WO2021253824A1 - Bridge pier scour protection method combining concave normal surface of revolution and particle material - Google Patents
Bridge pier scour protection method combining concave normal surface of revolution and particle material Download PDFInfo
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- WO2021253824A1 WO2021253824A1 PCT/CN2021/072817 CN2021072817W WO2021253824A1 WO 2021253824 A1 WO2021253824 A1 WO 2021253824A1 CN 2021072817 W CN2021072817 W CN 2021072817W WO 2021253824 A1 WO2021253824 A1 WO 2021253824A1
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- pier
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- 239000002245 particle Substances 0.000 title claims abstract description 28
- 238000000034 method Methods 0.000 title claims abstract description 18
- 239000000463 material Substances 0.000 title abstract 5
- XLYOFNOQVPJJNP-UHFFFAOYSA-N water Substances O XLYOFNOQVPJJNP-UHFFFAOYSA-N 0.000 claims abstract description 32
- 238000009991 scouring Methods 0.000 claims description 29
- 230000003628 erosive effect Effects 0.000 claims description 11
- 230000005484 gravity Effects 0.000 claims description 8
- 239000013049 sediment Substances 0.000 claims description 5
- 230000037396 body weight Effects 0.000 claims description 2
- 230000001681 protective effect Effects 0.000 abstract description 11
- 238000010276 construction Methods 0.000 abstract description 2
- 230000007423 decrease Effects 0.000 abstract description 2
- 230000007123 defense Effects 0.000 abstract 1
- 230000003313 weakening effect Effects 0.000 abstract 1
- 230000000694 effects Effects 0.000 description 8
- 239000008187 granular material Substances 0.000 description 4
- 238000005299 abrasion Methods 0.000 description 1
- 230000001133 acceleration Effects 0.000 description 1
- 230000009286 beneficial effect Effects 0.000 description 1
- 230000000903 blocking effect Effects 0.000 description 1
- 238000004364 calculation method Methods 0.000 description 1
- 230000008021 deposition Effects 0.000 description 1
- 238000010586 diagram Methods 0.000 description 1
- 238000012423 maintenance Methods 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 238000005381 potential energy Methods 0.000 description 1
- 239000011435 rock Substances 0.000 description 1
- 239000004576 sand Substances 0.000 description 1
- 238000006467 substitution reaction Methods 0.000 description 1
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Classifications
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- E—FIXED CONSTRUCTIONS
- E01—CONSTRUCTION OF ROADS, RAILWAYS, OR BRIDGES
- E01D—CONSTRUCTION OF BRIDGES, ELEVATED ROADWAYS OR VIADUCTS; ASSEMBLY OF BRIDGES
- E01D19/00—Structural or constructional details of bridges
- E01D19/02—Piers; Abutments ; Protecting same against drifting ice
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- E—FIXED CONSTRUCTIONS
- E02—HYDRAULIC ENGINEERING; FOUNDATIONS; SOIL SHIFTING
- E02B—HYDRAULIC ENGINEERING
- E02B3/00—Engineering works in connection with control or use of streams, rivers, coasts, or other marine sites; Sealings or joints for engineering works in general
- E02B3/20—Equipment for shipping on coasts, in harbours or on other fixed marine structures, e.g. bollards
- E02B3/26—Fenders
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A30/00—Adapting or protecting infrastructure or their operation
- Y02A30/30—Adapting or protecting infrastructure or their operation in transportation, e.g. on roads, waterways or railways
Definitions
- the invention belongs to the field of partial scour protection of bridge foundations, and in particular relates to a bridge pier scour protection method combining a concave rotating normal curved surface and a bulk body.
- the local scour protection measures of bridge piers are mainly divided into two categories: (1) Active protection. To reduce the scouring energy of the water flow on the piers, that is, to weaken the downflow and the horseshoe vortex flow in the scouring process of the water flow. Measures such as enlarging the foundation plane of the piers or setting foot guards are usually adopted to reduce the scouring energy of the water flow. (2) Passive protection. To improve the anti-scouring ability of the bottom bed near the bridge pier, usually by throwing rocks or twisting the king block around the foundation of the bridge pier, in an attempt to improve the anti-scouring ability of the bridge pier.
- Ripple protection has always been the most widely used form of passive protection for large and medium-sized bridge piers. It has disadvantages such as enhanced eddy current, poor protection effect, large operation and maintenance costs and workload. Especially under the action of extreme hydrodynamic force, a strong vortex is formed around the riprap, which intensifies the erosion of the vortex on the bed surface. Not only does it fail to protect, it may even have the opposite effect.
- the present invention proposes a method for protecting bridge piers from erosion by combining a concave rotating normal surface with granular bodies.
- the specific technical solutions are as follows:
- a method for pier scour protection combined with a concave rotating normal surface and bulk particles is used to protect the foundation scour of bridge piers across the sea or river.
- the method is used to protect the foundation scour of bridge piers across the sea or river.
- the normal curved protection structure is a section of rotating normal curved shell with a thickness of a.
