CN113323194B - Assembled antidetonation partition wall - Google Patents

Abstract

An assembled anti-seismic partition wall belongs to the technical field of assembled buildings and comprises an outer wall body and a combined supporting member arranged in the outer wall body, wherein a rectangular accommodating cavity for accommodating the combined supporting member is formed in the outer wall body; the combined support member comprises a plurality of support columns arranged at intervals and a laminated buffer assembly connected with the two adjacent support columns, the support columns transversely slide in the rectangular accommodating cavity, the laminated buffer assembly is formed by overlapping a plurality of sliding buffer plates at intervals, and the two adjacent sliding buffer plates are connected through a memory alloy connecting member. The device provided by the invention has a certain anti-seismic effect when an earthquake occurs, can protect the main structure of the wall body from collapsing, increases the safety of the structure, can facilitate subsequent repair and maintenance, and saves the cost.

Description

Assembled antidetonation partition wall

Technical Field

The invention belongs to the technical field of assembly type buildings, and particularly relates to an assembly type anti-seismic partition wall.

Background

Along with the continuous improvement of sustainable development and energy-saving and environment-friendly requirements and the continuous increase of labor cost, the industrialization of buildings represented by an assembled structural system is gaining more and more importance, and the application of the building is gradually heated. The production cost of the prefabricated assembly structure is low, the labor cost is greatly reduced, and the construction period is shortened; the product quality is better ensured, the production process is easier to control by the process production, and the production efficiency is greatly improved; the environmental pollution and the source waste caused by production are greatly reduced, the utilization rate of various materials is obviously improved, the generated waste materials, waste water and the like are more effectively controlled, and a part of structural members can be recycled. Although the assembled structure system has many advantages, how to improve the stability of the assembled system, especially how to play a certain anti-seismic effect when an earthquake happens, protect the main structure of the wall from collapsing, increase the safety of the structure, facilitate subsequent repair and maintenance, save the cost and solve the technical problem in the field all the time.

Disclosure of Invention

The invention solves the defects of the prior art and provides the assembled anti-seismic partition wall which has a certain anti-seismic effect when an earthquake occurs, can protect the main structure of the wall from collapsing, increases the safety of the structure, can facilitate subsequent repair and maintenance and saves the cost.

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

an assembled anti-seismic partition wall comprises an outer wall body and a combined supporting member arranged in the outer wall body, wherein a rectangular accommodating cavity for accommodating the combined supporting member is arranged in the outer wall body; the combined supporting member comprises a plurality of supporting columns which are arranged at intervals and a plurality of groups of laminated buffer components which are connected with two adjacent supporting columns, the heights of the supporting columns are matched with the heights of the rectangular accommodating cavities,

the laminated buffer assembly is formed by mutually connecting a plurality of sliding buffer plates along the beam direction, adjacent sliding buffer plates are connected through memory alloy connecting members, through holes are formed in positions where the supporting columns are connected with the laminated buffer assembly, connecting members are fixed in the through holes, the laminated buffer assembly is connected with adjacent supporting columns through the connecting members, the laminated buffer assembly can be formed by superposing the sliding buffer plates, vertical displacement can be superposed, and the vertical displacement is uniformly spread through each group of sliding buffer plates, so that the possibility of concentrated stress of a single memory alloy connecting member is avoided, the single memory alloy connecting member can be detached or added as required, different-scale earthquake environments can be met, and the assembly type installation requirement is met.

In this embodiment, the vertical draw-in groove of laying along the support stand direction has been seted up to the middle part symmetry of the positive and negative both sides of buffer board that slides, memory alloy connecting piece slip cartridge is in vertical draw-in groove, and adjacent buffer board that slides is through a plurality of memory alloy connecting pieces interconnect of installing in vertical draw-in groove, the buffer board that slides is provided with the stop device that prevents memory alloy connecting piece roll-off from vertical draw-in groove at the both ends of vertical draw-in groove, through setting up multiunit memory alloy connecting piece, when guaranteeing installation space, can improve the joint strength of structure, the multiunit memory alloy connecting piece is combined each other, can equal share effort, improves device's life-span.

In this embodiment, stop device includes spacing piece and locking device, the spacing piece sets up respectively in the business turn over, the exit end of vertical draw-in groove and spanes vertical draw-in groove, the both ends of spacing piece pass through locking device with the buffer board that slides is fixed continuous.

