CN212001592U - Bamboo wood structure energy dissipation shock attenuation node - Google Patents
Bamboo wood structure energy dissipation shock attenuation node Download PDFInfo
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- CN212001592U CN212001592U CN201922226620.8U CN201922226620U CN212001592U CN 212001592 U CN212001592 U CN 212001592U CN 201922226620 U CN201922226620 U CN 201922226620U CN 212001592 U CN212001592 U CN 212001592U
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Abstract
The invention discloses an energy dissipation and shock absorption node of a bamboo-wood structure, which comprises a column sleeve, a beam sleeve, an arc-shaped hinged plate, a pin shaft hole, a pin shaft, a stiffening plate, a sticky elastic plate, a bolt and the like. The upper and lower layers of columns are connected through a column sleeve, an arc-shaped hinged plate is welded on the column sleeve, and a pin shaft hole is formed in the arc-shaped hinged plate. The beam sleeves are arranged at the two ends of the beam, the arc-shaped hinged plate is welded on the beam sleeves, and pin shaft holes are formed in the arc-shaped hinged plate. The arc-shaped hinged plates on the column sleeve and the beam sleeve are arranged in a staggered mode, the positions of the arc-shaped hinged plates are adjusted to enable pin shaft holes to be in concentric circle positions, and the viscoelastic plates are adhered and fixed on the arc-shaped hinged plates on two sides by building super glue. And a hinge joint is formed after the pin shafts are inserted for connection. After the joint is subjected to strong shock or strong wind, the joint can generate torsional motion around the pin shaft, so that the viscoelastic plate is driven to rotate along with the torsional motion, and the vibration energy is consumed. The invention has simple structure, convenient installation and good energy dissipation and shock absorption effects, and can obviously reduce the vibration response of the structure under the action of disasters.
Description
Technical Field
The invention relates to the field of design of beam-column joints of bamboo-wood structures, in particular to an energy dissipation and shock absorption joint of a bamboo-wood structure.
Background
The bamboo structure has the advantages of light weight, energy conservation, environmental protection, flexible design, elegant appearance and the like, can show rich and various architectural styles, and has good bearing capacity in the aspect of structural performance. Because the beam column length of bamboo structure or timber structure is limited, must realize the equipment through the node connecting piece, traditional bamboo timber structure is connected and is fixed through metal connecting piece or tenon fourth of twelve earthly branches means. When the metal connecting pieces are adopted for node connection, the common nodes do not have the energy dissipation and shock absorption effects, the node strength of the tenon-and-mortise connection mode is poor, and the overall shock resistance and other capacities of the building can be reduced rapidly. When receiving earthquake or wind vibration, the beam column connected node of bamboo wood structure often can appear damaging, produces the potential safety hazard, still can influence its life. In addition, the structure that adopts metal connecting piece to connect is complicated, and the installation is loaded down with trivial details, can cause the difficulty in the construction, reduces engineering construction efficiency, so need improve its node connecting piece.
Disclosure of Invention
In order to solve the technical problems, the invention provides the bamboo-wood structure node connecting piece which is simple in structure and convenient to install, and not only can improve the shock absorption and energy dissipation effects, but also can improve the safety and durability of the structure. According to the invention, through the arc-shaped hinge plate connecting piece device, when the structure is subjected to earthquake energy input, the arc-shaped hinge plates can rotate, and the viscoelastic material arranged between the arc-shaped hinge plates can be twisted along with the rotation of the arc-shaped hinge plates, so that the purposes of energy dissipation and shock absorption are achieved.