- the point of intersection between the center of the pier and the unwashed river bed plane is the origin, the water flow direction is the positive direction of the x-axis, and the horizontal plane is perpendicular to the The direction of the water flow is the y-axis, and the pier axis downward is the positive direction of the z-axis, then the inner surface of the normal curved shell is a curved surface that satisfies the following equation:
- x, y, z are the coordinates of the points on the inner surface of the normal curved shell
- l is the gap distance between the inner surface of the normal curved shell and the surface of the pier after the normal curved shell is sleeved on the pier
- ⁇ is the scouring pit
- h 0 is the distance from the upper part of the normal curved shell to the bed surface.
- the ratio ⁇ of the thickness ⁇ h of the granular body layer to the maximum depth h b of the scour pit satisfies the following conditions:
- G' is the equivalent gravity of the granular particles
- F w is the water flow force
- ⁇ is the friction coefficient of the scouring pit bed surface
- L is the length of the scouring pit
- Angle ⁇ w is the water density.
- the normal curved surface protection structure further includes a cylindrical sleeve-shaped base inserted into the river bed for fixing the normal curved shell, the thickness of which is the same as that of the normal curved shell, and the inner surface of the base meets the following requirements relation:
- a 0.1 to 0.3 m
- h c 1 to 2 m.
- the particle size d of the granular particles is 3 to 5 times the initial particle size of the sediment under the extreme velocity of the local natural conditions.
- the protection system of the present invention organically combines the normal curved surface structure in the scour pit to resist downwashing water flow with the weakened horseshoe-shaped vortex of the granular body layer.
- the normal curved surface structure is mainly used to resist the downwashing current in front of the pier, and the granular body layer can reduce the bridge pier.
- the protection system can reduce the energy of downwashing and horseshoe vortex around the pier during the use of the bridge, reduce local scour, and effectively protect the foundation of the pier.
- Figure 1 is a diagram of the force on the granular body on the slope
- Figure 2 is a side view of the local scour protection around the bridge pier combined with a concave normal curved surface and granular body.
- Figure 3 is a top view of the local scour protection around the bridge pier combined with the concave rotating normal surface and the granular body.
- the force of the granular body in the pier scour pit can be simplified as: gravity, bed resistance, buoyancy, and water flow.
- A is the waterfront area:
- C D is the thrust coefficient
- the length of the scour pits before and after the pier is basically the same, and the angle between the slopes of the scour pits of the front and rear ends and the horizontal direction is also roughly the same, as shown in Figure 2, which is the invention
- the pier scour protection device combined with the concave rotating normal curved surface protection structure and the granular body.
- the concave rotating normal curved surface protection structure is laid and the rotating normal surface is rotated.
- a specific thickness of granular material is laid inside the surface protection structure.
- the rotating normal curved surface protection structure is a section of rotating normal curved shell with a thickness of a. The following specifically introduces the shape of the pier scour protection device.
- x, y, z are the coordinates of the points on the inner surface of the normal curved shell
- l is the gap distance between the inner surface of the normal curved shell and the surface of the pier after the normal curved shell is sleeved on the pier
- ⁇ is the scouring pit
- h 0 is the distance from the upper part of the normal curved shell to the bed surface.
- the normal curved structure is sunk into the scouring pit. Due to its own weight, the structure will compact the silt in the pit and fix it on the surface of the scouring pit.
- the normal curved surface protection structure also includes a cylindrical sleeve-shaped base inserted in the river bed for fixing the normal curved shell, the thickness of which is the same as that of the normal curved shell, and the inner surface of the cylindrical sleeve-shaped base satisfies the following relationship:
- Figure 3 is a top view of the protective structure and granular bodies.
- the particle size d and thickness ⁇ h of the laid granular material are determined by the calculation method of the starting flow velocity of the granular material slope and the force analysis of the granular material on the normal curved surface to play the most effective protective effect.
- the particle size d and laying thickness ⁇ h of the granular body ensure that the granular body will not be moved out of the scouring pit, and on the other hand, it can avoid the abrasion of the structure by the granular body.
- G' is the equivalent gravity of the granular particles
- F w is the water flow force
- ⁇ is the friction coefficient of the scouring pit bed surface
- L is the length of the scouring pit
- Angle ⁇ w is the water density.
- the particle size of the granular particles used is 3 to 5 times the initial particle size of the sediment under the extreme flow velocity under local natural conditions (without bridge construction).
- the pier scour protection device with the combination of the concave normal curved surface and the granular body of the present invention is laid in the local scour pit around the bridge pier, and uses the granular body gap to eliminate vortex and the movement of the granular body on the slope to consume the vortex energy to reduce the surrounding area of the bridge pier.
- the turbulence of the water flow and the strength of the horseshoe vortex reduce the erosion effect of the horseshoe vortex on the bridge pier and its protective structure.