In this embodiment, locking device is the screw, set up on the buffer board that slides and lay along vertical draw-in groove direction, and run through the spout of sliding the buffer board, the screw is installed in the spout, the screw passes the spout and locks the spacing piece of the buffer board both sides that slides on the buffer board that slides.

In this embodiment, the vertical draw-in groove is "T" style of calligraphy logical groove, memory alloy connecting element is "H" type, memory alloy connecting element both ends respectively with two buffer boards block that slide, T type groove vertical draw-in groove is used for cooperating with "H" type memory alloy connecting element's both ends, realizes that memory alloy connecting element is spacing slip in vertical draw-in groove.

In this embodiment, the outer wall body includes rectangular frame and fixes the wallboard in rectangular frame opening both sides, and two wallboards and rectangular frame enclose and close and form the rectangle holds the chamber.

In this embodiment, the connecting element includes the casing of rectangle, the casing is fixed in the through-hole of support column, the both ends that the casing is connected with stromatolite buffer assembly are equipped with connecting portion, connecting portion is including connecting the connecting bridge of upper and lower surface of casing, be provided with along vertical and memory alloy connecting element assorted third vertical draw-in groove on the connecting bridge, stromatolite buffer assembly passes through memory alloy connecting element and is connected with third vertical draw-in groove.

In this embodiment, the housing is provided with a mounting window on a side to be connected to the memory alloy connecting member, which facilitates mounting and connection of the housing.

The invention has the beneficial effects that:

1. the device is carried out through the support upright, when the device is stimulated by an earthquake, the support upright is limited in the rectangular accommodating cavity by the wallboard, so that the support upright can only transversely slide in the rectangular accommodating cavity, and therefore, the memory alloy connecting members are pulled by the adjacent support upright to be elongated and deformed, a certain energy consumption buffering capacity is achieved, the original state is restored under the action of the device, and the aim of protecting the whole structure from being damaged is achieved.

2. In this device first vertical draw-in groove and the vertical draw-in groove of second have been seted up respectively to the both sides of sliding buffer board, memory alloy connecting element's both ends respectively with first vertical draw-in groove and the vertical draw-in groove joint of second and vertically with sliding buffer board friction fit, two adjacent support posts are when vertical relative displacement takes place, slide along vertical draw-in groove through pulling memory alloy connecting element to consume energy through the friction, play certain energy dissipation shock-resistant purpose.

3. In this device, through setting up multiunit memory alloy connecting elements, when guaranteeing installation space, can improve the joint strength of structure, the multiunit memory alloy connecting elements is mutually combined, can evenly spread effort, improves the life-span of device.

4. In this device, through will slide the buffer board stack formation stromatolite buffer assembly can carry out a stack to vertical displacement, carries out the samming through each group buffer board that slides in vertical position, prevents that single memory alloy connecting elements from appearing concentrating stress's possibility, also can dismantle or install additional as required, can adapt to the seismic environment of different scales, satisfies assembled installation demand.

In summary, the device can play a certain anti-seismic effect when an earthquake occurs, can protect the main structure of the wall body from collapsing, increases the safety of the structure, can facilitate subsequent repair and maintenance, and saves the cost.

Drawings

FIG. 1 is a schematic diagram of the structure of the device of the present invention;

FIG. 2 is a schematic view of the structure of the laminated cushioning assembly and connecting member of the present invention;

FIG. 3 is a top view of FIG. 2;

FIG. 4 is a schematic view of a slip buffer of the present invention 1;

FIG. 5 is a schematic view of a slip buffer according to the present invention 2.

The figures are marked as follows: 1. an outer wall; 2. a rectangular accommodation chamber; 3. a support column; 4. a laminated buffer assembly; 41. a slip buffer plate; 42. a memory alloy connecting member; 43. the first vertical clamping groove; 44. the second vertical clamping groove; 45. a limiting device; 451. a limiting piece; 452. a locking device; 46. a chute; 5. a through hole; 6. a connecting member; 61. a housing; 62. a connection hole; 63. a connecting bridge; 64. a third vertical clamping groove; 65. and installing a window.

Detailed Description

Other advantages and effects of the present invention will become apparent to those skilled in the art from the description herein below, by describing embodiments of the present invention with specific examples. The invention may be practiced or carried out in other embodiments that depart from the specific details, and the details of the present description may be modified or varied from the spirit and scope of the present invention. It should be noted that the illustrations provided in the following embodiments merely illustrate the basic idea of the present invention by way of illustration, and the following embodiments and features in the embodiments may be combined with each other without conflict.

