Pier anti-collision protective cylinder with low rigidity and high energy consumption

文档序号:1517265 发布日期:2020-02-11 浏览:4次 中文

阅读说明:本技术 一种低刚度高耗能的桥墩防撞护筒 (Pier anti-collision protective cylinder with low rigidity and high energy consumption ) 是由 张旭辉 李超 王磊 陈秋池 周兴 于 2019-11-07 设计创作,主要内容包括:本发明公开一种低刚度高耗能的桥墩防撞护筒,该防撞护筒是由2-4个防撞护片通过梢杆系统连接而成的环柱状结构,各防撞护片相互独立,可自由运输、安装、拆除和更换,便于车船撞击后的维修更换。防撞护片内部填充有负泊松比腔体模块,不仅具备腔体结构初始刚度小的优势;同时具备负泊松比结构特殊的力学性能,在受到车船撞击发生纵向压缩的同时也会发生横向收缩,使得腔体结构向受冲击区域汇集,局部密度和侧向刚度增大,能有效提高阻尼力和吸能效果。该护筒具备初始刚度小,受压强化,高承载、高耗能等良好效果。此外,通过负泊松比腔体模块承压板的变厚度设计,能够实现梯度耗能和梯度刚度,对不同冲击能量下的车船撞击均具有良好的缓冲适应性。(The invention discloses a pier anti-collision protective barrel with low rigidity and high energy consumption, which is an annular columnar structure formed by connecting 2-4 anti-collision protective pieces through a pin rod system, wherein the anti-collision protective pieces are mutually independent and can be freely transported, installed, dismantled and replaced, and the pier anti-collision protective barrel is convenient to maintain and replace after a vehicle and a ship are impacted. The anti-collision protection sheet is internally filled with the negative Poisson ratio cavity module, so that the anti-collision protection sheet has the advantage of small initial rigidity of a cavity structure; meanwhile, the structure has special mechanical properties of a negative Poisson ratio structure, and can be transversely contracted when longitudinally compressed when impacted by vehicles and ships, so that the cavity structure is converged to an impacted area, the local density and the lateral rigidity are increased, and the damping force and the energy absorption effect can be effectively improved. The pile casing has the advantages of small initial rigidity, pressure reinforcement, high bearing capacity, high energy consumption and the like. In addition, through the variable thickness design of the negative Poisson ratio cavity module bearing plate, gradient energy consumption and gradient rigidity can be realized, and the buffer device has good buffer adaptability to vehicle and ship impacts under different impact energies.)

1. A low-rigidity high-energy-consumption pier anti-collision protective cylinder is characterized in that the anti-collision protective cylinder is of an annular columnar structure formed by connecting 2-4 anti-collision protective sheets through a pin-rod system, the inner cylindrical surface of the anti-collision protective cylinder is designed into a cylindrical surface, a square cylindrical surface or a round end surface according to the appearance of a pier and can be well attached to the pier, and the outer cylindrical surface of the anti-collision protective cylinder is a cylindrical surface, a round end surface, an elliptic cylindrical surface or a ship-shaped cylindrical surface; the shell of the anti-collision protection sheet is formed by welding a top plate, a bottom plate, a side plate, an inner panel and an outer panel, the inner edge of the side plate is welded with discontinuous pin inserting holes along the height, 2-8 layers of negative poisson ratio cavity modules are filled in the anti-collision protection sheet, and the negative poisson ratio cavity modules and the bridge pier are distributed in a radial mode on the same central line.

2. The device of claim 1, wherein the negative poisson's ratio cavity module is a single body of an inward concave hexagonal honeycomb structure formed by two bearing plates and two connecting plates; the bearing plates are thin plates with certain angles of concave parts, the two bearing plates are arranged in an axisymmetric mode, and the two ends of the bearing plates are connected through the connecting plates to form a single concave hexagonal honeycomb structure.

3. The device of claim 1, wherein the negative poisson's ratio cavity module is arranged in multiple layers, the bearing plates are continuous zigzag thin plates distributed continuously between each layer, and the adjacent bearing plates are symmetrically distributed by taking the central line of the two bearing plates as an axis; the connecting plates connect the adjacent bearing plates at the tooth valleys of the sawteeth respectively to form a layered structure.