- the gap between the granular bodies can reduce the wake vortex around the bridge piers and effectively absorb the horseshoe vortex energy; at the same time, the granular bodies will move diagonally away from the pier along the normal curved surface under the action of downwashing current, and then fall back under the action of gravity. Converting the kinetic energy of the water flow into the kinetic energy and potential energy of the granular body can further consume the energy of the downwash and the horseshoe vortex.
- the weight of the granular layer increases, and the normal curved surface structure compacts the sediment below it, which helps to maintain the stability of the protective structure.
- the corresponding curved structures and granular bodies can be designed with reference to the protection method provided by the present invention.
- the present invention has a guiding effect on the erosion protection of the foundation of wading buildings.
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- General Engineering & Computer Science (AREA)
- Ocean & Marine Engineering (AREA)
- Civil Engineering (AREA)
- Structural Engineering (AREA)
- Environmental & Geological Engineering (AREA)
- Mechanical Engineering (AREA)
- Architecture (AREA)
- Bridges Or Land Bridges (AREA)
Abstract
A bridge pier scour protection method combining a concave normal surface of revolution and a particle material. The method is used for protection against pier foundation scour in a sea-crossing or river-crossing beam bridge. When a scour pit in the local region surrounding the bottom of a bridge pier or a bridge column reaches a set depth, a concave normal surface-of-revolution protective structure is laid out, and a particle material of a specific thickness is laid out in the interior of the concave normal surface-of-revolution protective structure. The present protection method organically combines the defense against underscour water flow by a normal surface structure in a scour pit with the weakening of horseshoe vortexes by a particle material layer. The normal surface structure is mainly used to defend against underscour water flow in front of a pier, and the particle material layer is able to weaken horseshoe vortexes around the pier. During bridge use, the present protection system is able to decrease underscour flow and the energy of horseshoe vortexes around bridge piers and reduce local scour, thus having an effective protective effect on bridge pier foundations and being effective for protecting the foundations of partially-submerged constructions.
Description
本发明属于桥梁基础局部冲刷防护领域,具体涉及一种下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法。The invention belongs to the field of partial scour protection of bridge foundations, and in particular relates to a bridge pier scour protection method combining a concave rotating normal curved surface and a bulk body.
跨海(河)桥梁桥墩周围局部冲刷对于桥梁基础安全影响极大,是导致桥梁破坏的主要原因。桥墩周围局部冲刷导致的桥梁倒塌占总数的一半以上。所以,对桥墩局部冲刷进行有效和充分的防护十分重要。The local scour around the piers of cross-sea (river) bridges has a great impact on the safety of the bridge foundation and is the main cause of bridge damage. Bridge collapses caused by local scour around the piers accounted for more than half of the total. Therefore, it is very important to effectively and adequately protect the local scour of the bridge piers.
水流对桥墩的局部冲刷有三方面原因:(1)桥墩阻水导致周围流速增大,指水流遇到障碍物时过水断面面积减小,引起局部流速增大,床面泥沙冲刷而形成冲刷坑;(2)下冲水流掏蚀床面,主要指前进水流撞击桥墩后形成下冲水流,对床面产生强烈的掏蚀作用;(3)马蹄形漩涡冲刷,主要指水流绕过障碍物时形成的马蹄形漩涡,卷走了墩周的部分泥沙。There are three reasons for the local scour of the bridge piers by water flow: (1) The blocking of the bridge piers causes the surrounding flow velocity to increase, which means that when the flow encounters obstacles, the cross-sectional area of the water passing through decreases, causing the local flow velocity to increase, and the bed surface is scoured by sediment. Pit; (2) Downflushing water flow erodes the bed surface, mainly refers to the forward flow of water hitting the bridge piers to form a downwashing water flow, which produces a strong erosion effect on the bed surface; (3) Horseshoe vortex scouring, mainly refers to when the water flow bypasses obstacles The formed horseshoe-shaped vortex swept away part of the sand around the pier.
桥墩的局部冲刷防护措施主要分为两类:(1)主动防护。减小水流对桥墩的冲刷能量,即减弱水流冲刷过程中的下冲流和马蹄形漩涡流,通常采用扩大桥墩的基础平面或设护脚等措施以减小水流的冲刷能量。(2)被动防护。提高桥墩附近底床的防冲刷能力,通常是在桥墩基础周围抛石或扭王字块,试图提高桥墩的抗冲能力。The local scour protection measures of bridge piers are mainly divided into two categories: (1) Active protection. To reduce the scouring energy of the water flow on the piers, that is, to weaken the downflow and the horseshoe vortex flow in the scouring process of the water flow. Measures such as enlarging the foundation plane of the piers or setting foot guards are usually adopted to reduce the scouring energy of the water flow. (2) Passive protection. To improve the anti-scouring ability of the bottom bed near the bridge pier, usually by throwing rocks or twisting the king block around the foundation of the bridge pier, in an attempt to improve the anti-scouring ability of the bridge pier.