Wherein the drawings are for illustrative purposes only and are shown in schematic, non-physical, and not intended to limit the invention; for the purpose of better illustrating embodiments of the invention, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the size of the actual product; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

The same or similar reference numbers in the drawings of embodiments of the invention correspond to the same or similar components; in the description of the present invention, it should be understood that, if there are terms such as "upper", "lower", "left", "right", "front", "rear", etc., that indicate an azimuth or a positional relationship based on the azimuth or the positional relationship shown in the drawings, it is only for convenience of describing the present invention and simplifying the description, but not for indicating or suggesting that the referred device or element must have a specific azimuth, be constructed and operated in a specific azimuth, so that the terms describing the positional relationship in the drawings are merely for exemplary illustration and should not be construed as limiting the present invention, and that the specific meaning of the above terms may be understood by those of ordinary skill in the art according to the specific circumstances.

As shown in fig. 1 to 5, the assembled anti-seismic partition wall comprises an outer wall body 1 and combined supporting members arranged in the outer wall body 1, wherein the outer wall body comprises a rectangular frame and wall plates fixed on two sides of an opening of the rectangular frame, and the two wall plates and the rectangular frame are enclosed to form a rectangular accommodating cavity; the combined support member comprises a plurality of support columns 3 arranged at intervals and a laminated buffer assembly 4 connecting two adjacent support columns 3,

the laminated buffer assembly 4 is formed by mutually connecting a plurality of sliding buffer plates 41, the adjacent sliding buffer plates are provided with intervals and are connected through a memory alloy connecting member 42, a first vertical clamping groove 43 and a second vertical clamping groove 44 are symmetrically formed in two opposite sides of the sliding buffer plates 41 respectively, the first vertical clamping groove 43 and the second vertical clamping groove 44 are T-shaped through grooves, the memory alloy connecting member 42 is H-shaped, the memory alloy connecting member 42 is slidably mounted in the first vertical clamping groove 43 and the second vertical clamping groove 44, the adjacent sliding buffer plates 41 are connected through a plurality of memory alloy connecting members 42 mounted in the first vertical clamping groove 43 and the second vertical clamping groove 44, and limiting devices 45 are arranged at two ends of the sliding buffer plates 41 in the first vertical clamping groove 43 and the second vertical clamping groove 44 and used for limiting the memory alloy connecting member 42 when sliding up and down so as to prevent the memory alloy connecting member 42 from sliding out. The limiting device 45 comprises a limiting piece 451 and a locking device 452, the limiting piece 451 is arranged at the inlet and outlet ends of the first vertical clamping groove 43 and the second vertical clamping groove 44 and spans the first vertical clamping groove 43 and the second vertical clamping groove 44, two ends of the limiting piece 451 are fixedly connected with the sliding buffer plate 41 through the locking device 452, the locking device 452 comprises a screw, the sliding buffer plate 41 is provided with a sliding groove 46 which is distributed along the direction of the first vertical clamping groove 43 and the direction of the second vertical clamping groove 44 and penetrates through the sliding buffer plate 41, the screw is arranged in the sliding groove 46, and the screw penetrates through the sliding groove 46 and locks the limiting pieces 451 on two sides of the sliding buffer plate 41 on the sliding buffer plate 41.

The support column 3 is provided with a through hole 5, a connecting member 6 is fixed in the through hole 5, the laminated buffer assembly 4 is connected with the adjacent support column 3 through the connecting member 6, the connecting member 6 comprises a rectangular shell 61, the upper side, the lower side, the left side and the right side of the shell 61 are provided with connecting holes 62 connected with the support column 3, the shell 61 is connected with the support column 3 through screws arranged in the connecting holes 62, two ends, connected with the laminated buffer assembly 4, of the shell 61 are provided with connecting parts, the connecting parts comprise connecting bridges 63 connected with the upper surface and the lower surface of the shell 61, third vertical clamping grooves 64 are vertically arranged on the connecting bridges 63, and the third vertical clamping grooves 64 are respectively connected with the first vertical clamping grooves 43 and the second vertical clamping grooves 44 through memory alloy connecting members 42. Four corners of the housing 61 are provided with mounting windows 65 to facilitate mounting and connection of the connection member 6.

