opposite to the fixed bottom plate 7, is fixedly connected with a bearing plate 5, one end of the bearing plate 5, which is opposite to the buffering and stabilizing component 6, is fixedly connected with evenly distributed hydraulic shock absorbers 4, the top end of the hydraulic shock absorbers 4 is fixedly connected with a stress component 3, the top end of the stress component 3 is fixedly connected with a stress plate 1, the top end of the stress plate 1 is fixedly connected with evenly distributed frosted buffer pads 2, the two sides of the bottom end of the stress plate 1 are fixedly connected with symmetrically distributed expansion plates 10, and one end of each expansion plate 10, which is opposite to the stress plate 1, is inserted into the support sleeve plate 9;

second embodiment, on the basis of the first embodiment, according to fig. 3 to 5, the buffering and stabilizing assembly 6 includes a buffering and force-bearing block 61, an auxiliary support plate 62, a top plate 63, a connecting base 64, a spring sleeve 65, a first damping spring 66, a buffering assembly 67, a limiting plate 68 and a second damping spring 69, wherein the front end of the buffering stress block 61 is fixedly connected with a limit plate 68, the top end of the buffering stress block 61 is fixedly connected with a top plate 63, the peripheral positions of the bottom end of the top plate 63 are fixedly connected with auxiliary support plates 62, the spring sleeves 65 are fixedly connected to the periphery of the top end of the top plate 63, the top end of the top plate 63 is movably connected with the buffer assembly 67 in an inserted mode, the top end of the buffer assembly 67 is fixedly connected with the uniformly distributed first damping springs 66, one ends, opposite to the buffer assembly 67, of the first damping springs 66 are fixedly connected with the base 64, and the bottom of the inner surface of the buffer stress block 61 is fixedly connected with the second damping springs 69;

the buffer assembly 67 comprises a supporting block 671, a movable groove 672 and a stressed supporting block 673, wherein the movable groove 672 is formed at the front end of the supporting block 671, and the bottom ends of the supporting block 671 are fixedly connected with the stressed supporting blocks 673 which are symmetrically distributed;

third embodiment, on the basis of the first and second embodiments, according to fig. 6, the grounding assembly 8 includes a connecting plate 81, a connecting rod 82, a hollow sleeve 83, a fixing screw 84, barbs 85, a connecting ring 86 and a threaded rod 87, wherein the top end of the connecting plate 81 is fixedly connected with the hollow sleeve 83, the top end of the hollow sleeve 83 is inserted into the movable connecting rod 82, the fixing screw 84 is arranged below the connecting plate 81, the bottom end of the fixing screw 84 is fixedly connected with the connecting ring 86, the outer surface of the connecting ring 86 is fixedly connected with the two sets of barbs 85 which are vertically distributed, and the connecting ring 86 is fixedly connected with the threaded rod 87 at the end opposite to the fixing screw 84.

The working principle is as follows:

in specific implementation, the sanding buffer pads 2 and the stress plate 1 bear pressure from above, when the pressure reaches the position, the evenly distributed sanding buffer pads 2 firstly spread the pressure from above and transmit the pressure to the stress plate 1, the stress plate 1 drives the expansion plate 10 to move downwards, at the moment, the compression springs in the support sleeve plate 9 retract and absorb the pressure, when the expansion plate 10 moves downwards, the stress plate 1 transmits main vibration to the stress component 3 and the hydraulic shock absorber 4, when the vibration reaches the evenly distributed hydraulic shock absorber 4, the evenly distributed hydraulic shock absorber 4 recovers the vibration through retraction, so that the vibration amplitude above obtains a certain degree of attenuation, the rest force is transmitted to the bearing plate 5 and the buffering and stabilizing component 6, the buffering and stabilizing component 6 absorbs the pressure through retraction again, the earthquake from the building is further weakened, the whole building is reinforced by the grounding assemblies 8 at the positions around the fixed bottom plate 7, the grounding assemblies 8 improve the stability of the whole building, the connection degree of the whole building and the ground is more stable, the stability in the earthquake is enhanced, the problem of high use limitation caused by a single fixed structure is avoided, the whole building absorbs the possible earthquake through a multi-layer damping structure, and has a strong buffering and earthquake-proof effect, and the multi-layer damping structure has a special effect in special conditions such as earthquake and the like, so that the stability of the building above is better, the escape time can be effectively prolonged, or the damage degree of the building caused by earthquake waves is reduced, and the building is suitable for being used by residents in an earthquake zone;