现有防护措施存在成本高、防护效果差和不能有效抵御台风暴潮等灾害性海洋环境等不足。利用扩大桥墩基础顶面的主动防护措施在通常水流下能抵御下冲水流,然而在极端水动力环境下床面冲刷严重而下降,致使桥墩基础完全暴露于床面之上,从而在桥墩基础迎流面上形成更强的下冲水流,导致局部冲刷更为严重。桥墩墩体开缝能起到削弱马蹄形漩涡强度的作用,开缝多则降低桥墩强度,开缝少则效果差,开缝还可能被漂浮物等堵塞。因旋转流或主流摆动等造成桥墩行近水流方向与开缝方向不一致时,开缝就失去防护作用。Existing protection measures have disadvantages such as high cost, poor protection effect, and inability to effectively resist typhoon storm surges and other disastrous marine environments. The active protection measures that expand the top surface of the pier foundation can resist the downwashing flow under normal currents. However, under extreme hydrodynamic environments, the bed surface is severely scoured and descends, causing the pier foundation to be completely exposed on the bed surface, thus facing the bridge pier foundation. A stronger downwash is formed on the stream surface, which leads to more serious local scour. The opening of the pier body can weaken the strength of the horseshoe-shaped vortex. If there are more openings, the strength of the pier will be lowered. If there are few openings, the effect will be poor. The openings may also be blocked by floating objects. When the flow direction of the bridge pier is inconsistent with the direction of the opening due to rotating flow or mainstream swing, the opening of the seam will lose its protective effect.
抛石防护一直是大、中型桥梁桥墩最广泛采用的被动防护形式,具有涡流增强、防护效果差、运维费用和工作量较大等缺点。特别是当极端水动力作用下,抛石周围形成强烈的涡漩,加剧了涡漩对床面的掏蚀作用。不仅起不到防护作用,甚至可能起到相反的作用。Ripple protection has always been the most widely used form of passive protection for large and medium-sized bridge piers. It has disadvantages such as enhanced eddy current, poor protection effect, large operation and maintenance costs and workload. Especially under the action of extreme hydrodynamic force, a strong vortex is formed around the riprap, which intensifies the erosion of the vortex on the bed surface. Not only does it fail to protect, it may even have the opposite effect.
发明内容Summary of the invention
针对现有技术的不足,本发明提出一种下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,具体技术方案如下:In view of the shortcomings of the prior art, the present invention proposes a method for protecting bridge piers from erosion by combining a concave rotating normal surface with granular bodies. The specific technical solutions are as follows:
一种下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,该方法用于跨海或跨河桥梁桥墩基础冲刷的防护,当桥墩或桥桩底部周围局部冲刷坑达到设定深度后,铺设下凹的旋转正态曲面防护结构,并在旋转正态曲面防护结构内部铺设特定厚度的散粒体。A method for pier scour protection combined with a concave rotating normal surface and bulk particles. The method is used to protect the foundation scour of bridge piers across the sea or river. When the local scour pits around the bottom of the pier or bridge pile reach a set depth , Lay a concave rotating normal surface protection structure, and pave a specific thickness of granular body inside the rotating normal surface protection structure.
进一步地,所述正态曲面防护结构为厚度为a的一段旋转正态曲面壳体,以桥墩的中心与未冲刷的河床平面的交点为原点,水流方向为x轴正方向、水平面内垂直于水流方向的为y轴、桥墩轴线向下为z轴正方向,则所述正态曲面壳体的内表面为满足如下方程的曲面:Further, the normal curved protection structure is a section of rotating normal curved shell with a thickness of a. The point of intersection between the center of the pier and the unwashed river bed plane is the origin, the water flow direction is the positive direction of the x-axis, and the horizontal plane is perpendicular to the The direction of the water flow is the y-axis, and the pier axis downward is the positive direction of the z-axis, then the inner surface of the normal curved shell is a curved surface that satisfies the following equation:
其中,x,y,z为正态曲面壳体内表面点的坐标,l为所述正态曲面外壳套设在桥墩后正态曲面外壳的内表面距离桥墩表面的间隙距离;σ为与冲刷坑范围相关的方差值,h
0为正态曲面壳体上部到床面的距离。正态曲面底部位于床面以下mh
b处,h
b为最大冲刷坑深度,m=0.7~0.9。
Among them, x, y, z are the coordinates of the points on the inner surface of the normal curved shell, and l is the gap distance between the inner surface of the normal curved shell and the surface of the pier after the normal curved shell is sleeved on the pier; σ is the scouring pit The range-related variance value, h 0 is the distance from the upper part of the normal curved shell to the bed surface. The bottom of the normal curved surface is located at mh b below the bed surface, where h b is the depth of the maximum erosion pit, m=0.7~0.9.
进一步地,所述散粒体层厚度Δh与冲刷坑最大深度h
b的比值λ满足如下条件:
Further, the ratio λ of the thickness Δh of the granular body layer to the maximum depth h b of the scour pit satisfies the following conditions:
其中,G‘为散粒体颗粒等效重力;F
w为水流力;μ为冲刷坑床面的摩擦系数;L为冲刷坑长度;α,β为冲刷坑前后两部分坡面与水平面的夹角,ρ
w为水密度。
Among them, G'is the equivalent gravity of the granular particles; F w is the water flow force; μ is the friction coefficient of the scouring pit bed surface; L is the length of the scouring pit; Angle, ρ w is the water density.