4. The device of claim 1, wherein the number of layers of the negative poisson's ratio cavity module is 2-8, and is specifically determined according to the collision-resistant requirement, and the larger the number of layers, the better the collision-resistant energy dissipation performance of the device and the higher the safety factor.

5. The apparatus of claim 1, wherein the multi-layer negative poisson's ratio cavity module has a thickened thin plate as the continuous serrated bearing plate, the bearing plate is thinner near the inner panel of the bumper guard, the bearing plate is thicker near the outer panel of the bumper guard, and the outer panel of the bumper guard is slightly thicker than other plates.

6. The apparatus of claim 1, wherein the negative poisson's ratio cavity module internal cavity is further filled with energy-consuming core, and the energy-consuming core can be porous lightweight aggregate concrete, metal foam, rubber, and the like.

7. The device as claimed in claim 1, wherein the pin rod system is composed of a pin rod, pin tubes and pin caps, each collision-prevention guard plate is provided with 4-8 pin tubes which are sequentially welded at intervals and in flush with the inner edges of two side plates of the collision-prevention guard plate; the number of screw heads arranged in the inner hole of the screw tip cap is 1, and the screw heads are welded at the bottom of the inner edge of one side plate of each anti-collision protection sheet; the screw tip rod is a long rod which is level with the anti-collision protection sheet and is provided with a screw cap and a screw end, the rod diameter of the long rod is equal to or slightly smaller than the inner diameter of the screw tip pipe, the screw end of the screw tip pipe is matched with the screw cap, and the screw tip pipe and the screw cap can be screwed and fixed.

8. The apparatus of claim 1, wherein the bumper guard, the bolt pin, and the negative poisson's ratio cavity block are made of the same or different materials, preferably low yield steel, stainless steel, alloy materials, high strength rubber plates, and fiber plates.

9. The apparatus of claim 1, wherein the crash panel housing is sealed and waterproof, can float on the water surface and move with the water level up and down, and can be used for the crash protection of bridge piers in water and on land.

10. The device according to any one of claims 1 to 9, wherein any one of the above requirements is required for manufacturing the pier anti-collision casing with low rigidity and high energy consumption.

Technical Field

The invention relates to a pier anti-collision protective cylinder with low rigidity and high energy consumption, and belongs to the field of bridge structure vehicle and ship anti-collision and disaster reduction.

Background

In recent years, due to the high-speed increase of national economy, ships, vehicles and other transportation means are more and more, the appearance size and traffic density are also continuously increased, and in addition, due to the severe change of the external environment and subjective factors such as drunk driving and fatigue driving, accidents of collision of the ships, vehicles and the like on bridge abutments can often occur, so that the use safety and the service life of the bridges are influenced, the safety of the ships and the vehicles is threatened, and even serious catastrophic accidents can be caused. Therefore, it is necessary to take effective measures to avoid the collision of the bridge abutment with the vehicle or the ship or to reduce the damage caused by the collision.

At present, the vehicle and ship collision prevention of the bridge mainly comprises the following two aspects: on one hand, the probability of collision caused by congestion or narrowness is reduced by widening the distance between the bridge abutments; on the other hand, the collision avoidance device is arranged on the bridge pier, so that the damage caused by collision of vehicles and ships is reduced. For the latter, the currently commonly used anti-collision devices include a rubber fender mode and a rope pulling mode which absorb energy through elastic deformation, a wood structure protection, a reinforced concrete structure and a steel sleeve box which absorb energy through plastic deformation, a displacement gravity type protection device which converts kinetic potential energy into energy consumption, and the like. Different devices have the characteristics that the displacement is large when the rubber fender is collided, but the energy absorption is small; the concrete structure protection and steel jacket box consume impact kinetic energy through plastic deformation, but the rigidity is high, and large impact force can be generated at the moment of collision. The ideal bridge pier anti-collision device has the characteristics of low rigidity, high energy consumption, high bearing capacity, convenience in maintenance and replacement and the like.

