CN116145839A

CN116145839A - Energy-saving building assembled wall anti-seismic mechanism

Info

Publication number: CN116145839A
Application number: CN202211110551.4A
Authority: CN
Inventors: 胡希冀
Original assignee: Chengde Petroleum College
Current assignee: Chengde Petroleum College
Priority date: 2022-09-13
Filing date: 2022-09-13
Publication date: 2023-05-23
Anticipated expiration: 2042-09-13
Also published as: CN116145839B

Abstract

The invention belongs to the technical field of assembly type buildings, and discloses an energy-saving building assembly type wall anti-seismic mechanism, which is technically characterized in that: including the plywood, the plywood both sides are provided with respectively and erect the wall, plywood fixed mounting has multiunit fixed column, erect the wall towards seting up with the fixed column mutually supporting fixed slot, erect wall and be provided with anti-seismic mechanism in the plywood jointly, anti-seismic mechanism is including strengthening post, accomodate subassembly, flexible subassembly and control assembly, control assembly is including drive division and automatic control portion, through setting up by strengthening post, accomodate subassembly, flexible subassembly, drive division, the anti-seismic mechanism and fixed column, the fixed slot mutually supporting that automatic control portion constitutes, can further improve the shock resistance who erects wall and plywood when erecting wall and plywood and take place vibrations, effectively improve the stability of erecting wall and plywood.

Description

Energy-saving building assembled wall anti-seismic mechanism

Technical Field

The invention relates to the technical field of assembled buildings, in particular to an energy-saving building assembled wall anti-seismic mechanism.

Background

With the rapid development of modern industrial technology, the construction industry is beginning to change over the sky and over the earth. The speed block for constructing the assembled building is low in production cost, and the assembled building is widely applied.

The composite wall body of the keel sheet material, the paper grass board, the color steel heat preservation material coreboard, the honeycomb coreboard and the like are all wall materials. Wall material is an important part of building construction material because it is the basic material that makes up the building.

The assembled building is mainly formed by splicing and fixing a plurality of assembled parts through various fixing parts, and compared with a reinforced concrete building, the prior assembled building has poor earthquake resistance, is easy to deform and even topple when encountering geological disasters such as earthquakes, and cannot guarantee personal safety of users.

Disclosure of Invention

The invention aims to provide an energy-saving building assembled wall anti-seismic mechanism so as to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions:

the utility model provides an energy-conserving building assembled wall antidetonation mechanism, includes the plywood, the plywood both sides are provided with perpendicular wall respectively, the lateral wall fixed mounting of plywood orientation perpendicular wall has multiunit fixed column, perpendicular wall orientation lateral wall of plywood has seted up the fixed slot of mutually supporting with the fixed column, perpendicular wall installs fixed subassembly jointly with the both sides wall that the plywood links to each other, be provided with antidetonation mechanism jointly in perpendicular wall and the plywood, antidetonation mechanism is including strengthening column, accomodate subassembly, telescopic assembly and control assembly, accomodate the subassembly and be located the fixed column and be connected with the strengthening column, accomodate the subassembly and be used for accomodating the strengthening column in the fixed column, telescopic assembly is located the fixed column and be connected with accomodating the subassembly, telescopic assembly is used for mutually supporting with accomodating the subassembly and then promotes the strengthening column and remove outward towards the fixed column, control assembly is including drive portion and automatic control portion, drive portion is used for mutually supporting and then controls the strengthening column with telescopic assembly, automatic control portion is located and is connected with drive portion, the drive portion is used for monitoring the amplitude of vibration portion and then is used for starting the plywood to the plywood.

As a further scheme of the invention: the fixing assembly comprises two groups of placing grooves which are respectively formed in two side walls of the vertical wall connected with the laminate, L-shaped plates are jointly placed in the two groups of placing grooves, and a plurality of groups of bolts which are respectively connected with the vertical wall and the laminate in a threaded manner are connected to the surfaces of the L-shaped plates.

As a further scheme of the invention: the storage assembly comprises a fixed cavity formed in the fixed column, the fixed cavity is of a vertical strip-shaped structure, a mounting plate is slidably connected in the fixed cavity, the reinforcing column is located in the fixed cavity, one end, close to the laminate, of the reinforcing column is fixedly connected with the mounting plate, one end, far away from the laminate, of the reinforcing column is arranged into a pointed structure, and the mounting plate is connected with the telescopic assembly.