进一步地,所述正态曲面防护结构还包括插入河床中用于固定所述正态曲面壳体的圆柱套筒形底座,其厚度与正态曲面壳体厚度相同,该底座的内表面满足如下关系:Further, the normal curved surface protection structure further includes a cylindrical sleeve-shaped base inserted into the river bed for fixing the normal curved shell, the thickness of which is the same as that of the normal curved shell, and the inner surface of the base meets the following requirements relation:
进一步地,a=0.1~0.3m,h
c=1~2m。
Further, a = 0.1 to 0.3 m, and h c = 1 to 2 m.
进一步地,散粒体粒径d为当地自然条件下极端流速作用时泥沙起动粒径的3~5倍。Furthermore, the particle size d of the granular particles is 3 to 5 times the initial particle size of the sediment under the extreme velocity of the local natural conditions.
本发明的有益效果如下:The beneficial effects of the present invention are as follows:
桥墩周围局部冲刷的主因为下冲水流和马蹄形漩涡。本发明的防护体系将冲刷坑内的正态曲面结构抵御下冲水流与散粒体层削弱马蹄形漩涡有机结合起来,正态曲面结构主要用于抵御墩前下冲水流,散粒体层可以消减桥墩周围的马蹄涡。该防护体系能在大桥使用期间,消减桥墩周围下冲水流和马蹄涡能量,减小局部冲刷,对桥墩基础起到有效保护作用。The main cause of local scouring around the bridge piers is the downwash and the horseshoe vortex. The protection system of the present invention organically combines the normal curved surface structure in the scour pit to resist downwashing water flow with the weakened horseshoe-shaped vortex of the granular body layer. The normal curved surface structure is mainly used to resist the downwashing current in front of the pier, and the granular body layer can reduce the bridge pier. Horseshoe vortex around. The protection system can reduce the energy of downwashing and horseshoe vortex around the pier during the use of the bridge, reduce local scour, and effectively protect the foundation of the pier.
图1为斜坡上散粒体受力情况图;Figure 1 is a diagram of the force on the granular body on the slope;
图2为下凹型正态曲面和散粒体结合的桥墩周围局部冲刷防护侧面图。Figure 2 is a side view of the local scour protection around the bridge pier combined with a concave normal curved surface and granular body.
图3为下凹型旋转正态曲面和散粒体结合的桥墩周围局部冲刷防护俯视图。Figure 3 is a top view of the local scour protection around the bridge pier combined with the concave rotating normal surface and the granular body.
下面根据附图和优选实施例详细描述本发明,本发明的目的和效果将变得更加明白,应当理解,此处所描述的具体实施例仅仅用以解释本发明,并不用于限定本发明。The following describes the present invention in detail based on the accompanying drawings and preferred embodiments. The purpose and effects of the present invention will become more apparent. It should be understood that the specific embodiments described here are only used to explain the present invention and are not intended to limit the present invention.
首先介绍桥墩冲刷坑中的散粒体的受力情况。如图1所示,散粒体颗粒在冲刷坑表面受力可简化为:重力、床面阻力、浮力、水流力。First, introduce the force of the granular body in the pier scour pit. As shown in Figure 1, the force of the granular particles on the surface of the scouring pit can be simplified as: gravity, bed resistance, buoyancy, and water flow.
有效重力:G'=G-F
T
Effective gravity: G'=GF T
河床阻力:f
1-颗粒在冲刷坑底部受到的摩擦力
River bed resistance: f 1 -the friction force that the particles receive at the bottom of the scour pit
f
2-颗粒在冲刷坑斜面受到的摩擦力
f 2 -The friction force of the particles on the slope of the scouring pit
d为散粒体直径;u为水流速度;ρ为散粒体密度;ρ
w为水密度;g为重力加速度,取9.8N/kg。
d is the diameter of the granular body; u is the water flow velocity; ρ is the density of the granular body; ρ w is the water density; g is the acceleration of gravity, which is taken as 9.8N/kg.
