Assembled anti-collision facility for water area bridge pier
Technical Field
The invention belongs to the technical field of water area pier protection, and particularly relates to an assembled anti-collision device for water area piers.
Background
At present, a more effective measure for improving the anti-collision capability of the bridge is to arrange anti-collision facilities. The collision avoidance facilities may be classified into active collision avoidance facilities and passive collision avoidance facilities. The active anti-collision facility means that before the ship bridge collides, the ship can send out early warning signals such as sound, electricity, light and the like to guide, but the bridge pier cannot be fundamentally protected, and only an auxiliary effect can be achieved. The passive anti-collision device is a blocking and protecting pier device arranged for preventing the ship from directly colliding with the pier when the ship is close to the bridge. The passive crashproof facility mainly includes at present:
(1) The anti-collision steel sleeve box, which is directly constructed to resist compression deformation, has the following defects: the steel sleeve box structure has high rigidity, and the ship can be damaged in the impact process;
(2) The floating type flexible anti-collision sheath, which is directly constructed to be elastically deformed, has the following defects: the material has serious performance degradation after being soaked in water for a long time, so that the service life of the material is very limited, and the anti-collision capability is basically lost;
(3) Thin wall cofferdam collision avoidance system-indirect construction compression deformation resistance, the shortcoming is: only bridge piers can be protected, and ships can be seriously damaged due to too large deformation;
because the existing passive anti-collision facilities are not perfect, a new assembly type anti-collision facility for the water area pier needs to be designed.
Disclosure of Invention
The invention aims to provide an assembled anti-collision facility for a water area pier, which aims to solve the problem that the conventional passive anti-collision facility for a bridge is not perfect enough in the background technology.
In order to achieve the above purpose, the invention provides an assembled anti-collision facility for water area piers, which comprises a plurality of anti-collision floating boxes which are sequentially connected around the piers, wherein each anti-collision floating box comprises an anti-collision floating box body and a box body connecting part, the anti-collision floating box body is of an ultra-high performance concrete reinforced structure, two connecting ends of the anti-collision floating box body are respectively provided with two box body connecting parts which are distributed up and down,
the anti-collision floating box is internally provided with an internal energy consumption device for absorbing and consuming the impact energy when the anti-collision floating box body is impacted;
the inside clearance packing of anticollision flotation tank is provided with polymer damping energy consumption material, and when the anticollision flotation tank box was damaged, the buoyancy that the inside polymer damping energy consumption material of packing of anticollision flotation tank box received in water was greater than the gravity of whole anticollision flotation tank.
In a specific embodiment, the box body connecting parts comprise an upper box body connecting part arranged at the upper parts of two connecting ends of the anti-collision floating box body and a lower box body connecting part arranged at the lower parts of two connecting ends of the anti-collision floating box body, the box body connecting parts are plate-shaped and are provided with pin holes, connecting pin shafts are further arranged between adjacent anti-collision floating boxes, the two upper box body connecting parts of the adjacent anti-collision floating boxes are arranged in a staggered manner and are connected through the connecting pin shafts, the two lower box body connecting parts of the adjacent anti-collision floating boxes are arranged in a staggered manner and are connected through the connecting pin shafts, and the two adjacent anti-collision floating box bodies, the upper box body connecting parts and the lower box body connecting parts jointly enclose wave unloading through holes which are transversely communicated with the inner side and the outer side of the assembled anti-collision facility;
the box connecting portion comprises a water stop ring, an embedded steel plate and a rubber block, wherein the embedded steel plate is arranged in the rubber block and used for enhancing the rigidity and toughness of the box connecting portion, and the water stop ring is arranged on the outer side face of the rubber block in a surrounding mode and used for preventing water leakage at the joint of the anti-collision floating box body and the rubber block from entering the anti-collision floating box body.
In a specific embodiment, an armor coating is arranged on the outer side surface of the anti-collision buoyancy tank, which is far away from the bridge pier; a rubber layer for corrosion resistance and wear resistance is arranged outside the connecting pin shaft; the anti-collision floating box further comprises a high polymer collision steering device arranged on the outer side face, far away from the pier, of the anti-collision floating box body, wherein the high polymer collision steering device comprises -shaped steel bars which are detachably arranged on the anti-collision floating box body and a high polymer collision cylinder which is sleeved on the -shaped steel bars.
