CN205712600U - A kind of assembled assembles power consumption antidetonation body of wall - Google Patents

Abstract

The utility model provides a prefabricated assembled energy-consuming anti-seismic wall, which includes a cuboid partition wall panel, the cuboid partition wall panel includes a first partition wall unit panel and a second partition wall unit panel, and the first partition wall unit The panel is provided with a first partition wall slope, and the second partition wall unit panel is provided with a second partition wall slope, the slope and size of the first partition wall slope and the second partition wall slope are the same, and the first partition wall The inclined surface of the wall and the inclined surface of the second partition wall are connected by laminated rubber members; one side wall in the length direction of the cuboid partition wall is provided with a tenon groove, and the opposite side wall is provided with a joint with the tenon and groove. and tenons, the cuboid partition wall panels bite and connect with each other to form a prefabricated partition wall. Adopting the technical solution of the utility model, the anti-seismic performance is good; and the prefabricated wall panel formwork is simple, which is convenient for production and quality control; the assembly is simple, the installation is convenient, the construction efficiency is high, and it is suitable for mass production.

Description

A prefabricated assembled energy-dissipating anti-seismic wall

technical field

The utility model relates to an assembled partition wall, in particular to an assembled energy-consuming and anti-seismic wall.

Background technique

With the continuous improvement of sustainable development, energy conservation and environmental protection requirements, and the continuous increase of labor costs, the industrialization of buildings represented by prefabricated structural systems has received more and more attention, and its applications have gradually heated up. The production cost of the prefabricated assembly structure is lower, which greatly reduces the labor cost and shortens the construction period; the product quality is better guaranteed, and the process production makes the production process easier to control, which greatly improves the production efficiency; Environmental pollution and energy waste caused by production are eliminated, and the utilization rate of various materials is significantly improved, so that waste and wastewater generated are more effectively controlled, and some structural components can even be recycled and reused.

From the perspective of prefabricated building structure, the relevant supporting components mainly include roof panels, exterior wall composite panels, floor slabs and other components. Prefabricated buildings are produced according to construction industry standards, and involve the reform of the construction industry and the transformation of emerging industries. The original purpose of prefabricated buildings is to produce residential buildings through industrial manufacturing. The overall building system maintains low-carbon, earthquake-resistant, economical and applicable advantages in the development of a conservation-oriented society, which is of great benefit to consumers; according to the requirements of the national construction industry development policy, the design and assembly are advanced and sustainable The overall structure of the building meets market demand. If our country wants to embark on the road of civilized building construction, it should actively use new materials and new technologies, which is in line with the development trend of future prefabricated buildings.

However, the existing prefabricated partition walls have the following problems:

1. Most prefabricated lightweight partition walls do not have energy dissipation and anti-seismic performance;

2. The partition wall materials used in the production process need to be improved. More environmentally friendly and recyclable materials can be used within the scope of the economy;

3. Molds and accessories need to be improved. The quality of raw materials for manufacturing molds is uneven, and the supporting conditions are different, making it difficult to produce high-quality abrasive tools and accessories, and the production accuracy and production efficiency are low;

4. There is a lack of standardized and general prefabricated components. The components have a single variety and specification, the building and structural functions are out of touch, and the versatility and interchangeability are not strong. It is difficult to realize the industrialization of prefabricated partition walls.

Utility model content

In view of the above technical problems, the utility model discloses a prefabricated assembled energy-consuming anti-seismic wall, which overcomes the shortcomings of the existing prefabricated partition walls such as difficulty in realizing industrialization, waste of materials, and most of them do not have anti-seismic performance. Provides a prefabricated partition wall that is green, environmentally friendly, easy to produce and assemble, and has a certain energy consumption and anti-seismic effect.