As a further scheme of the invention: the telescopic component comprises a threaded rod rotationally installed in the fixing cavity, the threaded rod is in threaded connection with the mounting plate, a fixing hole communicated with the fixing cavity is formed in the side wall of the fixing column, far away from the laminate, of the fixing column, the fixing hole and the reinforcing column are located at the same axis, and the threaded rod is connected with the transmission part.

As a further scheme of the invention: the driving part comprises a driving cavity formed in the laminate, the threaded rod extends into the driving cavity towards one end of the laminate and is fixedly connected with a driven inclined fluted disc, a motor is fixedly installed in the driving cavity, an output shaft of the motor is fixedly installed with a driving inclined fluted disc which is meshed and connected with the driven inclined fluted disc, and the motor is connected with the automatic control part.

As a further scheme of the invention: the automatic control part comprises a control cavity formed in the laminate, a controller is fixedly arranged in the control cavity, the controller is electrically connected with the motor, a box-shaped fixing shell is fixedly arranged in the control cavity, a detection ball is placed in the fixing shell, a pressure sensor matched with the detection ball is fixedly arranged on the inner side wall and the inner bottom wall of the fixing shell respectively, and the pressure sensor is electrically connected with the controller.

As a further scheme of the invention: the reinforced column is internally provided with a reinforced part, the reinforced part comprises a plurality of groups of vertical grooves formed in the side wall of the reinforced column, the reinforced rod is rotationally installed in the vertical grooves, the movable end of the reinforced rod is arranged into a pointed structure, the reinforced column is internally provided with a unidirectional positioning part matched with the reinforced rod, and the unidirectional positioning part is used for adjusting the position of the reinforced rod when the reinforced column moves.

As a further scheme of the invention: the unidirectional positioning portion comprises a mounting groove which is formed in the reinforcing column and communicated with the vertical groove, a support is fixedly connected in the mounting groove, and an extrusion spring matched with the reinforcing rod is fixedly arranged on the surface of the support.

As still further aspects of the invention: and a reinforcing plate which is in sliding connection with the reinforcing column is fixedly arranged in the fixing cavity.

Compared with the prior art, the invention has the beneficial effects that: through setting up by reinforcing column, accomodate subassembly, telescopic link, drive division, automatic control portion constitute antidetonation mechanism and fixed column, fixed slot mutually support, can further improve the shock resistance of erecting wall and plywood when erecting wall and plywood and take place to shake, effectively improve the stability of erecting wall and plywood, it is relatively poor to have solved current fabricated building and reinforced concrete building, the shock resistance, when encountering geological disasters such as earthquake, easy deformation is emptyd even, can't guarantee user's personal safety's problem.

Drawings

Fig. 1 is a schematic structural view of an assembled wall earthquake-proof mechanism of an energy-saving building provided in an embodiment of the invention.

Fig. 2 is an enlarged schematic view of the structure of fig. 1 a.

Fig. 3 is an enlarged schematic view of the structure B in fig. 1.

Fig. 4 is a schematic structural diagram of what is in an energy-saving building assembled wall earthquake-proof mechanism according to an embodiment of the present invention.

Wherein: vertical wall 1, laminate 2, fixed column 3, fixed slot 4, fixed assembly 5, placement slot 51, L-shaped plate 52, bolt 53, anti-vibration mechanism 6, reinforcing column 61, storage assembly 62, fixed cavity 621, mounting plate 622, telescoping assembly 63, threaded rod 631, fixed hole 632, control assembly 64, transmission 641, driving cavity 6411, motor 6412, driven helical gear 6413, driving helical gear 6414, automatic control portion 642, control cavity 6421, controller 6422, fixed case 6423, pressure sensor 6424, detection ball 6425, reinforcing portion 7, vertical slot 71, reinforcing rod 72, unidirectional positioning portion 8, mounting slot 81, bracket 82, compression spring 83, reinforcing plate 9.

Detailed Description

It should be noted that, without conflict, the embodiments of the present invention and features of the embodiments may be combined with each other.

Specific implementations of the invention are described in detail below in connection with specific embodiments.