Disclosure of Invention

The invention aims to provide a pier anti-collision protective cylinder with low rigidity and high energy consumption, which can effectively solve the problems and adopts the following specific technical scheme:

a low-rigidity high-energy-consumption pier anti-collision protective cylinder is of a ring-column-shaped structure formed by connecting 2-4 anti-collision protective sheets through a pin rod system, wherein the inner cylindrical surface of the anti-collision protective cylinder is designed into a cylindrical surface, a square cylindrical surface or a circular end surface according to the appearance of a pier and can be well attached to the pier, and the outer cylindrical surface of the anti-collision protective cylinder is a cylindrical surface, a circular end surface, an elliptic cylindrical surface or a ship-shaped cylindrical surface; the shell of the anti-collision protection sheet is formed by welding a top plate, a bottom plate, a side plate, an inner panel and an outer panel, the inner edge of the side plate is welded with discontinuous pin inserting holes along the height, 2-8 layers of negative poisson ratio cavity modules are filled in the anti-collision protection sheet, and the negative poisson ratio cavity modules and the bridge pier are distributed in a radial mode on the same central line.

Furthermore, the single body of the negative Poisson ratio cavity module is of an inwards concave hexagonal honeycomb structure consisting of two bearing plates and two connecting plates; the bearing plates are thin plates with certain angles of concave parts, the two bearing plates are arranged in an axisymmetric mode, and the two ends of the bearing plates are connected through a connecting plate to form a single concave hexagonal honeycomb cavity structure.

Furthermore, the negative Poisson ratio cavity module is arranged in multiple layers, the pressure bearing plates are continuous sawtooth-shaped thin plates which are continuously distributed among the layers, and the adjacent pressure bearing plates are symmetrically distributed by taking the central lines of the two pressure bearing plates as axes; the connecting plates connect the adjacent bearing plates at the tooth valleys of the sawteeth respectively to form a layered structure.

Further, the number of layers of the negative poisson ratio cavity module is 2-8, the number of layers is determined according to the collision resistance requirement, the more the number of layers is, the better the collision resistance and energy consumption performance of the device is, and the higher the safety factor is.

Furthermore, the continuous sawtooth-shaped bearing plate of the multilayer negative poisson ratio cavity module is a variable-thickness thin plate, the bearing plate close to the inner panel of the anti-collision protection sheet is thinner, the bearing plate close to the outer panel of the anti-collision protection sheet is thicker, and the outer panel of the anti-collision protection sheet is slightly thicker than other plates.

Furthermore, the inner cavity of the negative poisson's ratio cavity module can be further filled with an energy-consuming inner core, and the energy-consuming inner core can be porous lightweight aggregate concrete, metal foam, rubber and the like.

Furthermore, the pin rod system consists of a pin rod, pin tubes and pin caps, 4-8 pin tubes are arranged on each anti-collision protective sheet and are sequentially welded on the inner edges of the two side plates of the anti-collision protective sheet at intervals and in a flush manner; the number of screw heads arranged in the inner hole of the screw tip cap is 1, and the screw heads are welded at the bottom of the inner edge of one side plate of each anti-collision protection sheet; the screw tip rod is a long rod which is level with the anti-collision protection sheet and is provided with a screw cap and a screw end, the rod diameter of the long rod is equal to or slightly smaller than the inner diameter of the screw tip pipe, the screw end of the screw tip pipe is matched with the screw cap, and the screw tip pipe and the screw cap can be screwed and fixed.

Furthermore, the anti-collision protection sheet, the screw tip rod and the negative poisson's ratio cavity module are made of the same or different materials, and low-yield steel, stainless steel, alloy materials, high-strength rubber plates and fiber boards are preferably selected as the materials.

Furthermore, the shell of the anti-collision protection sheet is sealed and waterproof, can float on the water surface and move along with the rise and fall of the water level, and the anti-collision protection sheet can be used for anti-collision protection of bridge piers in water and on land.