To this end, the technical scheme of the utility model is:

A prefabricated assembled energy dissipation and anti-seismic wall, which includes a cuboid partition wall panel, the cuboid partition wall panel includes a first partition wall unit panel and a second partition wall unit panel, and the first partition wall unit panel is provided with a second partition wall unit panel. A partition wall slope, the second partition wall unit plate is provided with a second partition wall slope, the slope and size of the first partition wall slope and the second partition wall slope are the same, and the first partition wall slope is the same as the second partition wall slope The slopes of the two partition walls are connected by laminated rubber components; one side wall in the length direction of the cuboid partition wall is provided with a tenon groove, and the opposite side wall is provided with a tenon that engages with the tenon groove, The cuboid partition wall boards bite and connect with each other to form a prefabricated partition wall. Wherein, the mortise is a groove; the mortise is a bump. Preferably, the cross section of the tongue and groove is in the shape of a circular segment, and the height of the circular segment is greater than the radius.

Wherein, the slope angle of the first partition wall slope and the second partition wall slope is preferably 60-80 degrees, that is, the angle between the first partition wall slope and the horizontal plane, the angle between the second partition wall slope and the horizontal plane All are 60-80 degree, to ensure that the long right-angled side of the triangle is the half of the long side (vertical side) of the first partition wall and the second partition wall.

As a further improvement of the present utility model, the inclination angles of the first partition wall slope and the second partition wall slope are 65-75 degrees. Further preferably, the slope angle of the first partition wall slope and the second partition wall slope is 70 degrees.

As a further improvement of the present utility model, the section of the first partition wall unit panel in the length direction of the cuboid partition wall panel is a right-angled trapezoid, and the section of the second partition wall unit panel in the length direction of the cuboid partition wall panel is a triangle.

As a further improvement of the utility model, the first partition wall slope and the second partition wall slope of the cuboid partition wall board form a partition wall splicing surface, and the two cuboid partition wall boards are occluded and connected to each other to form a partition wall unit. The partition wall splicing surfaces of the two cuboid partition wall panels are on the same plane, forming the connection surface of the partition wall unit.

As a further improvement of the utility model, the partition wall splicing surfaces of the two cuboid partition wall panels are on the same plane as the diagonal surfaces of the partition wall units.

As a further improvement of the present utility model, the assembly-type assembled energy-consuming anti-seismic wall is obtained by splicing an odd number of cuboid partition wall panels, wherein the number of the rectangular parallelepiped partition wall panels is an odd number, and the assembly-type assembly energy-consuming anti-seismic wall The wall body is formed by splicing the partition wall unit and the cuboid partition wall board.

As a further improvement of the utility model, the cuboid partition wall is located on the side of the assembled energy-dissipating and anti-seismic wall, and the plane where the connecting surface of the partition wall unit is located is the same as the partition wall of the cuboid partition wall The planes where the stitched faces intersect.

As a further improvement of the present utility model, the assembly-type assembled energy-dissipating seismic wall is obtained by splicing even numbers of rectangular parallelepiped partition wall panels, wherein the rectangular parallelepiped The body is spliced sequentially from left to right using 1 to N/2 partition wall units.

As a further improvement of the present utility model, the connection surfaces of the first to M partition wall units are parallel to each other; the connection surfaces of the (M+1)th to N/2 partition wall units are parallel to each other, And intersect with the plane where the connecting surface of the first to Mth partition wall units is located; wherein, the M=[N/4], that is, M takes an integer.

As a further improvement of the present utility model, the connection surfaces of the first to N/2th partition wall units intersect one partition wall unit in sequence. That is, the connection surface of the first partition wall unit is parallel to the connection surface of the second partition wall unit, and the connection surface of the first partition wall unit intersects the plane where the connection surface of the third partition wall unit is located.

As a further improvement of the utility model, the prefabricated assembled energy-dissipating seismic wall can be obtained by combining odd-numbered splicing and/or even-numbered splicing. With this technical solution, in the splicing of the prefabricated assembled energy-dissipating aseismic wall, odd-numbered splicing or even-numbered splicing can be performed according to actual needs, or a combination of odd-numbered splicing and even-numbered splicing can be used.