As shown in fig. 1, a structure diagram of an energy-saving building assembled wall anti-seismic mechanism according to an embodiment of the invention is provided, the structure diagram comprises a laminate 2, vertical walls 1 are respectively arranged at two sides of the laminate 2, a plurality of groups of fixing columns 3 are fixedly installed at the side walls of the laminate 2 facing the vertical walls 1, fixing grooves 4 mutually matched with the fixing columns 3 are formed at the side walls of the vertical walls 1 facing the laminate 2, fixing assemblies 5 are jointly installed at two side walls of the vertical walls 1 connected with the laminate 2, an anti-seismic mechanism 6 is jointly arranged in the vertical walls 1 and the laminate 2, the anti-seismic mechanism 6 comprises a reinforcing column 61, a containing assembly 62, a telescopic assembly 63 and a control assembly 64, the containing assembly 62 is located in the fixing columns 3 and connected with the reinforcing column 61, the telescopic assembly 62 is located in the fixing columns 3 and connected with the containing assembly 62, the telescopic assembly 63 is used for mutually matched with the containing assembly 62 so as to push the reinforcing column 61 to move towards the outside of the fixing columns 3, the control assembly 64 comprises a transmission part 641 and a telescopic part 641, the transmission part 641 is automatically matched with the transmission part 641, and the transmission part 641 is further connected with the transmission part 641, and the transmission part is automatically controlled by the transmission part 641, and the transmission part is connected with the transmission part 641, and the transmission part is automatically is controlled by the transmission part and the transmission part is automatically and the transmission is controlled by the transmission and the transmission.

When the vertical wall 1 and the laminate 2 are assembled, the vibration intensity received by the laminate 2 can be monitored in real time through the automatic control part 642 automatically when the vibration intensity reaches a certain degree, the automatic control part 642 automatically controls the transmission part 641 to start, the transmission part 641 and the telescopic component 63 and the storage component 62 are mutually matched, the reinforcement column 61 in the fixed column 3 can be conveniently controlled to move towards the outer side of the fixed column 3, one end of the reinforcement column 61 extends into the vertical wall 1 from the fixed column 3, the stability of the vertical wall 1 can be further improved, and the deformation and even tilting of the vertical wall 1 and the laminate 2 in vibration can be effectively avoided.

As shown in fig. 2, as a preferred embodiment of the present invention, the fixing assembly 5 includes placement grooves 51 formed on two side walls of the vertical wall 1 connected to the laminate 2, respectively, two sets of L-shaped plates 52 are placed in the placement grooves 51 together, and a plurality of sets of bolts 53 screwed to the vertical wall 1 and the laminate 2 are screwed to the surface of the L-shaped plates 52.

After preliminary joint fixed to perpendicular wall 1 and plywood 2 through fixed column 3 and fixed slot 4 mutually support, install L template 52 in fixed slot 4 and fixed column 3 two sets of standing grooves 51 adjacent, corresponding screw hole has been seted up in the fixed slot 4, at L template 52 surface screw thread installation multiunit bolt 53, multiunit bolt 53 respectively with perpendicular wall 1 and plywood 2 threaded connection, L template 52 can further be fixed perpendicular wall 1 and plywood 2, effectively improves the stability of perpendicular wall 1 and plywood 2.

As shown in fig. 2, as a preferred embodiment of the present invention, the accommodating assembly 62 includes a fixing cavity 621 formed inside the fixing column 3, the fixing cavity 621 is of a vertically elongated structure, a mounting plate 622 is slidably connected in the fixing cavity 621, the reinforcing column 61 is located in the fixing cavity 621, one end of the reinforcing column 61 near the laminate 2 is fixedly connected with the mounting plate 622, one end of the reinforcing column 61 far from the laminate 2 is provided with a pointed structure, and the mounting plate 622 is connected with the telescopic assembly 63.

In use, the mounting plate 622 is located at one end of the fixing cavity 621, which is close to the laminate 2, the mounting plate 622 controls the whole reinforcing column 61 to be located in the fixing cavity 621 inside the fixing column 3, and the fixing cavity 621 can store the reinforcing column 61 for a long time.