when the vibration above is transmitted to the buffering stabilizing component 6, the connecting base 64 and the spring sleeve 65 firstly contact with the upper side and absorb and feed back the force, the spring sleeve 65 at the peripheral position can reduce the descending speed of the connecting base 64, play a role in buffering and shock absorption, and prevent the problem of overlarge impact force caused by the overhigh reaction speed of the connecting base 64, after the impact force is absorbed by the spring sleeve 65 at the peripheral position, the force reaches the first damping spring 66 through the connecting base 64, the first damping spring 66 absorbs the force through compression and transmits the force to the buffering component 67, the buffering component 67 drives the movable groove 672 and the stressed branch block 673 to move downwards after being stressed, because the bottom end of the stressed branch block 673 is connected with the second damping spring 69, the second damping spring 69 can absorb and buffer the force transmitted by the stressed branch block 673, and the limiting plate 68 at the front end of the buffering stressed block 61 limits the descending range of the buffering component 67, the limiting plate 68 penetrates through the buffering stress block 61 and is inserted into the movable groove 672, so that the maximum rising range and the maximum falling range of the buffering assembly 67 are limited, excessive force is prevented from being transmitted to a lower position through the buffering assembly 67, the transmitted vibration is greatly attenuated after repeated rebound buffering of the buffering assembly 67 and the damping spring II 69, the buffering and stabilizing assembly 6 is used as a main buffering structure for bearing upper vibration, the great buffering and damping effect is achieved, the integral supporting and stabilizing effect is achieved, if the gravity center point is integral, the gravity center point has problems, the buffering and damping effect cannot be achieved, the self vibration is easy to occur, the buffering and stabilizing assembly 6 has a certain buffering effect when facing different degrees of vibration through a multi-layer sustainable buffering structure, and partial impact force can be counteracted through free rebound, the supporting and buffering functions are met;

the grounding component 8 plays a role in reinforcing the whole installation, the grounding component 8 is buried in a foundation when in use, the foundation is used as a foundation structure of a building and plays a vital role in the whole stability, the grounding component 8 can deeply penetrate into the soil layer to play an additional role in reinforcement and support, the fixing screw 84 and the barb 85 are driven to rotate when in use, the threaded rod 87 is inserted into the soil layer, the barb 85, the connecting ring 86 and the threaded rod 87 are driven to deeply penetrate into the soil through continuous rotation, in the rotating process, the contact area of the barb 85 and the soil is enlarged, the connection between the barb 85 and the soil is firmer, when the fixing screw 84, the barb 85, the connecting ring 86 and the threaded rod 87 are deeply installed in the soil, at the moment, the top end of the connecting rod 82 is connected with the auxiliary support plate 62, and when the buffering stabilizing component 6 moves downwards due to the vibration transmitted from the upper part, the hollow sleeve 83 is in contact with the top end of the fixed screw 84 and continuously transmits the downward force from the upper part to the fixed screw 84, so that the barb 85, the connecting ring 86 and the threaded rod 87 are deeper into the soil, the higher the pressure of the upper part is, the deeper the fixed screw 84 is, the soil is reinforced, and after the downward force disappears, the buffering and stabilizing component 6 moves downwards, the bottom end of the hollow sleeve 83 is separated from the top end of the fixed screw 84 and keeps a proper distance.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

Although embodiments of the present invention have been shown and described, it will be appreciated by those skilled in the art that changes, modifications, substitutions and alterations can be made in these embodiments without departing from the principles and spirit of the invention, the scope of which is defined in the appended claims and their equivalents.