As a further improvement of the utility model, the shape factor S of the laminated rubber member satisfies: S ₁ >15, 6>S ₂ >3, wherein, S ₁ is the first shape factor, that is, each rubber layer can effectively bear pressure The ratio of the area to the free surface area; S ₂ is the second shape factor, which is the ratio of the effective bearing area to the total thickness of the adhesive layer. where S1 and S2 are calculated using the following _{formula :}

${\mathrm{<span\; class="notranslate">\; S</span>}}_{\mathrm{<span\; class="notranslate">\; 1</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; D.</span>}<span\; class="notranslate">\; -</span>{\mathrm{<span\; class="notranslate">\; D.</span>}}_{\mathrm{<span\; class="notranslate">\; 0</span>}}}{\mathrm{<span\; class="notranslate">\; 4</span>}\mathrm{<span\; class="notranslate">\; T</span>}}<span\; class="notranslate">\; ,</span>$

${\mathrm{<span\; class="notranslate">\; S</span>}}_{\mathrm{<span\; class="notranslate">\; 2</span>}}<span\; class="notranslate">\; =</span>\frac{\mathrm{<span\; class="notranslate">\; D.</span>}}{\mathrm{<span\; class="notranslate">\; no</span>}\mathrm{<span\; class="notranslate">\; T</span>}}<span\; class="notranslate">\; ;</span>$

In the above formula, D ₀ is the diameter of the middle hole of the rubber layer; T is the thickness of each layer of rubber; n is the number of rubber layers; D is the diameter of the effective bearing surface of the rubber layer.

Preferably, the laminated rubber member includes 11 steel plates with a thickness of 1 mm and 12 layers of rubber with a thickness of 3 mm. Through calculation, S ₁ =16.9, S ₂ =5.6, which can meet the requirements.

Preferably, the laminated rubber member adopts NR rubber. This type of rubber not only has excellent elasticity, dynamic performance, processing performance, alkali resistance and aging resistance, but also has high strength itself.

As a further improvement of the utility model, the first partition wall slope, the second partition wall slope and the laminated rubber member are bonded with TB1521 industrial adhesive; the first partition wall unit plate and the second partition wall unit plate The wall unit panels are hollow lightweight partition panels of silicon-magnesium aerated concrete.

Using this technical solution, TB1521 industrial adhesive has the following characteristics: (1) Strong initial adhesion, and the elasticity will not disappear after bonding; (2) No need for cumbersome operations such as metering and heating, and anyone can easily operate it. In this way, the user can be more convenient to use, and the long-term bonding quality can be guaranteed.

With this technical solution, the partition wall unit board adopts a hollow design of lightweight and high-strength GM material. The hollow lightweight partition wall board of silicon-magnesium aerated concrete is formed by chemical reaction of various inorganic materials. Its characteristics and advantages as follows:

(1) Lightweight: This material is lighter than wood and can float on water;

(2) Sound insulation and heat preservation: This material is composed of countless individual air bubbles, which improves the sound insulation and heat preservation effect of the product;

(3) Good fire resistance: GM boards synthesized by inorganic materials are non-combustible;

(4) Good anti-bending and anti-shock performance: the countless anti-corrosion short fibers added to the wallboard enhance the anti-bending and anti-shock performance of the wallboard;

(5) The size of the wallboard is accurate, the length and size can be cut at will, and the installation is very convenient. Large block dry installation, the work efficiency can be increased by more than 20 times;

(6) It is porous, and can be nailed, planed, and drilled, which is convenient for water and electricity pipeline installation and embedding construction.

With this technical solution, the user can fill in appropriate materials according to the needs of use, such as thermal insulation materials and sound insulation materials. It has multi-functionality, high strength, easy installation, and greatly improves efficiency.

As a further improvement of the present utility model, the length of the cuboid partition wall is 2200-3500 mm, and the width is 500-700 mm. Further preferably, the length of the cuboid partition wall is 2800mm, and the width is 600mm.

The size of the cuboid partition board can be designed according to the size commonly used in the current market, which is convenient for large-scale industrial production.