The invention has the beneficial effects that: firstly, the protective barrel is of a ring-column structure formed by connecting 2-4 anti-collision protective pieces through a pin-rod system, and the anti-collision protective pieces are independent from each other and can be freely transported, installed, disassembled and replaced, thereby being very convenient for repairing and replacing the anti-collision protective barrel after the vehicle and the ship are impacted. Secondly, 2-8 layers of negative poisson ratio cavity modules are filled in each anti-collision protection sheet, so that the anti-collision protection sheet has the advantage of small initial rigidity of a cavity structure, and can effectively reduce the impact force of vehicles and ships; meanwhile, the energy-absorbing cavity has special mechanical properties of a negative poisson ratio structure, and can be transversely contracted when longitudinally compressed when impacted by vehicles and ships, so that the cavity structure is converged to an impacted area, the local density and the lateral rigidity are increased, the damping force and the energy-absorbing effect are further effectively improved, and particularly, the energy-absorbing effect can be further improved after an energy-consuming inner core is further filled in a negative poisson ratio cavity module. The anti-collision protection sheet has the advantages of small initial rigidity, gradual reinforcement under pressure, high bearing capacity, high energy consumption and other good buffering effects, and can effectively protect the safety of bridge structures and vehicles and ships. In addition, through the variable thickness design of the negative Poisson ratio cavity module bearing plate, gradient energy consumption and gradient rigidity can be realized, and the buffer device has good buffer adaptability to vehicle and ship impacts under different impact energies.

The present invention will be described in detail with reference to the accompanying drawings.

Drawings

FIG. 1 is a schematic view of the installation of a pier anti-collision casing on a pier in the present invention;

FIG. 2 is a schematic view of the assembly and disassembly of the anti-collision pier casing according to the present invention;

FIG. 3 is an exploded view of the bumper guard of the present invention;

FIG. 4 is a comparative graph of stress analysis of an anti-collision pier casing according to the present invention;

fig. 5 is a multi-style plan view of the pier anti-collision casing of the present invention.

Reference numerals: 1, an anti-collision protection sheet; 1.1 an outer panel; 1.2 inner panel; 1.3 a top plate; 1.4 a bottom plate; 1.5 side plates; 1.6 negative Poisson ratio cavity module bearing plate; 1.7 negative poisson's ratio cavity module connecting plate; 2 a tip-rod system; 2.1 a screw tip rod; 2.2, a tip pipe; 2.3 screw tip cap.

Detailed Description

The technical solution in the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings in the embodiments of the present invention. The embodiments described are only a part of the embodiments of the present invention, and not all embodiments, and therefore, the present invention is not limited to the protection scope of the present invention, which is described in the first place.

Referring to fig. 1 to 5, a pier anti-collision casing with low rigidity and high energy consumption according to a first preferred embodiment of the present invention is shown, and the pier anti-collision casing is an annular columnar structure formed by connecting 2 to 4 anti-collision casing pieces through a pin-rod system, and 2 to 8 layers of negative poisson ratio cavity modules are filled in the anti-collision casing pieces, and has the characteristics of low initial rigidity and negative poisson ratio structure of the cavity structure, reinforced compression, high load bearing, high energy consumption, and the like.

The design scheme of the embodiment is as follows:

a low-rigidity high-energy-consumption pier anti-collision protective cylinder is of an annular columnar structure formed by connecting 2-4 anti-collision protective pieces 1 through a pin rod system 2, wherein the inner cylindrical surface of the anti-collision protective cylinder is designed into a cylindrical surface, a square cylindrical surface or a round end surface according to the appearance of a pier and can be well attached to the pier, and the outer cylindrical surface of the anti-collision protective cylinder is a cylindrical surface, a round end surface, an elliptic cylindrical surface or a ship-shaped cylindrical surface; the outer shell of the anti-collision protection piece 1 is formed by welding an outer panel 1.1, an inner panel 1.2, a top plate 1.3, a bottom plate 1.4 and side plates 1.5, discontinuous pin inserting holes are welded on the inner edges of the side plates along the height direction, 2-8 layers of negative poisson ratio cavity modules are filled in the anti-collision protection piece 1, and the negative poisson ratio cavity modules and the bridge piers are distributed in a radial shape on the same central line.