Claims

1. The utility model provides a safe antidetonation multilayer buffering building structure, includes PMKD (7), its characterized in that: the periphery of the top end of the fixed bottom plate (7) is connected with a grounding component (8) through threads, the top end of the fixed bottom plate (7) is fixedly connected with a buffering and stabilizing component (6), one end of the buffering and stabilizing component (6) opposite to the fixed bottom plate (7) is fixedly connected with a bearing plate (5), one end of the bearing plate (5) opposite to the buffering and stabilizing component (6) is fixedly connected with evenly distributed hydraulic shock absorbers (4), the top end of the hydraulic shock absorber (4) is fixedly connected with a stressed component (3), the top end of the stress component (3) is fixedly connected with a stress plate (1), the top end of the stress plate (1) is fixedly connected with evenly distributed frosted buffer pads (2), and both sides of the bottom end of the stress plate (1) are fixedly connected with symmetrically distributed expansion plates (10), one end of the expansion plate (10), which is opposite to the stress plate (1), is inserted into the support sleeve plate (9);

the buffering stabilizing component (6) comprises a buffering stress block (61), an auxiliary support plate (62), a top plate (63), a connecting base (64), a spring sleeve (65), a damping spring I (66), a buffering component (67), a limiting plate (68) and a damping spring II (69), wherein the buffering stress block (61) is close to a front end fixedly connected with the limiting plate (68), the top end of the buffering stress block (61) is fixedly connected with the top plate (63), the bottom end peripheral positions of the top plate (63) are fixedly connected with the auxiliary support plate (62), the top end peripheral positions of the top plate (63) are fixedly connected with the spring sleeve (65), the top end of the top plate (63) is inserted with the movably connected buffering component (67), the top end of the buffering component (67) is fixedly connected with the uniformly distributed damping spring I (66), and the damping spring I (66) is back to the end of the buffering component (67) and is fixedly connected with the connecting base (64), the bottom of the inner surface of the buffering stress block (61) is fixedly connected with a second damping spring (69);

the bottom end of the buffering stress block (61) is fixedly connected with the top end of the fixed bottom plate (7), the spring sleeve (65) is positioned right above the auxiliary support plate (62), and the number of the spring sleeve are the same;

one end of the auxiliary support plate (62) is fixedly connected with the top plate (63), the other end of the auxiliary support plate (62) is fixedly connected with the buffering stress block (61), and a plurality of groups of damping springs II (69) which are symmetrically distributed are arranged at the bottom of the inner surface of the buffering stress block (61);

the buffer assembly (67) comprises a supporting block (671), a movable groove (672) and a stressed supporting block (673), wherein the movable groove (672) is formed in the front end of the supporting block (671), and the bottom ends of the supporting block (671) are fixedly connected with the stressed supporting block (673) which are symmetrically distributed.

2. A safe earthquake-resistant multi-layer buffering building structure as claimed in claim 1, wherein the top of said sanding buffer pad (2) is at a higher level than the top of the stress plate (1), and the side end of said stress component (3) and the side end of the bearing plate (5) are in the same vertical plane.

3. A safe earthquake-resistant multi-storey buffer building structure according to claim 1, wherein the bottom of the inner surface of the support sleeve plate (9) is provided with compression springs which are evenly distributed and fixedly connected with the bottom end of the expansion plate (10).

4. A safe anti-seismic multi-layer buffering building structure according to claim 1, wherein a limiting plate (68) is inserted into the inner surface of the movable groove (672), and the bottom end of the stressed branch block (673) is fixedly connected with a second damping spring (69) at the bottom of the inner surface of the buffering stressed block (61).

5. A safe earthquake-resistant multi-layer buffering building structure according to claim 1, characterized in that the grounding assembly (8) comprises a connecting plate (81), a connecting rod (82), a hollow sleeve (83), a fixing screw (84), barbs (85), a connecting ring (86) and a threaded rod (87), wherein the top end of the connecting plate (81) is fixedly connected with the hollow sleeve (83), the top end of the hollow sleeve (83) is inserted with the movably connected connecting rod (82), the fixing screw (84) is arranged below the connecting plate (81), the bottom end of the fixing screw (84) is fixedly connected with the connecting ring (86), the outer surface of the connecting ring (86) is fixedly connected with two sets of barbs (85) which are vertically distributed, and the connecting ring (86) is fixedly connected with the threaded rod (87) at one end opposite to the fixing screw (84).

6. A safe earthquake-resistant multi-layer buffering building structure according to claim 5, wherein the connecting plate (81) is fixedly connected with the auxiliary support plate (62) at one end far away from the hollow sleeve (83), a compression spring is fixedly connected with the inner surface of the hollow sleeve (83), and the barbs (85) are arranged in an equidistant distribution.