As shown in fig. 2, as a preferred embodiment of the present invention, the telescopic assembly 63 includes a threaded rod 631 rotatably installed in the fixing cavity 621, the threaded rod 631 is in threaded connection with the mounting plate 622, a side wall of the fixing post 3 away from the laminate 2 is inwardly provided with a fixing hole 632 communicated with the fixing cavity 621, the fixing hole 632 is located at the same axis position as the reinforcing post 61, and the threaded rod 631 is connected with the transmission part 641.

When vibration needs to be further reinforced to the vertical wall 1 and the laminate 2, the transmission part 641 drives the threaded rod 631 to rotate in the fixed cavity 621, the threaded rod 631 drives the mounting plate 622 to move in the fixed cavity 621 along the direction of the threaded rod 631 through threaded transmission with the mounting plate 622, the mounting plate 622 drives the reinforcing column 61 to move in the moving process, and then the reinforcing column 61 can be conveniently pushed to the outer side of the fixed column 3 through the fixing hole 632 and inserted into the vertical wall 1, so that the stability of the vertical wall 1 can be effectively improved.

As shown in fig. 2, as a preferred embodiment of the present invention, the transmission part 641 includes a driving cavity 6411 formed inside the laminate 2, the threaded rod 631 extends into the driving cavity 6411 toward one end of the laminate 2 and is fixedly connected with a driven bevel gear 6413, a motor 6412 is fixedly installed in the driving cavity 6411, an output shaft of the motor 6412 is fixedly installed with a driving bevel gear 6414 in meshed connection with the driven bevel gear 6413, and the motor 6412 is connected with the automatic control part 642.

When the vibration needs to be reinforced to the vertical wall 1 during use, the automatic control part 642 automatically starts the motor 6412, the motor 6412 drives the driving helical gear disk 6414 to rotate and then drives the driven helical gear disk 6413 through the driving helical gear disk 6414 in a meshed manner, the threaded rod 631 can be conveniently controlled to rotate, and the threaded rod 631 and the mounting plate 622 are in threaded transmission so as to drive the mounting plate 622 to move along the direction of the threaded rod 631 in the fixing cavity 621.

As shown in fig. 2, as a preferred embodiment of the present invention, the automatic control portion 642 includes a control chamber 6421 formed inside the laminate 2, a controller 6422 is fixedly installed in the control chamber 6421, the controller 6422 is electrically connected with the motor 6412, a box-shaped fixing case 6423 is fixedly installed in the control chamber 6421, a detection ball 6425 is placed in the fixing case 6423, pressure sensors 6424 mutually matched with the detection ball 6425 are fixedly installed on an inner side wall and an inner bottom wall of the fixing case 6423, and the pressure sensors 6424 are electrically connected with the controller 6422.

When the floor shakes to drive the laminate 2 to vibrate, the detection ball 6425 in the laminate 2 shakes in the fixed shell 6423, the detection ball 6425 shakes in the fixed shell 6423 to enable the detection ball 6425 to collide with the pressure sensor 6424 on the inner side wall or the inner bottom wall of the fixed shell 6423, and when the vibration reaches a certain degree, the pressure sensor 6424 receives pressure to reach a certain degree, the pressure sensor 6424 automatically starts the motor 6412 to further control the motor 6412 to rotate to strengthen the vertical wall 1.

As shown in fig. 2, as a preferred embodiment of the present invention, the reinforcement column 61 is provided with a reinforcement portion 7, the reinforcement portion 7 includes a plurality of groups of vertical slots 71 formed on the side wall of the reinforcement column 61, the vertical slots 71 are rotatably provided with reinforcement rods 72, the movable ends of the reinforcement rods 72 are provided with pointed structures, the reinforcement column 61 is provided with a unidirectional positioning portion 8 cooperating with the reinforcement rods 72, and the unidirectional positioning portion 8 is used for adjusting the position of the reinforcement rods 72 while the reinforcement column 61 moves.

