高应变拟合检测报告

XXX工程基桩检测方案编写：审核：批准：委托单位：编制单位：单位地址：联系人：编制日期：目录1服务承诺及质量保证承诺 (3)2方案编制依据及检测目的 (3)2.1方案编制依据 (3)2.2检测目的 (3)3工程概况 (3)4检测方法及抽检数量 (3)4.1高应变法 (4)4.2桩身完整性检测 (4)5高应变试验检测方法 (4)5.1检测试验方法及技术要求 (4)6基桩桩身完整性检测 (5)6.1低应变法 (5)6.2需施工单位现场配合、准备的工作 (7)7检测工期估算 (7)7.1高应变法 (7)7.2低应变法 (7)7.3编写报告 (7)8保证本工程检测安全的方法和措施 (7)9拟投入检测人员 (8)10拟配备的检测设备 (9)检测方案会签栏 (10)1服务承诺及质量保证承诺严格遵守检验工作程序，执行国家、行业和地区有关检验的标准、规范，为委托单位提供科学公正、准确可靠、优质高效的服务，以“一流的质量、一流的管理、一流的服务、一流的效率”确保实现以下承诺：质量承诺：满足国家现行相关规范（规程）的要求，如因检测工作不到位或检测成果资料错误，造成委托方工程损失的，按国家或广西区现行建筑法规的有关规定承担相应责任。

（以上段落可以修改或删除）2方案编制依据及检测目的2.1方案编制依据2.1.1《建设工程安全生产管理条例》；2.1.2委托方提供的本工程图纸；2.1.3《建筑基桩检测技术规范》（JGJ106－2014）；2.1.4国家有关规范（规程）和设计要求。

2.2检测目的2.2.1采用高应变法对基桩进行检测，判定单桩竖向抗压承载力是否满足设计要求；2.2.2采用低应变法对基桩进行检测，检测桩身缺陷及其位置，判定桩身完整性类别。

3工程概况本项目基础采用静压预应力混凝土管桩。

单位工程概况具体见表3.1。

4检测方法及抽检数量根据相关规范和文件的要求，该工程拟采用高应变法试验检测单桩竖向抗压承载力，采用低应变法来检测桩身完整性。

委托编号：2019-模拟-051计量认证：160302340774资质证号：（冀）建检字第11147号检测报告（高应变检测）工程名称：---*******************2019年9月注意事项1、报告无“检验检测专用章”或检验单位公章无效；2、复制报告未重新加盖“检验检测专用章”或检测单位公章无效；3、报告无报告人、审核、批准签字无效；4、报告涂改和无骑缝章无效；5、对检测签订报告若有异议，应于收到报告之日起十五日内向检测单位提出；6、一般情况，委托检测鉴定，仅对委托项目负责。

高应变试验检测报告批准人：审核人：主检人：绘图人：目录一、工程概况 (5)二、检测内容 (5)三、检测依据 (5)四、检测数量表 (5)五、工程地质概况 (5)六、检测方法简介 (5)七、检测结果分析 (8)八、附图 (10)一、工程概况地基参数：本工程桩桩径800mm，单桩承载力特征值不小于1400kN，混凝土强度C30。

检测方法：高应变法检测设备：基桩动测仪一台，重锤。

检测日期：2019年9月22日二、检测内容：单桩竖向承载力特征值。

三、检测依据1、《建筑基桩检测技术规范》JGJ106-2014；2、设计图纸及相关技术资料。

四、检测数量表五、工程地质概况详见勘察报告六、检测方法简介本次检测采用高应变曲线拟合法，严格依据执行《建筑基桩检测技术规范》（JGJ106-2014）被检测桩均被凿去浮浆及破损部分，露出新鲜密实的混凝土；每根桩两侧经打磨平整处理后各对称布置2传感器。

测试仪器为基桩动测仪，现场检测设备安装祥见所附示意图1。

实测曲线拟合法是利用重锤锤击下测量的桩顶力和速度波形来计算桩侧和桩端阻力分布的一种高应变动测方法。

其计算方法是从一条实测曲线[如V(t)曲线─对加速度曲线积分而求得]出发，通过对桩身各段土阻力和其它动力参数进行设定，然后通过波动理论计算程序，应用行波理论构造迭代格式，将计算的桩顶力波Fc(t)曲线同实测的力波曲线Fm(t)进行反复比较、迭代 (迭代过程中可对人为假定参数进行调整)，使得计算Fc(t)曲线与实测Fm(t)曲线的拟合趋于完善(即拟合因子MQ 达到设置的标准要求)。

高应变法检测计算承载力与静载对比分析摘要：桩基检测方法多样，各种检测方法具有不同的特点。

本文结合检测实例对检测管桩工程承载力的高应变与单桩竖向抗压静载试验检测两种方法的测试原理、过程、结果等方面进行对比分析。

与高应变相比，静载法试验结果直观、准确，但试验周期长、费用高。

实践中可根据具体工况选用，通过采取控制措施提供测试的准确性。

关键词：预应力管桩；高应变拟合曲线法；单桩竖向抗压静载试验引言由基桩和桩顶的承台构成的桩基础工程主要承载上部建筑荷载力并有效传递到深层地下，是整个工程中较为重要的部分，其涉及建筑主体的安全，其质量管控不容忽视。