根据跨海大桥现场观测资料,在以潮汐主导的海峡河口环境中,桥墩前后冲刷坑长度基本相等,前后端冲刷坑斜面与水平方向夹角也大致相等,如图2所示,为本发明的下凹型旋转正态曲面防护结构与散粒体结合的桥墩冲刷防护装置,当桥墩或桥桩底部周围局部冲刷坑达到设定深度后,铺设下凹的旋转正态曲面防护结构,并在旋转正态曲面防护结构内部铺设特定厚度的散粒体。旋转正态曲面防护结构为厚度为a的一段旋转正态曲面壳体。下面具体对桥墩冲刷防护装置的形状进行介绍。According to the field observation data of the cross-sea bridge, in the strait and estuary environment dominated by tides, the length of the scour pits before and after the pier is basically the same, and the angle between the slopes of the scour pits of the front and rear ends and the horizontal direction is also roughly the same, as shown in Figure 2, which is the invention The pier scour protection device combined with the concave rotating normal curved surface protection structure and the granular body. When the local scour pit around the bottom of the pier or bridge pile reaches the set depth, the concave rotating normal curved surface protection structure is laid and the rotating normal surface is rotated. A specific thickness of granular material is laid inside the surface protection structure. The rotating normal curved surface protection structure is a section of rotating normal curved shell with a thickness of a. The following specifically introduces the shape of the pier scour protection device.
进一步地,所述正态曲面防护结构为厚度为a的一段旋转正态曲面壳体,正态曲面底部位于床面以下mh
b处,h
b为最大冲刷坑深度,m=0.7~0.9。以桥墩的中心与未冲刷的河床平面的交点为原点,水流方向为x轴正方向、水平面内垂直于水流方向的为y轴、桥墩轴线向下为z轴正方向,则所述正态曲面壳体的内表面为满足如下方程的曲面:
Further, the normal curved surface protection structure is a section of a rotating normal curved shell with a thickness of a, the bottom of the normal curved surface is located mh b below the bed surface, and h b is the maximum erosion pit depth, m=0.7-0.9. Taking the point of intersection between the center of the pier and the plane of the unwashed river bed as the origin, the direction of water flow is the positive direction of the x-axis, the horizontal plane perpendicular to the direction of the water flow is the y-axis, and the pier axis downward is the positive direction of the z-axis, then the normal surface The inner surface of the shell is a curved surface that satisfies the following equation:
其中,x,y,z为正态曲面壳体内表面点的坐标,l为所述正态曲面外壳套设在桥墩后正态曲面外壳的内表面距离桥墩表面的间隙距离;σ为与冲刷坑范围相关的方差值,h
0为正态曲面壳体上部到床面的距离。正态曲面底部位于床面以下mh
b处,h
b为最大冲刷坑深度,m=0.7~0.9。
Among them, x, y, z are the coordinates of the points on the inner surface of the normal curved shell, and l is the gap distance between the inner surface of the normal curved shell and the surface of the pier after the normal curved shell is sleeved on the pier; σ is the scouring pit The range-related variance value, h 0 is the distance from the upper part of the normal curved shell to the bed surface. The bottom of the normal curved surface is located at mh b below the bed surface, where h b is the depth of the maximum erosion pit, m=0.7~0.9.
在冲刷坑形成后,将此正态曲面结构沉至冲刷坑内,由于自重的作用,该结构会压实坑内泥沙从而固定在冲刷坑表面。After the scouring pit is formed, the normal curved structure is sunk into the scouring pit. Due to its own weight, the structure will compact the silt in the pit and fix it on the surface of the scouring pit.
进一步地,为了使该旋转正态曲面防护结构能够被牢固地固定,因此在旋转正态曲面防护结构下端继续设置一段圆柱套筒形底座,垂直向下插入沉积层中,从而将旋转正态曲面防护结构固定在冲刷坑底部的河床上。正态曲面防护结构还包括插入河床中用于固定所述正态曲面壳体的圆柱套筒形底座,其厚度与正态曲面壳体厚度相同,圆柱套筒形底座的内表面满足如下关系:Furthermore, in order to enable the rotating normal curved surface protection structure to be firmly fixed, a section of cylindrical sleeve-shaped base is continuously provided at the lower end of the rotating normal curved surface protection structure, and inserted vertically downward into the deposition layer, thereby rotating the normal curved surface The protective structure is fixed on the river bed at the bottom of the scour pit. The normal curved surface protection structure also includes a cylindrical sleeve-shaped base inserted in the river bed for fixing the normal curved shell, the thickness of which is the same as that of the normal curved shell, and the inner surface of the cylindrical sleeve-shaped base satisfies the following relationship:
当设置底座时,h
c即为旋转正态曲面防护结构插入河床底部的深度。进一步地,a=0.1~0.3m,h
c=1~2m。
When the base is set, h c is the depth at which the rotating normal curved protection structure is inserted into the bottom of the river bed. Further, a = 0.1 to 0.3 m, and h c = 1 to 2 m.