The single body of the negative Poisson ratio cavity module is an inwards concave hexagonal honeycomb structure consisting of two bearing plates 1.6 and two connecting plates 1.7; the bearing plates 1.6 are thin plates with certain angles of concave parts, the two bearing plates 1.6 are arranged in an axial symmetry mode, and the two ends of the bearing plates are connected through the connecting plate 1.7 to form a single concave hexagonal honeycomb cavity structure.

The negative Poisson ratio cavity module is arranged in multiple layers, the pressure bearing plates 1.6 are continuous zigzag thin plates which are continuously distributed among the layers, and the adjacent pressure bearing plates 1.6 are symmetrically distributed by taking the center lines of the two pressure bearing plates as axes; the connecting plates 1.7 connect the adjacent bearing plates 1.6 at the tooth valleys of the sawteeth respectively into a layered structure.

The number of layers of the negative Poisson ratio cavity module is 2-8, and is determined according to the collision resistance requirement, the more the number of layers is, the better the collision resistance and energy consumption performance of the device is, and the higher the safety factor is.

The continuous sawtooth-shaped bearing plate 1.6 of the multilayer negative Poisson ratio cavity module is a variable thickness thin plate, the bearing plate 1.6 close to the inner panel of the anti-collision protection sheet 1 is thinner, the bearing plate 1.6 close to the outer panel of the anti-collision protection sheet 1 is thicker, and the outer panel of the anti-collision protection sheet 1 is slightly thicker than other plates.

The inner cavity of the negative Poisson ratio cavity module can be further filled with an energy-consuming inner core, and the energy-consuming inner core can be porous lightweight aggregate concrete, metal foam, rubber and the like.

The pin rod system 2 consists of a pin rod 2.1, pin tubes 2.2 and pin caps 2.3, each anti-collision protective sheet 1 is provided with 4-8 pin tubes 2.2, and the pin tubes are sequentially welded on the inner edges of two side plates of the anti-collision protective sheet 1 at intervals and in parallel; the number of the screw heads arranged in the inner hole of the screw tip cap 2.3 is 1, and the screw heads are welded at the bottom of the inner edge of one side plate of each anti-collision protection sheet 1; the screw tip rod 2.1 is a long rod which is level with the anti-collision protection sheet 1 and is provided with a screw cap and a screw end head, the rod diameter of the long rod is equal to or slightly smaller than the inner diameter of the screw tip tube 2.2, the screw end head of the screw tip rod 2.1 is matched with the screw tip cap 2.3, and the screw tip rod and the screw tip cap can be screwed and fixed. When the anti-collision protection sheet is installed, the proper positions are adjusted to align the inner holes of the tip pipes 2.2 of the adjacent anti-collision protection sheets 1, then the tip pipes 2.2 are sequentially inserted by using the tip rods 2.1 and are screwed and fixed in the tip caps 2.3, and the anti-collision protection sheets 1 are connected and assembled.

The anti-collision protection sheet 1, the screw tip rod 2.1 and the negative poisson's ratio cavity module are made of the same or different materials, and low-yield steel, stainless steel, alloy materials, high-strength rubber plates and fiber plates are preferably selected as the materials.

The shell of the anti-collision protection sheet 1 is sealed and waterproof, can float on the water surface and move along with the water level, and the anti-collision protection sheet 1 can be used for anti-collision protection of bridge piers in water and on land.

The applicant states that a new method generated by combining some steps of the above-mentioned embodiment with the technical solution of the summary of the invention is also one of the description scope of the present invention, and other embodiments of these steps are not listed in the present application for the sake of brevity.