In a specific embodiment, the internal energy consumption device comprises a steel grid and a steel pipe network, wherein the steel grid is composed of steel plates, the steel plates are arranged in a triangular prism shape, the steel pipes in the steel pipe network are arranged vertically or in parallel, and nodes connected with the steel pipes are distributed in a lattice mode.
In a specific embodiment, the internal energy dissipation device comprises a steel grid and a round steel cylinder, wherein the steel grid is composed of steel plates, the steel plates are distributed in a triangular prism shape, and the round steel cylinder is arranged in a vertical direction.
In a specific embodiment, the high molecular damping energy dissipation material is polyurethane foam.
In a specific embodiment, the outer side face, close to the pier, of the anti-collision floating box body is further provided with a high-molecular damping element, the high-molecular damping element is a rubber block with a built-in steel wire mesh, the high-molecular damping element is provided with a countersunk through hole, and the high-molecular damping element is detachably arranged on the outer side face, close to the pier, of the anti-collision floating box body through the countersunk through hole by bolts.
In a specific embodiment, the top of the anti-collision floating box body is provided with an access hole, and a detachable access cover is arranged at the access hole.
In a specific embodiment, the concrete adopted by the anti-collision buoyancy tank body is ultra-high performance concrete, the ultra-high performance concrete comprises cement, silica fume, fly ash, quartz powder, quartz sand, nano mineral powder, polycarboxylic acid high efficiency water reducer, water and steel fiber, and the nano mineral powder comprises nano SiO 2 And nano CaCO 3 The ultra-high performance concrete has compressive strength of 120 MPa-200 MPa and material breaking energy of 20-40 kJ/m 2 The diffusion rate of chloride ions is 0.02X10 -12 m 2 /s~0.03×10 -12 m 2 And/s and the water absorption porosity is 1 to 1.5 percent.
In a specific embodiment, the assembled anti-collision facility for the water area pier comprises four anti-collision floating boxes, wherein the four anti-collision floating boxes are sequentially connected to form an ellipse, two anti-collision floating box bodies are in a cuboid shape, and the other two anti-collision floating box bodies are in a semicircular shape.
Compared with the prior art, the invention has the following beneficial effects:
the invention eliminates the hidden trouble of collision of the ship with the bridge to a certain extent, makes up the defect of shorter service life or larger damage to the ship of the existing anti-collision facility, combines the latest achievements of material research and anti-collision mechanism research, and realizes overall protection of the safety of the bridge and the ship.
The design of the wave discharging holes adopted by the invention avoids the transitional vibration of the whole anti-collision facility, so that the anti-collision facility has good stress performance under the action of waves. The service life of the structure is prolonged by the aid of the connecting mode of the assembled structure, the assembled structure is convenient to replace, and the construction period of the site is shortened.
The concrete with specific standard is selected, so that the concrete has excellent mechanical property and durability, and the compressive strength of the concrete is very similar to the steel strength of an anti-collision steel sleeve box; the material fracture energy has very good impact resistance; the chloride ion diffusion rate is low and is 2% of that of common concrete, and the concrete has very excellent durability. The anti-collision buoyancy tank body formed by the concrete has good shock resistance and durability.
The energy consumption mode of the invention is to form a collision system by the ship, the bridge pier and the invention. The invention absorbs the impact energy by changing the direction of the impact force and plastic deformation and breakage, so that the impact kinetic energy is dissipated, or the impact energy of the ship is reduced, the ship cannot directly impact the bridge pier, the impact energy transferred to the bridge pier by the ship is limited or reduced, the impact force of the ship is controlled within a safe range, and the safety of the bridge pier is ensured.
In addition to the objects, features and advantages described above, the present invention has other objects, features and advantages. The present invention will be described in further detail with reference to the drawings.