The technical scheme adopted by the invention for solving the technical problems is as follows: the utility model provides a bamboo wood structure energy dissipation shock attenuation node, includes column sleeve, beam sleeve, arc articulated slab, round pin axle, round pin shaft hole, glutinous elastic plate, stiffening plate, bolt hole. The beam column length of bamboo structure or timber structure is limited, must realize the equipment through the node connection spare, the length of single post is the same with the floor height usually, upper and lower two-layer post passes through the post sleeve and links to each other, set up the baffle in the post sleeve, the baffle position is located the centre, the first half is used for the upper strata post to link to each other, the latter half is used for the lower floor post to link to each other, fix the post in the post sleeve through bolted connection, the welding has arc articulated slab A on the post sleeve, the welding is at the telescopic avris of post, be equipped with round pin axle hole A on it. And a stiffening plate is arranged below the arc-shaped hinge plate A and is used for bearing the shearing force transmitted by the beam. The two ends of the beam are provided with beam sleeves, and the beam is fixed on the beam sleeves through bolt connection. The beam sleeve is welded with an arc-shaped hinged plate B, the arc-shaped hinged plate B is welded on the side of the beam sleeve, the position of the arc-shaped hinged plate B is opposite to that of the arc-shaped hinged plate A, a pin shaft hole B is formed in the arc-shaped hinged plate B, and a pin shaft sequentially penetrates through the pin shaft hole A in the arc-shaped hinged plate A and the pin shaft hole B in the arc-shaped hinged plate B during. And viscoelastic plates are arranged in gaps among the arc-shaped hinge plates. The viscoelastic plate has the advantages of good bonding performance and good elasticity, and high-strength glue is coated on two sides of the viscoelastic plate and is fixed on the arc-shaped hinged plates on two sides. When the hinged point rotates, the viscoelastic plate is twisted, and the node can achieve the effects of energy dissipation and shock absorption due to the characteristic that the stress of the macromolecular substance lags behind the strain.
The pin shaft is made of round steel, and after the center position of the A-shaped pin shaft hole is determined, the position of the beam is adjusted during installation, so that the center position of the B-shaped pin shaft hole on the beam and the center position of the A-shaped pin shaft hole are on the same horizontal straight line. The pin shaft sequentially penetrates through the pin shaft hole A and the pin shaft hole B during installation to form a hinged joint. The arc-shaped hinged plate rotates around the pin shaft, so that the operation is reliable and the disassembly is convenient.
The pin shaft hole A and the pin shaft hole B are equal in size and are matched with the pin shaft, and the size of the pin shaft hole A and the size of the pin shaft hole B are slightly larger than the diameter of the pin shaft, so that the tolerance requirement in machinery is met, and the pin shaft can be smoothly inserted into the pin shaft hole. The position of the pin shaft hole A on the arc-shaped hinged plate A and the position of the pin shaft hole B on the arc-shaped hinged plate B are ensured to meet the assembly requirement of the pin shaft, namely, when the beam column is assembled, the pin shaft hole A and the pin shaft hole B can form a concentric circle after the positions are adjusted.
The viscoelastic plate is made of viscoelastic materials, and both sides of the viscoelastic plate are stuck and fixed on the arc-shaped hinged plate A and the arc-shaped hinged plate B by building super glue. After the arc-shaped hinged plates A and the arc-shaped hinged plates B are arranged in a staggered and alternate mode, the gap interval between the two plates is the same, the thickness of the elastic adhesive plate is the same as that of the gap interval, holes with the same size as that of the pin shaft holes A and B are reserved in the elastic adhesive plate, and the pin shaft can penetrate through the holes during installation. When the hinged joint rotates, because the two sides of the viscoelastic plate are firmly adhered to the arc-shaped hinged plate A and the arc-shaped hinged plate B respectively, and the arc-shaped hinged plate A and the arc-shaped hinged plate B rotate relatively, the viscoelastic plate is forced to perform relative torsional motion around the pin shaft, so that the energy of earthquake or wind vibration is consumed, and the aim of reducing earthquake disasters or wind vibration disasters is fulfilled. The thickness of the viscoelastic plate is determined according to the clearance between the arc-shaped hinge plate A and the arc-shaped hinge plate B.
The beam sleeve is fixed on the beam through a bolt hole by a bolt. When the beam sleeve is installed, the beam sleeve is placed at a proper position of the beam end and then fixed by bolts. The bolts are uniformly arranged on the beam sleeve at equal intervals to ensure the connection stability. The size of the bolt and bolt hole should comply with relevant usage regulations.
The column sleeve is also bolted to the column through bolt holes. When the installation is carried out, the column sleeve is firstly placed at a proper position of the column end and then fixed by the bolt. The bolts are uniformly arranged on the column sleeve at equal intervals to ensure the connection stability. The size of the bolt and bolt hole should comply with relevant usage regulations.
The stiffening plate is arranged below the arc-shaped hinged plate A, the stiffening plate is formed by vertically welding two steel plates, equidistant bolt holes are formed in the steel plates parallel to the columns, and the stiffening plate is fixed on the side of the columns through bolts and used for bearing the shearing force transmitted by the beams.