The utility model discloses a method for assembling the energy-consuming and anti-seismic wall of the assembly type, which comprises the following steps:

Step A: Install the cuboid partition board first, then align the tenon of the cuboid partition board with the tenon of another cuboid partition board for splicing, connect the cuboid partition boards together in turn, and adjust the verticality and adjacent boards flatness of the surface;

Step B: lay out the wires on the ground and ceiling panels, and install the cuboid partition wall panels in sequence from one end of the main wall or column to the other end, and when there is a door opening, install it from the door opening to both sides;

Step C: Install the positioning board first, scrape the bonding material at the mortise and top surface of the cuboid partition wall board, seal the hole at the upper end of the cuboid partition wall board, align the positioning board up and down, and the cuboid partition wall board The lower end of the wall panel is 30mm-60mm away from the ground;

Step D: drive a wooden wedge into the solid rib at the lower part of the cuboid partition wall and wedge tightly; use the wooden wedge to put the cuboid partition wall in place, and squeeze the cuboid partition wall vertically upward so that The top of the rectangular parallelepiped partition board is pressed against the bottom of the beam, and then the rectangular parallelepiped partition board is fixed;

Step E: Set positioning steel clips and anti-seismic steel clips at the joints between the cuboid partition wall panels and the roof, structural beams, main walls, and columns.

As a further improvement of the utility model, it also includes:

Step F: Fill the gaps between the rectangular parallelepiped partition wall boards with bonding material, squeeze the gaps between the boards tightly, and scrape the extruded bonding materials flat; The gap between the body and the floor is filled with dry hard fine stone concrete; the wooden wedges are taken out after 3 days of curing on the vertical slabs, and the wedge holes are filled.

Adopting the above-mentioned technical scheme meets the requirements of the general JGJ/T 157-2014 standard "Technical Specifications for Lightweight Slatted Partition Walls in Buildings", and the quality is more guaranteed.

The novel assembled inner partition wall of the utility model improves the shape and material of the wall body, can realize energy consumption, and achieve the purpose of anti-seismic. The partition wall has the characteristics of simple structure and regular shape, which is convenient for large-scale mechanized production and product quality control, and has good promotion value. Compared with blocks, the prefabricated partition wall has the advantages of convenient and quick construction, low labor intensity, smooth wall surface (it can save the wall plastering), high wall strength and better integrity. In the production project, "green materials" with light weight, high strength, economy and environmental protection, high degree of industrialization and good seismic performance are used to make it more suitable for industrial production.

Compared with the prior art, the beneficial effects of the utility model are:

First, adopting the technical scheme of the utility model, the seismic performance is good; the first unit plate and the second unit plate of the partition wall are connected by laminated rubber components, which can effectively realize energy consumption and shock absorption; the wall and the structural beam or The plates are connected by steel clips, and the connection strength can be fully guaranteed; the connection between the cuboid unit blocks of the partition wall adopts the non-slurry block connection technology, and friction will be generated under the earthquake, so as to achieve the effect of energy consumption. Moreover, the wall body of the prefabricated partition wall is made of light-weight and high-strength GM material, which can ensure sufficient strength of the wall body and greatly reduce the self-weight of the structure.

Second, adopting the technical solution of the utility model, the partition wall unit adopts a hollow design, and can be filled with appropriate materials according to the use requirements, such as thermal insulation materials and sound insulation materials, which are multifunctional, high in strength, and easy to install.

Thirdly, adopting the technical solution of the utility model, the prefabricated wall panel formwork is simple, which is convenient for production and quality control. The prefabricated wall panel adopts hollow wall, which is poured with environmentally friendly composite materials, which is beneficial to improve the production speed and control the quality of the wall panel prefabrication process.

Fourth, adopting the technical solution of the utility model, the assembled construction method has high efficiency and is easy to install: the partition wall can be installed by using the method of installing the strip partition wall on the lower wedge top plate, which is simple to assemble and improves the efficiency.

Fifth, adopting the technical solution of the utility model, the size of the partition wall can be designed according to the size commonly used in the current market. In addition to facilitating large-scale industrial production, it can also be applied to walls of most sizes through splicing.

Description of drawings

Fig. 1 is a schematic diagram of the structure of a cuboid partition wall panel according to an embodiment of the present invention.

Fig. 2 is a schematic side view of the laminated rubber member of an embodiment of the present invention.

Fig. 3 is an assembly diagram of a partition wall unit according to an embodiment of the present invention.