图3为该防护结构与散粒体俯视图。铺设散粒体的粒径d和厚度Δh由散粒体斜坡起动流速的计算方法,通过散粒体在正态曲面上的受力分析确定,以起到最有效的防护作用。散粒体粒径d和铺设厚度Δh一方面保证散粒体不会被外移出冲刷坑,另一方面避免散粒体对结构的磨蚀。该正态曲面结构与桥墩之间留有一定间隙,以避免对桥墩产生撞击力。因此,该散粒体层的厚度用以下方式确定:Figure 3 is a top view of the protective structure and granular bodies. The particle size d and thickness Δh of the laid granular material are determined by the calculation method of the starting flow velocity of the granular material slope and the force analysis of the granular material on the normal curved surface to play the most effective protective effect. On the one hand, the particle size d and laying thickness Δh of the granular body ensure that the granular body will not be moved out of the scouring pit, and on the other hand, it can avoid the abrasion of the structure by the granular body. There is a certain gap between the normal curved structure and the bridge pier to avoid impact force on the bridge pier. Therefore, the thickness of the granular body layer is determined in the following way:
若保证该颗粒不会被冲刷离开防护结构,则应满足:散粒体被冲至正态曲面防护结构边 缘前,速度就应降至零并回落回冲刷坑底部,即水流力和浮力做正功之和小于重力和表面阻力做负功之和。另外设原有最大冲刷深度为h
b,水流流速u,桥墩直径为D,μ为冲刷坑散粒体层表面的阻力系数。铺设散粒体层厚度为Δh=λh
b,粒径d,极端水动力条件下水流流速为u
2。即W
Fw+W
FT≤W
G+W
f
If it is ensured that the particles will not be washed away from the protective structure, it should be satisfied: before the granular particles are washed to the edge of the normal curved protective structure, the speed should be reduced to zero and fall back to the bottom of the scour pit, that is, the water flow and buoyancy are positive. The sum of work is less than the sum of negative work done by gravity and surface resistance. In addition, suppose the original maximum scouring depth is h b , the water flow velocity u, the bridge pier diameter is D, and μ is the resistance coefficient of the scouring pit granular layer surface. The thickness of the laid granular layer is Δh=λh b , the particle size is d, and the water flow velocity under extreme hydrodynamic conditions is u 2 . That is, W Fw + W FT ≤ W G + W f
整理,得:Organize, get:
其中,G‘为散粒体颗粒等效重力;F
w为水流力;μ为冲刷坑床面的摩擦系数;L为冲刷坑长度;α,β为冲刷坑前后两部分坡面与水平面的夹角,ρ
w为水密度。
Among them, G'is the equivalent gravity of the granular particles; F w is the water flow force; μ is the friction coefficient of the scouring pit bed surface; L is the length of the scouring pit; Angle, ρ w is the water density.
优选地,采用的散粒体粒径为当地自然条件下(未建桥)极端流速作用时泥沙起动粒径的3~5倍。Preferably, the particle size of the granular particles used is 3 to 5 times the initial particle size of the sediment under the extreme flow velocity under local natural conditions (without bridge construction).
本发明的下凹型正态曲面与散粒体结合的桥墩冲刷防护装置铺设在桥墩周围局部冲刷坑内,利用散粒体空隙消涡及散粒体在斜坡上运动消耗涡体能量,以削减桥墩周围水流紊动和马蹄涡的强度,降低马蹄涡对桥墩及其防护结构的冲蚀作用。散粒体之间的空隙可消减桥墩周围的尾流漩涡,有效地吸收马蹄涡能量;同时散粒体在下冲水流作用下会沿正态曲面离桥墩斜向运动,再在重力作用下回落,将水流的动能转化为散粒体的动能与势能,可进一步消耗下冲水流和马蹄涡的能量。散粒体层的重量增加正态曲面结构对其下泥沙的压实作用,有助于保持防护结构的稳定性。The pier scour protection device with the combination of the concave normal curved surface and the granular body of the present invention is laid in the local scour pit around the bridge pier, and uses the granular body gap to eliminate vortex and the movement of the granular body on the slope to consume the vortex energy to reduce the surrounding area of the bridge pier. The turbulence of the water flow and the strength of the horseshoe vortex reduce the erosion effect of the horseshoe vortex on the bridge pier and its protective structure. The gap between the granular bodies can reduce the wake vortex around the bridge piers and effectively absorb the horseshoe vortex energy; at the same time, the granular bodies will move diagonally away from the pier along the normal curved surface under the action of downwashing current, and then fall back under the action of gravity. Converting the kinetic energy of the water flow into the kinetic energy and potential energy of the granular body can further consume the energy of the downwash and the horseshoe vortex. The weight of the granular layer increases, and the normal curved surface structure compacts the sediment below it, which helps to maintain the stability of the protective structure.
对其他涉水建筑物,可参照本发明提供的防护方法设计相应的曲面结构和散粒体,本发明对涉水建筑物基础冲刷防护有指导作用。For other wading buildings, the corresponding curved structures and granular bodies can be designed with reference to the protection method provided by the present invention. The present invention has a guiding effect on the erosion protection of the foundation of wading buildings.
本领域普通技术人员可以理解,以上所述仅为发明的优选实例而已,并不用于限制发明,尽管参照前述实例对发明进行了详细的说明,对于本领域的技术人员来说,其依然可以对前述各实例记载的技术方案进行修改,或者对其中部分技术特征进行等同替换。凡在发明的精神和原则之内,所做的修改、等同替换等均应包含在发明的保护范围之内。Those of ordinary skill in the art can understand that the above descriptions are only preferred examples of the invention and are not intended to limit the invention. Although the invention has been described in detail with reference to the foregoing examples, for those skilled in the art, they can still The technical solutions recorded in the foregoing examples are modified, or some of the technical features are equivalently replaced. All modifications and equivalent substitutions made within the spirit and principle of the invention shall be included in the scope of protection of the invention.