Compared with the prior art, the invention has the beneficial effects that: the invention has simple structure and convenient construction, the node can generate torsional motion around the pin shaft after the structure is subjected to the action of strong earthquake or strong wind, thereby driving the viscoelastic plate to rotate along with the torsional motion, and consuming vibration energy, thereby ensuring the safety of the whole structure. The invention improves the earthquake-resistant performance of the building, is suitable for the nodes of various newly-built bamboo building structures, and is also suitable for reinforcing the existing bamboo building.
Drawings
In order to more clearly illustrate the technical solutions in the embodiments of the present invention, the drawings needed to be used in the description of the embodiments of the present invention will be briefly introduced below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art that other drawings can be obtained according to these drawings without creative efforts.
FIG. 1 is a schematic structural view of the present invention;
FIG. 2 is a schematic view of the beam-column joint of the present invention;
FIG. 3 is a cross-sectional view taken along line I-I of the present invention;
FIG. 4 is a sectional view of the present invention II-II;
FIG. 5 is a perspective view of a beam-column joint connection of the present invention;
FIG. 6 is a perspective view of a stiffener device according to the present invention;
FIG. 7 is a diagram illustrating various aspects of the present invention;
FIG. 8 is a sectional view of the intermediate column according to the present invention;
FIG. 9 is a cross-sectional view of a corner post according to the present invention;
FIG. 10 is a cross-sectional view of the side post of the present invention.
In fig. 1 to 10, 1 is a column; 2 is a column sleeve; 3 is a pin shaft hole A; 4 is an arc-shaped hinged plate A; 5 is a pin shaft; 6 is an arc-shaped hinged plate B; 7 is a beam sleeve; 8 is a beam; 9 is a bolt hole; 10 is a stiffening plate; 11 is a pin shaft hole B; 12 is a viscoelastic plate.
Detailed description of the invention
In order to make the objects, technical solutions and advantages of the present invention more apparent, the present invention is described in further detail below with reference to the accompanying drawings and embodiments.
Fig. 1 is a schematic view of the whole structure of the energy-dissipating and shock-absorbing node connecting piece of the bamboo-wood structure. For the object bamboo-wood structure aimed by the invention, the beam-column length is limited, and the object bamboo-wood structure is connected into a whole by virtue of nodes. As shown in FIG. 1, the core is that the pin shaft 5 passes through the arc-shaped hinge plate A4 and the pin shaft hole A3 and the pin shaft hole B11 on the arc-shaped hinge plate B6 in sequence to form a hinge point for realizing connection. As shown in FIG. 4, 3 arc-shaped hinge plates A4 are welded on the column sleeve 2, and 2 arc-shaped hinge plates B6 are welded on the beam sleeve. The positions thereof are such that the pin-shaft hole a3 and the pin-shaft hole B11 are concentric circles. The arc-shaped hinge plates A4 and the arc-shaped hinge plates B6 are arranged in a staggered and alternating mode, and the gap spacing is the same. In these gaps, the elastic plate 12 is bonded with a strong adhesive for construction. The thickness of the viscoelastic plate 12 is determined according to the clearance between the curved hinge plate A4 and the curved hinge plate B6. As shown in FIG. 3, when the beam-column node connection is installed, the curved hinge plate A4 and the curved hinge plate B6 on the beam-column are adjusted in position to align their pin hole, and the pin 5 is inserted into these pin hole to form a hinge point, wherein the viscoelastic plate 12 fills the entire gap. As shown in fig. 6, in order to stabilize the beam-column joint, a stiffening plate 10 is provided, and the stiffening plate 10 is fixed to the column by bolts so as to bear the shearing force transmitted from the beam. In order to cope with different practical situations, three different column position situations are presented, namely a middle column, a corner column and a side column. The invention provides an energy dissipation and shock absorption node connecting piece of a bamboo-wood structure, which is characterized by comprising the following construction steps:
(1) as shown in fig. 1, a column sleeve 2 prefabricated in a factory is fixed on a column 1 through a bolt hole 9, and a beam sleeve 7 is fixed on a beam 8 through the bolt hole 9;
(2) as shown in fig. 4, three arc-shaped hinge plates A4 are equidistantly welded on the column sleeve 2, two arc-shaped hinge plates B6 are equidistantly welded on the beam sleeve 7, and pin shaft holes of the arc-shaped hinge plates are arranged in a concentric circle position when the beam sleeve is installed;
(3) as shown in fig. 3, the two sides of the viscoelastic plate 12 are adhered and fixed on the arc-shaped hinge plate a4 of the column and the arc-shaped hinge plate B6 of the beam by building strong glue, the reserved pin shaft hole on the viscoelastic plate 12 is aligned with the pin shaft hole A3 and the pin shaft hole B11, and then the pin shaft 5 is inserted for connection;
(4) as shown in fig. 6, the stiffener plate 10 is fixed to the column 1 by bolts.