In this embodiment, the first vertical clamping groove 43 and the second vertical clamping groove 44 have the same structure and are symmetrical relative to the center of the sliding buffer plate 41, two ends of the memory alloy connecting member 42 are respectively clamped with the first vertical clamping groove 43 and the second vertical clamping groove 44 and are vertically and slidably connected with the sliding buffer plate 41, so that the first vertical clamping groove 43 and the second vertical clamping groove 44 are respectively clamped with half of the memory alloy connecting member 42, and when two adjacent support columns 3 are relatively displaced vertically, the two adjacent support columns slide along the vertical clamping grooves by pulling the memory alloy connecting member 42, so that energy consumption is carried out through friction, a certain energy consumption and vibration resistance purpose is achieved, and the wall body is prevented from being vertically deformed to a greater extent.

Finally, it is noted that the above-mentioned preferred embodiments are only intended to illustrate rather than limit the invention, and that, although the invention has been described in detail by means of the above-mentioned preferred embodiments, it will be understood by those skilled in the art that various changes in form and details may be made therein without departing from the scope of the invention as defined by the appended claims.

Claims (7)

1. An assembled antidetonation partition wall, its characterized in that: the combined support structure comprises an outer wall body and a combined support member arranged in the outer wall body, wherein a rectangular accommodating cavity for accommodating the combined support member is arranged in the outer wall body; the combined support component comprises a plurality of support columns arranged at intervals and a plurality of groups of laminated buffer components connected with the two adjacent support columns, the heights of the support columns are matched with those of the rectangular accommodating cavity, the support columns are clamped in the rectangular accommodating cavity, the laminated buffer components are formed by mutually connecting a plurality of sliding buffer plates along the beam direction, the adjacent sliding buffer plates are connected through memory alloy connecting components, through holes are formed in the positions, connected with the laminated buffer components, of the support columns, connecting components are fixedly arranged in the through holes, the laminated buffer components are connected with the adjacent support columns through the connecting components, the connecting components comprise rectangular shells, the shells are fixedly arranged in the through holes of the support columns, connecting parts are arranged at two ends, connected with the laminated buffer components, of the shells, the connecting parts are connected with connecting bridges on the upper surface and the lower surface of the shells, third vertical clamping grooves matched with the memory alloy connecting components are vertically formed in the connecting bridges, and the laminated buffer components are connected with the third vertical clamping grooves through the memory alloy connecting components.

2. The fabricated anti-seismic partition according to claim 1, wherein: the vertical clamping grooves distributed along the direction of the supporting upright posts are symmetrically formed in the middle of the front side and the back side of the sliding buffer plate, the memory alloy connecting members are slidably clamped in the vertical clamping grooves, the adjacent sliding buffer plates are connected with each other through a plurality of memory alloy connecting members installed in the vertical clamping grooves, and limiting devices for preventing the memory alloy connecting members from sliding out of the vertical clamping grooves are arranged at the two ends of the vertical clamping grooves.

3. The fabricated anti-seismic partition wall of claim 2, wherein: the limiting device comprises a limiting piece and a locking device, wherein the limiting piece is arranged at the inlet end and the outlet end of the vertical clamping groove respectively and spans across the vertical clamping groove, and two ends of the limiting piece are fixedly connected with the sliding buffer plate through the locking device.

4. A fabricated anti-seismic partition according to claim 3, wherein: the locking device is a screw, a sliding groove which is arranged along the vertical clamping groove direction and penetrates through the sliding buffer plate is formed in the sliding buffer plate, the screw is installed in the sliding groove, and the screw penetrates through the sliding groove and locks limiting pieces on two sides of the sliding buffer plate on the sliding buffer plate.

5. The fabricated anti-seismic partition wall of claim 2, wherein: the vertical clamping groove is a T-shaped through groove, and the memory alloy connecting member is H-shaped.

6. The fabricated anti-seismic partition according to claim 1, wherein: the outer wall body comprises a rectangular frame and wallboards fixed on two sides of an opening of the rectangular frame, and the two wallboards and the rectangular frame are enclosed to form the rectangular accommodating cavity.

7. The fabricated earthquake-resistant partition as recited in any one of claims 1 to 6, wherein: the shell is provided with a mounting window on the side connected with the memory alloy connecting member, which is convenient for mounting and connecting the shell.