Claims (6)
- 一种下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,该方法用于跨海或跨河桥梁桥墩基础冲刷的防护,当桥墩或桥桩底部周围局部冲刷坑达到设定深度后,铺设下凹的旋转正态曲面防护结构,并在旋转正态曲面防护结构内部铺设特定厚度的散粒体。正态曲面底部位于床面以下mh b处,h b为最大冲刷坑深度,m=0.7~0.9。 A method for scouring protection of bridge piers combined with a concave rotating normal surface and bulk particles is characterized in that the method is used for the protection of the scouring of the bridge pier foundations of cross-sea or river-crossing bridges. After setting the depth, lay a concave rotating normal surface protection structure, and pave a specific thickness of granular body inside the rotating normal surface protection structure. The bottom of the normal curved surface is located at mh b below the bed surface, where h b is the depth of the maximum erosion pit, m=0.7~0.9.
- 根据权利要求1所述的下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,所述正态曲面防护结构为厚度为a的一段旋转正态曲面壳体,以桥墩的中心与未冲刷的河床平面的交点为原点,水流方向为x轴正方向、水平面内垂直于水流方向的为y轴、桥墩轴线向下为z轴正方向,则所述正态曲面壳体的内表面为满足如下方程的曲面:The pier scour protection method combined with a concave rotating normal curved surface and granular body according to claim 1, wherein the normal curved surface protection structure is a section of rotating normal curved shell with a thickness of a. The point of intersection between the center of and the unwashed river bed plane is the origin, the direction of the water flow is the positive x-axis direction, the horizontal plane perpendicular to the direction of the water flow is the y-axis, and the axis of the bridge pier downwards is the positive z-axis direction, then the normal curved shell The inner surface of is a curved surface that satisfies the following equation:其中,x,y,z为正态曲面壳体内表面点的坐标,l为所述正态曲面外壳套设在桥墩后正态曲面外壳的内表面距离桥墩表面的间隙距离;σ为与冲刷坑范围相关的方差值,h 0为正态曲面壳体上部到床面的距离。 Among them, x, y, z are the coordinates of the points on the inner surface of the normal curved shell, and l is the gap distance between the inner surface of the normal curved shell and the surface of the pier after the normal curved shell is sleeved on the pier; σ is the scouring pit The range-related variance value, h 0 is the distance from the upper part of the normal curved shell to the bed surface.
- 根据权利要求2所述的下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,所述散粒体层厚度Δh与冲刷坑最大深度h b的比值λ满足如下条件: The method for protecting bridge piers against erosion by combining a concave rotating normal surface with granular bodies according to claim 2, wherein the ratio λ of the thickness of the granular body layer Δh to the maximum depth of the scouring pit h b satisfies the following conditions:散粒体颗粒有效重力:G'=G-F T Effective gravity of granular particles: G'=GF T其中,F w为水流力;μ为冲刷坑床面的摩擦系数;L为冲刷坑长度;α,β为冲刷坑前后两部分坡面与水平面的夹角,ρ w为水密度。 Among them, F w is the water flow force; μ is the friction coefficient of the scouring pit bed surface; L is the length of the scouring pit; α, β are the angles between the slope and the horizontal plane before and after the scouring pit, and ρ w is the water density.
- 根据权利要求3所述的下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,所述正态曲面防护结构还包括插入河床中用于固定所述正态曲面壳体的圆柱套 筒形底座,其厚度与正态曲面壳体厚度相同,该底座的内表面满足如下关系:The pier scour protection method combined with a concave rotating normal curved surface and granular bodies according to claim 3, wherein the normal curved surface protection structure further comprises inserting into a river bed for fixing the normal curved shell The thickness of the cylindrical sleeve-shaped base is the same as that of the normal curved shell, and the inner surface of the base satisfies the following relationship:h c为圆柱套筒形底座高度。 h c is the height of the cylindrical sleeve-shaped base.
- 根据权利要求4所述的下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,a=0.1~0.3m,h c=1~2m。 The method for scouring protection of bridge piers combined with a concave rotating normal surface and granular bodies according to claim 4, characterized in that a = 0.1 to 0.3 m, and h c = 1 to 2 m.
- 根据权利要求4所述的下凹型旋转正态曲面与散粒体结合的桥墩冲刷防护方法,其特征在于,散粒体粒径d为当地自然条件下极端流速作用时泥沙起动粒径的3~5倍。According to claim 4, the method for protecting bridge pier erosion by combining a concave rotating normal surface with bulk particles is characterized in that the particle size d of the bulk particles is 3% of the initial particle size of the sediment under the action of extreme flow velocity under local natural conditions. ~ 5 times.
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