When the reinforcing column 61 is inserted into the vertical wall 1, the reinforcing column 61 drives the reinforcing rods 72 to be synchronously inserted into the vertical wall 1, when the reinforcing column 61 is inserted into the deepest part of the vertical wall 1, the starting motor 6412 is reversed to drive the threaded rod 631 to reversely rotate, the threaded rod 631 and the mounting plate 622 are mutually matched to drive the reinforcing column 61 to move towards the fixed column 3, and when the reinforcing column 61 moves towards the fixed column 3, the reinforcing column 61 is mutually matched with the reinforcing column 61 through the unidirectional positioning parts 8, so that the reinforcing rods 72 on two sides of the reinforcing column 61 can be conveniently inserted into the vertical wall 1 along the horizontal direction, and the earthquake resistant effect of the vertical wall 1 is further improved.

As shown in fig. 2, as a preferred embodiment of the present invention, the unidirectional positioning portion 8 includes a mounting groove 81 formed in the reinforcement post 61 and communicating with the vertical groove 71, a bracket 82 is fixedly connected in the mounting groove 81, and a pressing spring 83 matched with the reinforcement post 72 is fixedly installed on the surface of the bracket 82.

When the reinforcement column 61 moves towards the interior of the vertical wall 1, the pushing force of the extrusion spring 83 does not affect the movement of the reinforcement rod 72, and when the reinforcement column 61 moves towards the interior of the fixed column 3 in a small amplitude, the extrusion spring 83 and the reinforcement column 61 are matched with each other, so that the reinforcement rod 72 can be conveniently inserted into the vertical wall 1 along the horizontal direction, and the earthquake-resistant effect of the vertical wall 1 is further improved.

As shown in fig. 2, as a preferred embodiment of the present invention, the fixing chamber 621 is fixedly provided therein with a reinforcing plate 9 slidably coupled to the reinforcing column 61.

The working principle of the invention is as follows: in the use, through the fixed slot 4 with erect wall 1 surface and the mutual joint of the fixed column 3 on plywood 2 surface, can carry out preliminary fixed to erecting wall 1 and plywood 2 in the assembled building, preliminary fixed back, install L template 52 in fixed slot 4 and the adjacent two sets of standing grooves 51 of fixed column 3, corresponding screw hole has been seted up in fixed slot 4, at L template 52 surface screw mounting multiunit bolt 53, multiunit bolt 53 respectively with erecting wall 1 and plywood 2 threaded connection, L template 52 can further be fixed erecting wall 1 and plywood 2, effectively improves the stability of erecting wall 1 and plywood 2. When the floor shakes to drive laminate 2 to shake, detect ball 6425 in the laminate 2 shakes in fixed casing 6423, detect ball 6425 shakes in fixed casing 6423 and then makes detect ball 6425 collide with the pressure sensor 6424 of fixed casing 6423 inside wall or interior bottom wall, after vibrations reach the pressure that the degree leads to pressure sensor 6424 to receive and reaches a certain degree, pressure sensor 6424 automatic start motor 6412, motor 6412 drives initiative helical tooth dish 6414 and then drives through initiative helical tooth dish 6414 and driven helical tooth dish 6413 meshing, and the control threaded rod 631 that can be convenient rotates, threaded rod 631 drives mounting panel 622 along threaded rod 631 direction through with mounting panel 622 screw drive and then moves in fixed cavity 621, mounting panel 622 drives the post 61 and removes and then can be convenient through fixed orifices 632 with the post 61 outside of pushing the fixed post 3 and insert to the inside of vertical wall 1, can effectively improve vertical wall 1's stability. When the reinforcement column 61 moves towards the interior of the vertical wall 1, the pushing force of the extrusion spring 83 does not affect the movement of the reinforcement rod 72, and when the reinforcement column 61 moves towards the interior of the fixed column 3 in a small amplitude, the extrusion spring 83 and the reinforcement column 61 are matched with each other, so that the reinforcement rod 72 can be conveniently inserted into the vertical wall 1 along the horizontal direction, and the earthquake-resistant effect of the vertical wall 1 is further improved.

While the preferred embodiments of the present invention have been described in detail, the present invention is not limited to the above embodiments, and various changes can be made without departing from the spirit of the present invention within the knowledge of those skilled in the art.