In the above embodiment, a pier anti-collision protective barrel with low rigidity and high energy consumption is provided, and is an annular columnar structure formed by connecting 2 to 4 anti-collision protective pieces through a pin rod system, wherein 2 to 8 layers of negative poisson ratio cavity modules are filled in the anti-collision protective pieces, and the pier anti-collision protective barrel has the characteristics of low initial rigidity and negative poisson ratio structure of a cavity structure, reinforced compression, high bearing, high energy consumption and the like. Meanwhile, the anti-collision protection pieces are connected through a pin-rod system and can be independently transported, installed, dismantled and replaced, and the anti-collision protection barrel is convenient to maintain and replace after the vehicle and the ship are impacted.

The technical principle is as follows: the invention provides a pier anti-collision protective cylinder with low rigidity and high energy consumption, which is essentially of a structure that a negative poisson ratio cavity module and an energy consumption inner core are filled in an anti-collision protective sheet 1. Firstly, the protective sleeve is a ring-column-shaped structure formed by welding 2-4 anti-collision protective sheets 1 with discontinuous pin inserting holes through the inner edge of a side plate and fixing the anti-collision protective sheets by using a pin rod system 2, and the anti-collision protective sheets 1 are mutually independent and can be freely transported, installed, dismantled and replaced, thereby being very convenient for maintaining and replacing the anti-collision protective sleeve after the vehicle and the ship are impacted; simultaneously, the protective cylinder can be used for collision avoidance of piers on water and land, and can float on the water surface and move along with the rise and fall of the water level due to the fact that the shell of the collision-prevention protective sheet 1 is sealed and waterproof when being applied to collision avoidance of piers on water, and the phenomenon that the rise and fall of the water level are lower than or exceed the collision-prevention protective cylinder to cause that the protective effect cannot be achieved is avoided. Secondly, 2-8 layers of negative poisson ratio cavity modules are filled in each anti-collision protection sheet 1, so that the anti-collision protection sheet has the advantage of small initial rigidity of a cavity structure, and can effectively reduce the impact force and damage degree of vehicles and ships, and people, vehicles and ships and piers are beneficial to safety guarantee; the anti-collision device has the advantages that the anti-collision device has special mechanical properties of a negative poisson ratio structure, longitudinal compression is caused by the collision of a vehicle and a ship on the traditional anti-collision device, and meanwhile, transverse diffusion is caused, so that the phenomenon that the collision position is concave and the two sides are convex obviously occurs, however, the anti-collision device is longitudinally compressed by the collision of the vehicle and the ship, and simultaneously, transverse contraction is caused, so that the cavity structure is converged to an impacted area, the local density and the lateral rigidity are increased, the damping force and the energy absorption effect are further effectively improved, the collision deformation is smaller than that of the traditional anti-collision device, particularly, after an energy-consuming inner core is further filled in a negative poisson ratio cavity module, the energy-. In addition, through the variable thickness design of the negative Poisson ratio cavity module bearing plate 1.6, gradient energy consumption and gradient rigidity can be realized, and the buffer device has good buffer adaptability to vehicle and ship impacts under different impact energies. Therefore, the anti-collision protection sheet 1 has low initial rigidity, can be gradually strengthened under pressure, and has good buffering effects of high bearing capacity, high energy consumption and the like.

According to the technical principle of the invention, the principle is applied to pier anti-collision protective cylinders with other shapes, for example, the inner cylindrical surface of the anti-collision protective cylinder is designed into a cylindrical surface, a square cylindrical surface or a round end surface according to the appearance of a pier, and the outer cylindrical surface of the anti-collision protective cylinder is a cylindrical surface, an elliptic cylindrical surface, a round end surface or a ship-shaped cylindrical surface, and the same technical effects can be achieved.

The applicant further states that the present invention is described by the above embodiments to explain the structure and implementation method of the apparatus of the present invention, but the present invention is not limited to the above embodiments, i.e. it is not meant to imply that the present invention must rely on the above structures and methods to implement the present invention. It should be understood by those skilled in the art that any modifications to the present invention, the addition of equivalent alternatives to the embodiments of the present invention and steps, the selection of specific modes, etc., are within the scope of the present invention and the disclosure.

The present invention is not limited to the above embodiments, and all embodiments adopting the similar structure and method to achieve the object of the present invention are within the protection scope of the present invention.

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