Fig. 4 is a structural schematic diagram of an assembled partition wall unit according to an embodiment of the present invention.

Fig. 5 is a structural schematic diagram of an odd splicing according to an embodiment of the present invention.

Fig. 6 is a schematic structural diagram of an even splicing according to an embodiment of the present invention.

detailed description

Below in conjunction with accompanying drawing, preferred embodiment of the present utility model is described in further detail.

Example 1

As shown in Figures 1 to 6, a prefabricated assembled energy-dissipating anti-seismic wall includes a cuboid partition wall panel 1, and the cuboid partition wall panel 1 includes a first partition wall unit panel 2 and a second partition wall unit panel 3. The first partition wall unit panel 2 is provided with a first partition wall slope 21, and the second partition wall unit panel 3 is provided with a second partition wall slope 31, and the first partition wall slope 21 is connected with the second partition wall slope The slope and size of the wall slope 31 are the same, the first partition wall slope 21 and the second partition wall slope 31 are connected by a laminated rubber member 4, the first partition wall slope 21, the second partition wall slope 31 TB1521 industrial adhesive is used for bonding with the laminated rubber member 4; the side wall of the rectangular parallelepiped partition wall 1 in the length direction is provided with a mortise 5, and the opposite side wall is provided with a The mortise 5 is engaged with the tenon 6, and the cuboid partition wall panels 1 are interlocked and connected by the mortise 5 and the tenon 6 to form a prefabricated partition wall; the first partition wall slope 21 and the second partition wall slope The slope angle of 31 is 70 degrees. The section of the first partition wall unit panel 2 in the longitudinal direction of the rectangular parallelepiped partition wall panel 1 is a right-angled trapezoid, and the section of the second partition wall unit panel 3 in the longitudinal direction of the rectangular parallelepiped partition wall panel 1 is triangular. The first partition wall slope 21 and the second partition wall slope 31 form a partition wall splicing surface 7, and the two cuboid partition wall panels 1 are engaged and connected to each other to form a partition wall unit 8. The two cuboid partition wall panels 1 The partition wall splicing surfaces 7 are connected on the same plane to form the connection surface 9 of the partition wall unit 8 . The partition wall splicing surface 7 of the two cuboid partition wall panels 1 is on the same plane as the diagonal surface of the partition wall unit 8, that is, the connecting surface 9 of the partition wall unit 8 and the partition wall unit 8 Diagonal faces are on the same plane. The board 2 of the first partition wall unit 8 and the board 3 of the second partition wall unit 8 are hollow lightweight partition wall boards of silicon magnesium aerated concrete.

As shown in FIG. 2 , the laminated rubber member 4 includes 11 steel plates 41 with a thickness of 1 mm and 12 layers of rubber 42 with a thickness of 3 mm. Through calculation, S ₁ =16.9 and S ₂ =5.6 meet the requirements. Among them, S1 is the _first shape factor, that is, the ratio of the effective pressure-bearing area of each adhesive layer to the free surface area; S2 is the _second shape factor, which is the ratio of the effective pressure-bearing area to the total thickness of the adhesive layer.

As shown in Figure 5, the prefabricated assembled energy-dissipative seismic wall can be spliced with odd numbers of cuboid partition wall panels 1, wherein the number of the cuboid partition wall panels 1 is an odd number, and the prefabricated assembled energy-dissipative seismic wall The body is formed by splicing the partition wall unit 8 and the cuboid partition wall panel 1; first, the cuboid partition wall panel 1 is spliced into the partition wall unit 8, and then the partition wall units 8 are spliced together, and assembled into the assembly For the side of the energy-dissipating and anti-seismic wall, the cuboid partition wall panel 1 and the partition wall unit 8 are spliced, wherein the cuboid partition wall panel 1 is located on the side of the assembled energy-dissipating and anti-seismic wall, and the The plane where the connecting surface 9 of the partition wall unit 8 is located intersects the plane where the partition wall splicing surface 7 of the cuboid partition wall panel 1 is located.