Drawings
The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this specification, illustrate embodiments of the invention and together with the description serve to explain the invention. In the drawings:
FIG. 1 is a top view of one embodiment of the present invention;
FIG. 2 is a partial schematic view of a wave dissipating through hole according to one embodiment of the present invention;
FIG. 3 is a schematic top view cross-section of one embodiment of the present invention;
FIG. 4 is a schematic diagram of an internal energy consuming device according to one embodiment of the present invention;
FIG. 5 is a schematic cross-sectional top view of another embodiment of the present invention;
FIG. 6 is a schematic diagram of an internal energy consuming device according to another embodiment of the present invention;
FIG. 7 is a perspective view of a tank attachment portion according to one embodiment of the present invention;
fig. 8 is a perspective view of a polymeric damping element according to one embodiment of the present invention.
1, an anti-collision buoyancy tank; 2. a connecting pin shaft; 3. wave discharging through holes; 11. an anti-collision buoyancy tank body; 12. a box body connecting part; 14. an internal energy consumption device; 15. a polymer damping element; 16. a high molecular collision steering device; 111. an access cover; 121. a rubber block; 122. embedding a steel plate; 123. and a water stop ring.
Detailed Description
Embodiments of the invention are described in detail below with reference to the attached drawings, but the invention can be implemented in a number of different ways, which are defined and covered by the claims.
Example 1
The invention relates to an assembled anti-collision facility for water area piers, which comprises a plurality of anti-collision floating boxes 1 which are sequentially connected around the piers, wherein each anti-collision floating box 1 comprises an anti-collision floating box body 11 and a box body connecting part 12, each anti-collision floating box body 11 is of an ultra-high performance concrete reinforced structure, two box body connecting parts 12 which are distributed up and down are arranged at two connecting ends of each anti-collision floating box body 11,
an internal energy consumption device 14 for absorbing and consuming the impact energy of the anti-collision floating box body when the anti-collision floating box body is impacted is arranged in the anti-collision floating box 1;
the inside clearance packing of anticollision flotation tank is provided with polymer damping energy consumption material, and when crashproof flotation tank box 11 was damaged, the buoyancy that the inside polymer damping energy consumption material of packing of anticollision flotation tank box 11 received in water was greater than the gravity of whole anticollision flotation tank 1. The connecting pin shaft 2 is also provided with a cotter pin for locking the pin shaft.
In a specific embodiment, the box connecting portion 12 includes an upper box connecting portion disposed at the upper portions of two connecting ends of the anti-collision floating box 11 and a lower box connecting portion disposed at the lower portions of two connecting ends of the anti-collision floating box 11, the box connecting portion 12 is plate-shaped and is provided with a pin hole, a connecting pin shaft 2 is further disposed between two adjacent anti-collision floating boxes 1, two upper box connecting portions of the adjacent anti-collision floating boxes 1 are staggered and connected through the connecting pin shaft 2, two lower box connecting portions of the adjacent anti-collision floating boxes are staggered and connected through the connecting pin shaft 2, and two adjacent anti-collision floating box 11, the upper box connecting portion and the lower box connecting portion together enclose a wave unloading through hole 3 which is transversely communicated with the inner side and the outer side of the assembled anti-collision facility;
the box body connecting portion 12 comprises a water stop ring 123, an embedded steel plate 122 and a rubber block 121, wherein the embedded steel plate 122 is arranged in the rubber block 121 and used for enhancing the rigidity and toughness of the box body connecting portion 12, and the water stop ring 123 is arranged on the outer side surface of the rubber block 121 in a surrounding mode and used for preventing water leakage at the joint of the anti-collision floating box body 11 and the rubber block 121 from being poured into the anti-collision floating box body 11.
The box body connecting portion 12 is a bracket. The design of the wave unloading through hole weakens the impact force of water flow, avoids the whole transitional vibration of the assembled anti-collision facility, and ensures that the assembled anti-collision facility has good stress performance under the wave action. The assembled structure connection mode avoids abrasion between the box body connection part and the anti-collision floating box body under the wave action, and prolongs the service life of the assembled anti-collision facility. Before the anti-collision floating box body 11 is manufactured and poured, a part of the rubber block is embedded into the anti-collision floating box body 11, and then the anti-collision floating box body 11 is integrally poured and formed, so that the connection firmness of the rubber block and the anti-collision floating box body 11 can be ensured.