The above is only the case in one connection direction of the invention on a column. In practical cases, as shown in fig. 7, the connection node may be a side column connection or a middle column connection, so that the beam-column connection is generally three cases. As shown in fig. 8, four sides of the column are connected to the beam. As shown in fig. 9, the two sides of the post are connected to the beam and form a corner pattern. As shown in fig. 10, three sides of the post are connected to the beam and form a "T" pattern. In practical application, the method is implemented according to different situations.
It will be understood by those skilled in the art that the foregoing is only a preferred embodiment of the present invention, and is not intended to limit the invention, and that any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the scope of the present invention.
Claims (7)
1. The utility model provides a bamboo wood structure energy dissipation shock attenuation node which characterized in that: the upper layer and the lower layer of columns are connected through a column sleeve (2), an arc-shaped hinged plate A (4) is welded on the column sleeve (2), a pin shaft hole A (3) is formed in the column sleeve, a stiffening plate (10) is arranged below the arc-shaped hinged plate A (4), beam sleeves (7) are arranged at two ends of each beam, an arc-shaped hinged plate B (6) is welded on each beam sleeve (7), a pin shaft hole B (11) is formed in each beam sleeve, a pin shaft (5) sequentially penetrates through the pin shaft holes A (3) and the pin shaft holes B (11) in the arc-shaped hinged plate A (4) and the arc-shaped hinged plate B (6) during installation, a hinged joint is formed, and a sticky elastic.
2. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: the pin shaft (5) is made of round steel, and the pin shaft (5) penetrates through the pin shaft hole A (3) and the pin shaft hole B (11) when being installed to form a hinged joint.
3. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: the pin shaft hole A (3) and the pin shaft hole B (11) are the same in size and are matched with the pin shaft (5) and meet tolerance requirements in machinery, and the position of the pin shaft hole A (3) on the arc-shaped hinged plate A (4) and the position of the pin shaft hole B (11) on the arc-shaped hinged plate B (6) are guaranteed to meet assembly requirements of the pin shaft (5).
4. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: viscoelastic plate (12) make for viscoelastic material, both sides are pasted and are fixed on arc-shaped hinged plate A (4) and arc-shaped hinged plate B (6), gap interval in the middle of after arc-shaped hinged plate A (4) and arc-shaped hinged plate B (6) are arranged in turn mutually in a staggered manner is the same, viscoelastic plate (12) thickness is the same with this gap interval, reserve on viscoelastic plate (12) with round pin shaft hole A (3), round pin shaft hole B (11) the same size hole.
5. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: the beam sleeve (7) is fixed on the beam (8) through a bolt hole (9) by a bolt.
6. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: the column sleeve (2) is fixed on the column (1) through a bolt hole (9) by a bolt.
7. An energy dissipation and shock absorption node of bamboo-wood structure according to claim 1, characterized in that: the stiffening plate (10) is arranged below the arc-shaped hinged plate A (4) and is fixed on the side of the column (1).
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CN201922226620.8U CN212001592U (en) | 2019-12-12 | 2019-12-12 | Bamboo wood structure energy dissipation shock attenuation node |
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CN201922226620.8U CN212001592U (en) | 2019-12-12 | 2019-12-12 | Bamboo wood structure energy dissipation shock attenuation node |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN115288305A (en) * | 2022-08-31 | 2022-11-04 | 西安建筑科技大学 | Box structure with hinged top beam |
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
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CN115288305A (en) * | 2022-08-31 | 2022-11-04 | 西安建筑科技大学 | Box structure with hinged top beam |
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