Claims

1. The utility model provides an energy-conserving building assembled wall anti-seismic mechanism, includes the plywood, the plywood both sides are provided with perpendicular wall respectively, its characterized in that, the lateral wall fixed mounting of plywood orientation perpendicular wall has multiunit fixed column, perpendicular wall orientation lateral wall of plywood has seted up the fixed slot that mutually support with the fixed column, perpendicular wall installs fixed subassembly jointly with the both sides wall that the plywood links to each other, be provided with anti-seismic mechanism jointly in perpendicular wall and the plywood, anti-seismic mechanism is including strengthening column, storage subassembly, flexible subassembly and control assembly, storage subassembly is located the fixed column and is connected with the strengthening column, storage subassembly is used for accomodating the strengthening column in the fixed column, flexible subassembly is located the fixed column and is connected with storage subassembly, flexible subassembly is used for mutually supporting with storage subassembly and then promotes the strengthening column and remove towards the fixed column outside, control assembly is including drive portion and automatic control portion, drive portion is located the plywood and is connected with flexible subassembly, drive portion is used for mutually supporting and then carries out control with the strengthening column, automatic control portion is located in and is connected with automatic control portion, receive the drive portion and monitor the plywood vibration amplitude and then starts the plywood.

2. The energy-saving building assembled wall earthquake-resistant mechanism according to claim 1, wherein the fixing assembly comprises placing grooves respectively formed in two side walls connected with the vertical wall and the laminate, L-shaped plates are jointly placed in the two placing grooves, and a plurality of groups of bolts respectively connected with the vertical wall and the laminate are in threaded connection with the surfaces of the L-shaped plates.

3. The energy-saving building assembled wall anti-seismic mechanism of claim 1, wherein the storage assembly comprises a fixed cavity formed in a fixed column, the fixed cavity is of a vertically long-strip structure, a mounting plate is slidably connected in the fixed cavity, the reinforcing column is located in the fixed cavity, one end, close to the laminate, of the reinforcing column is fixedly connected with the mounting plate, one end, far away from the laminate, of the reinforcing column is of a pointed structure, and the mounting plate is connected with the telescopic assembly.

4. The energy-saving building assembled wall earthquake-proof mechanism of claim 3, wherein the telescopic assembly comprises a threaded rod rotatably installed in the fixing cavity, the threaded rod is in threaded connection with the mounting plate, a fixing hole communicated with the fixing cavity is formed in a side wall, far away from the laminate, of the fixing column, the fixing hole and the reinforcing column are located at the same axis, and the threaded rod is connected with the transmission part.

5. The energy-saving building assembled wall earthquake-proof mechanism of claim 4, wherein the transmission part comprises a driving cavity formed in the laminate, the threaded rod extends into the driving cavity towards one end of the laminate and is fixedly connected with a driven inclined fluted disc, a motor is fixedly installed in the driving cavity, an output shaft of the motor is fixedly installed with a driving inclined fluted disc which is meshed and connected with the driven inclined fluted disc, and the motor is connected with the automatic control part.

6. The energy-saving building assembled wall anti-seismic mechanism of claim 5, wherein the automatic control part comprises a control cavity formed in the laminate, a controller is fixedly arranged in the control cavity, the controller is electrically connected with the motor, a box-shaped fixed shell is fixedly arranged in the control cavity, a detection ball is placed in the fixed shell, pressure sensors matched with the detection ball are respectively and fixedly arranged on the inner side wall and the inner bottom wall of the fixed shell, and the pressure sensors are electrically connected with the controller.

7. The energy-saving building assembled wall anti-seismic mechanism of claim 1, wherein the reinforcing part is arranged in the reinforcing column, the reinforcing part comprises a plurality of groups of vertical grooves formed in the side wall of the reinforcing column, the reinforcing rod is rotatably arranged in the vertical grooves, the movable end of the reinforcing rod is arranged into a pointed structure, a unidirectional positioning part matched with the reinforcing rod is arranged in the reinforcing column, and the unidirectional positioning part is used for adjusting the position of the reinforcing rod while the reinforcing column moves.

8. The energy-saving building assembled wall earthquake-proof mechanism of claim 7, wherein the unidirectional positioning portion comprises a mounting groove which is formed in the reinforcing column and communicated with the vertical groove, a bracket is fixedly connected in the mounting groove, and an extrusion spring which is matched with the reinforcing rod is fixedly arranged on the surface of the bracket.

9. An energy saving building assembled wall seismic mechanism according to claim 3, wherein a reinforcing plate in sliding connection with the reinforcing column is fixedly installed in the fixing cavity.