In a specific embodiment, an armor coating is arranged on the outer side surface of the anti-collision buoyancy tank 1 away from the bridge pier; a rubber layer for corrosion resistance and wear resistance is arranged outside the connecting pin shaft 2; armor coatings for spray coating armor coatings are commercially available. The armor coating improves the impact resistance, abrasion resistance, corrosion resistance and other performances of the impact face of the assembled anti-collision facility, has small surface friction force and is easy to collide and turn.
The anti-collision buoyancy tank 1 further comprises a high polymer collision steering device 16 arranged on the outer side face, far away from the pier, of the anti-collision buoyancy tank body 11, and the high polymer collision steering device 16 comprises -shaped steel bars which are detachably arranged on the anti-collision buoyancy tank body 11 and a high polymer collision cylinder which is sleeved on the -shaped steel bars. The macromolecular collision steering device has two layers in total, and the macromolecular collision steering device has the function of being beneficial to changing the heading of the ship after the ship is hit. The course changes after the ship is impacted, so that a part of kinetic energy of the ship can be reserved on the ship, the energy loading in the impact process is reduced, the impact energy born by the bridge is reduced, and the bridge and the ship are protected.
In a specific embodiment, the internal energy dissipation device 14 includes a steel grid and a steel pipe network, the steel grid is composed of steel plates, the steel plates are arranged in a triangular prism shape, the steel pipes in the steel pipe network are arranged vertically or in parallel, and the nodes where the steel pipes are connected are arranged in a lattice. The internal consumer 14, including the steel grid and steel pipe network, is suitable for use in situations where the impact forces are small.
In a specific embodiment, the internal energy dissipating device 14 includes a steel grid and a circular steel cylinder, the steel grid is composed of steel plates, the steel plates are arranged in a triangular prism shape, and the circular steel cylinder is arranged in a vertical direction. The round steel cylinder can be provided with different diameters according to the requirement. The internal consumer 14, comprising a steel grid and a circular steel cylinder, is suitable for use in situations where the impact forces are high.
In a specific embodiment, the high molecular damping energy dissipation material is polyurethane foam. Polyurethane foam is commercially available.
In a specific embodiment, the outer side surface of the anti-collision floating box body 11, which is close to the pier, is further provided with a polymer damping element 15, the polymer damping element 15 is a rubber block with a built-in steel wire mesh, the polymer damping element 15 is provided with a countersunk through hole, and the polymer damping element 15 is detachably arranged on the outer side surface of the anti-collision floating box body 11, which is close to the pier, through the countersunk through hole by a bolt. The high polymer damping element 15 can slow down the impact force through the elastic deformation, prolongs the impact force time course and reduces the acting force peak value on the bridge pier.
In a specific embodiment, the top of the anti-collision buoyancy tank 11 is provided with a manhole, and a detachable access cover 111 is provided at the manhole.
In one placeIn a specific embodiment, the concrete adopted by the anti-collision buoyancy tank 11 is ultra-high performance concrete, the ultra-high performance concrete comprises cement, silica fume, fly ash, quartz powder, quartz sand, nano mineral powder, polycarboxylic acid high efficiency water reducer, water and steel fiber, and the nano mineral powder comprises nano SiO 2 And nano CaCO 3 The ultra-high performance concrete has compressive strength of 120 MPa-200 MPa and material breaking energy of 20-40 kJ/m 2 The diffusion rate of chloride ions is 0.02X10 -12 m 2 /s~0.03×10 -12 m 2 And/s and the water absorption porosity is 1 to 1.5 percent. Ultra-high performance concrete is commercially available.
In a specific embodiment, the fabricated anti-collision facility for the water area pier comprises four anti-collision floating boxes 1, wherein the four anti-collision floating boxes 1 are sequentially connected to form an ellipse, two anti-collision floating box bodies 11 are in a cuboid shape, and the other two anti-collision floating box bodies 11 are in a semicircular shape.