As shown in Figure 6, the prefabricated assembled energy-dissipating anti-seismic wall can also be spliced with even numbers of cuboid partition wall panels 1, wherein the cuboid partition wall panels 1 are an even number N, and the prefabricated assembled energy-dissipating anti-seismic wall The body is spliced sequentially from left to right using 1 to N/2 partition wall units 8, and the connecting surfaces 9 of the first to M partition wall units 8 are parallel to each other; the (M+1) The connection surfaces 9 of the first to N/2 partition wall units 8 are parallel to each other, and intersect with the plane where the connection surfaces 9 of the first to M partition wall units 8 are located; wherein, the M=[N/4 ], that is, M takes an integer. In this example, N is 12. From left to right, the connection surfaces 9 of the first to third partition wall units 8 are parallel to each other, and the connection surfaces 9 of the fourth to sixth partition wall units 8 are parallel to each other, and the former The connection surface 9 intersects the plane of the latter connection surface 9 to form a symmetrical splicing.

The connection joints of the laminated rubber components formed between the above-mentioned even-numbered and odd-numbered plates are cracks that often occur under earthquake action, and have better energy dissipation and seismic performance.

In the splicing of prefabricated assembled energy-dissipating seismic walls, odd-numbered splicing or even-numbered splicing can be performed as required, or a combination of odd-numbered splicing and even-numbered splicing can be used.

Numerical simulation calculations are carried out on the four-story frame structure using the prefabricated partition wall. The floor height of the frame structure is 3.2m, the total height of the structure is 3.2×4=12.8m, the bays are 6×4m, the total length of the frame structure is 6×4=24m, and the total width of the frame structure is 4×2=8m. The size of the horizontal main beam is 400×600mm, and the size of the vertical main beam is 300×500mm. The maximum displacement and acceleration of the top and bottom floors of the frame structure under two different support conditions, the specific parameter values are shown in Table 1:

The simulation result table of table 1 embodiment 1 and comparative example

Comparative example No seismic prefabricated partition wall DisplacementX(mm) Acceleration a(cm/s ² ) top floor 17.3 795.03 bottom layer 18.74 739.21 Example 1 There is an anti-seismic prefabricated partition wall DisplacementX(mm) Acceleration a(cm/s ² ) top floor 15.46 740.05 bottom layer 14.96 714.18

From the data analysis in Table 1 above, it can be seen that the seismic partition wall in Example 1 can reduce the top acceleration of the frame structure by 6.9%, and reduce the top displacement by 10.6%, which has good seismic performance; and has high construction efficiency and convenient installation.

Example 2

An assembly method of the assembled energy-dissipating earthquake-resistant wall of embodiment 1, comprising the following steps:

Step A: Install the cuboid partition board first, then align the tenon of the cuboid partition board with the tenon of another cuboid partition board for splicing, connect the cuboid partition boards together in turn, and adjust the verticality and adjacent boards flatness of the surface;

Step B: lay out the wires on the ground and ceiling panels, and install the cuboid partition wall panels in sequence from one end of the main wall or column to the other end, and when there is a door opening, install it from the door opening to both sides;

Step C: Install the positioning board first, scrape the adhesive material at the groove and top surface of the cuboid partition wall board, seal the upper end of the cuboid partition wall board, align the positioning board up and down, and the cuboid partition wall board The lower end of the wall panel is 30mm-60mm away from the ground;

Step D: drive a wooden wedge into the solid rib at the lower part of the cuboid partition wall and wedge tightly; use the wooden wedge to put the cuboid partition wall in place, and squeeze the cuboid partition wall vertically upward so that The top of the rectangular parallelepiped partition board is pressed against the bottom of the beam, and then the rectangular parallelepiped partition board is fixed;

Step E: setting positioning steel clips and anti-seismic steel clips at the joints between the cuboid partition wall panels and the roof, structural beams, main walls, and columns;

Step F: Fill the gaps between the rectangular parallelepiped partition wall boards with bonding material, squeeze the gaps between the boards tightly, and scrape the extruded bonding materials flat; The gap between the body and the floor is filled with dry hard fine stone concrete; the wooden wedges are taken out after 3 days of curing on the vertical slabs, and the wedge holes are filled.