When the ship collides with the anti-collision device, under the condition that the ship speed is low, when the ship contacts with the high polymer collision steering device 16, the ship can be guided to steer, so that most of kinetic energy of the ship is reserved on the ship, the energy conversion in the collision process is reduced, the collision energy born by the bridge is reduced, and the bridge and the ship are protected. Under the condition of higher ship speed, the high polymer collision steering device 16 and the armored paint on the surface of the buoyancy tank body also play a role in buffering and guiding, then the ship collides with the ultra-high performance concrete material on the buoyancy tank surface, the material deforms or breaks and absorbs energy, when the ship collision force reaches the inside of the buoyancy tank body, the internal energy dissipation device 14 of the ship can plastically deform and consume the collision energy, and meanwhile, the polyurethane foam high polymer material in the internal energy dissipation device 14 also can compress and deform and consume energy. The buoyancy tank body is buffered by the high polymer damping element 15 and contacted with the bridge pier, and finally the impact force reaching the bridge pier is insufficient to damage the bridge pier, and meanwhile, the reaction force suffered by the ship is consumed mostly by the energy consumption device in the buoyancy tank body, so that the semi-rigid and semi-flexible anti-collision device can protect the safety of the bridge pier and the ship under the action of the energy consumption system.
The internal energy dissipation device 14 of the box is one of the most important energy dissipation elements, and mainly plays a role in diffusing impact force and reducing local node damage.
The wave unloading through hole design between two anti-collision floating box bodies can weaken the fluid impact force born by the assembly type anti-collision facility for the water area bridge pier to a certain extent, meanwhile, the contact area of the side wall of the anti-collision floating box body is reduced, the transmission of the impact energy between the anti-collision floating box bodies is also greatly weakened, and the effect of blocking the expansion of the damage area is achieved. Because the connecting pin shaft 2 at the connecting part of the box body connecting part 12 is movable, the anti-collision floating box body and the box body are mutually movable, so that when sea waves or foreign matters strike the anti-collision floating box body, the anti-collision floating box body and the box body can mutually move to carry out torsion energy consumption.
When the impact force of the ship is small, the high polymer collision steering device 16 is easy to deflect the ship, the anti-collision buoyancy tank body of the internal energy consumption device 14 releases the impact capability through structural deformation, and the ship is easy to deflect due to small friction force of the armor coating.
When the impact force of the ship is large, the anti-collision buoyancy tank body with the built-in internal energy consumption device 14 can release the impact energy of the ship through the deformation and damage of the structure, so that the impact force peak value is reduced, and the bridge pier and the ship are protected from damage. Even if the anti-collision floating box body is impacted and damaged, water flows into the anti-collision floating box body, the built-in polyurethane foam rubber can exert the floating force to prevent the anti-collision floating box body from sinking into water.
The invention releases energy through the deformation and damage of the anti-collision buoyancy tank body, the deformation of the high polymer collision steering device and the high polymer damping element, and the like, thereby protecting the bridge pier and the ship from being damaged.
The invention has better structural reliability. The invention adopts the ultra-high performance concrete as the main material, and has outstanding innovation. The ultra-high performance concrete has high impact toughness, high impermeability and excellent durability, and can absorb the impact capacity of the ship part through deformation and damage of the ultra-high performance concrete structure, reduce the impact peak value and have high energy absorption capacity. Meanwhile, the invention adopts the armor coating to buffer the impact force, changes the course after the ship is impacted, and reduces the collision energy of the ship. The invention can effectively disperse impact load, protect bridges and ships, and take into account the interests of several related parties.
The invention has better environmental adaptability. The main body material ultra-high performance concrete of the anti-collision floating box body has excellent compactness, impermeability and durability, and has good waterproof capability and seawater corrosion resistance. The armor coating on the collision surface of the anti-collision buoyancy tank can also improve the seawater permeation resistance of the structure.
The invention has better construction feasibility and economy. Compared with inland, the invention has the advantages that the construction of the offshore bridge is more difficult, the invention adopts a modular structure and industrial manufacture, the ship can be quickly repaired after collision, the small collision is not damaged, the middle collision is well repaired, and the large collision is well replaced. The installation, transportation, maintenance and replacement are convenient, and the installation and construction are convenient.
The foregoing is a further detailed description of the invention in connection with specific preferred embodiments, and it is not to be construed that the invention is limited to the specific embodiments. It will be apparent to those skilled in the art that several simple deductions and substitutions can be made without departing from the spirit of the invention, and these are considered to be within the scope of the invention.