The specific implementations described above are preferred implementations of the present utility model, and are not intended to limit the specific implementation scope of the present utility model. The scope of the present utility model includes but is not limited to this specific implementation. , The equivalent changes made by the structure are all within the protection scope of the present utility model.

Claims (9)

1. an assembled assembles power consumption antidetonation body of wall, it is characterized in that: it includes cuboid partition plate, described cuboid partition plate includes the first partition wall cell board and the second partition wall cell board, described first partition wall cell board is provided with the first partition wall inclined-plane, described second partition wall cell board is provided with the second partition wall inclined-plane, described first partition wall inclined-plane and the gradient on the second partition wall inclined-plane and size are identical, are connected by laminated rubber component between described first partition wall inclined-plane and the second partition wall inclined-plane；One sidewall of described cuboid partition plate length direction is provided with tongue-and-groove, another relative sidewall be provided with sting with described tongue-and-groove and tenon, mutually sting between described cuboid partition plate and connect and compose assembling type partition wall.

Assembled the most according to claim 1 assembles power consumption antidetonation body of wall, it is characterised in that: the draft angle on described first partition wall inclined-plane and the second partition wall inclined-plane is 60-80 degree.

Assembled the most according to claim 2 assembles power consumption antidetonation body of wall, it is characterized in that: described first partition wall cell board is right-angled trapezium in the cross section of described cuboid partition plate length direction, described second partition wall cell board is triangle in the cross section of described cuboid partition plate length direction.

Assembled the most according to claim 2 assembles power consumption antidetonation body of wall, it is characterized in that: the first partition wall inclined-plane of described cuboid partition plate and the second partition wall inclined-plane form partition wall Mosaic face, connection composition partition wall unit it is mutually twisted between two cuboid partition plates, the partition wall Mosaic face of said two cuboid partition plate at grade, forms the joint face of partition wall unit.

Assembled the most according to claim 4 assembles power consumption antidetonation body of wall, it is characterised in that: the diagonal plane of the partition wall Mosaic face of said two cuboid partition plate and described partition wall unit is at grade.

Assembled the most according to claim 5 assembles power consumption antidetonation body of wall, it is characterized in that: described assembled assembles power consumption antidetonation body of wall and obtains for using cuboid partition plate to carry out odd number splicing, wherein, the quantity of described cuboid partition plate is odd number, and described assembled assembles power consumption antidetonation body of wall for using described partition wall unit and cuboid partition plate to be spliced；Described cuboid partition plate is positioned at described assembled and assembles the side of power consumption antidetonation body of wall, and the plane at the joint face place of described partition wall unit intersects with the plane at the partition wall Mosaic face place of described cuboid partition plate.

Assembled the most according to claim 5 assembles power consumption antidetonation body of wall, it is characterized in that: described assembled assembles power consumption antidetonation body of wall and obtains for using cuboid partition plate to carry out even number splicing, wherein, described cuboid partition plate is even number N, described assembled assembling power consumption antidetonation body of wall is for from left to right to use 1 ~ N/2 partition wall unit to be spliced successively, and the joint face of described 1st ~ m-th partition wall unit is parallel to each other；Described (M+1) individual ~ and the joint face of the N/2 partition wall unit is parallel to each other, and intersects with the plane at the joint face place of the 1st ~ m-th partition wall unit；Wherein, described M=[N/4].

8. assemble power consumption antidetonation body of wall according to the assembled described in claim 1 ~ 7 any one, it is characterised in that: form factor S of described laminated rubber component meets: S₁> 15,6 > S₂> 3, wherein, S₁It is the first form factor, the ratio of the most each glue-line effective pressure area and free area；S₂It is the second form factor, for the ratio of effective pressure area with glue-line gross thickness.

Assembled the most according to claim 8 assembles power consumption antidetonation body of wall, it is characterised in that: use the industrial adhesive bonds of TB1521 between described first partition wall inclined-plane, the second partition wall inclined-plane and described laminated rubber component；Described first partition wall cell board and the second partition wall cell board are silicon magnesium air entrained concrete hollow, light wt. partition.