预应力管桩采用高压、高温、蒸汽养护等技术手段，应力强度可达到C80以上，而且承载能力强、施工效率高、成本低、养护周期短、成桩质量可靠，目前应用极为广泛。

高应变检测根据一维纵波理论，计算出桩模型和桩土体系简化，所有计算结果是基于桩-土模型和测量参数的设定，高应变法的计算结果具有多解性，因此，需要动静对比，进一步验证计算结果的准确性。

一、高应变检测原理及特点高应变检测基于应力波理论，依据一维应力波弹性传播原理，假定桩周土介质均匀，桩身为弹性直杆件，且具有一维、杆件材料和杆截面应力均匀连续、各向同性的属性，采用重锤冲击桩顶，获得较高的冲击能量，使桩土间相对位移量能够满足测量要求，桩周土摩阻力及桩端支承力通过重锤力的激发，利用传感器获取基桩竖向抗压承载力，从而对桩身质量完整性进行评判。

再利用计算机辅助系统拟合计算实测波形分析得到基桩周、周土力学参数、桩端土阻力分布以及荷载-沉降曲线。

通常，假定基桩是1个材质均匀、等截面的直杆，杆周围摩阻力忽略不计，直杆截面面积为A，直杆材料弹性模量为E，密度为ρ，时间为t，当杆在轴向力作用下沿x轴方向发生纵向位移μ，设定在杆件受压时，应变及各种力为正，速度、位移、加速度等参数定义为与x轴同方向为正，可以得到一维应力波动方程：式中， ,为应力波沿杆竖向传播速度。

Pile High-Strain Dynamic (Drop-Weight) Testing and Low-Strain Pile Integrity TestingReport（Final）Project Name：T e s t i n gL o c a t i o n：Testing Time：January 18,2014January 21.2014Project name：Owner ：Investigation：CompanyDesign：CompanyConstruction：CompanyTesting：CompanyThe Main testing Technicist：andCertificate No. Compiled by：Checked by：Review by：Approved by：Explanation：Testing Company：AddressPostal code：Table of Content1．Project Summery (4)2．Principles and Methods of Testing (8)2.1 Low Strain Integrity Testing (8)2.2 High Strain Dynamic Testing (8)3．Equipment (9)4．Test Result (10)4.1 Detection of low strain pile integrity (10)4.2 High strain detection of vertical bearing capacity of a singlepile (12)5．Conclusion (12)Figure: (13)1.Low-strain curve (13)2.High-strain curve (13)3.Foundation pile detection plan (14)1．Project SummeryThe proposed building(structure) divide into Working Area and Equipment Area. Working area mainly include: Fire Emergency Center, Administration Building, Dinning Room, Prayer Room etc.; Equipment area mainly include: Main Substation, Stream&Generating Set, Integrated Pumping station, Waste Disposal Plant, Cooling Water Unit, Packing House, Torch, Synthetic Ammonia Installation, Ammonia Tank, Urea Plant, Urea Bagged Warehouse, Bulk Urea Warehouse etc. Major building(structure)shown in the table below:The detection of the project, using bored pile foundation, and technology of long spiral drilled, the total number of pile is 12, length 18.9m,effective length 18.1m,diameter 500mm,single-pile vertical bearing capacity characteristic value of 1000kN,concrete class C30.Our Company undertake the Engineering Foundation pile detection tasks, use High-Strain Dynamic (Drop-Weight) Testing method to detect the verticalbearing capacity of a single pile which detection number is 5,and use the low-strain method to detect the pile integrity, the amount of which is 10. The testing work began on January 18,2014,completed on January 18,2014. According to drilling report，the stratum consists of plain and miscellaneous fill, Silt , Silty clay, clay etc.,described as below:Layer 0，Miscellaneous fill: variedness，mainly composed of construction waste. Just No.JT2 pore is distributed at preliminary prospecting.Layer 0A，Plain fill:brick red with gray,mainly silty sand,mixed with a little silt.Just No.140 and 144 pore are distributed.Layer 1A0，Silty clay:from brick red to yellowish-brown with gray,mixed with a little silty sand.Soft plastic.High compressibility.Local distribution.Layer 1A1-1,silty sand:brown with gray,mixed with a little silt and a very small amount of clay.From very wed to saturation,loose.High compressibility.Scattered distribution.Layer 1A1,s ilty sand:from brick red to brown-yellowish with gray,mixed with a little silt and a very small amount of clay.From very wed to saturation,from loose to slightly dense.High compressibility.Local distribution.Layer 1A,Silty clay:gray,yellowish-brown,with a little silty sand.Plastic.Medium plastic.Widely distributed.Layer 1A2,s ilt:from yellowish-brown to brick red,mixed with a little clay.Medium dense,from wed to very wed.Medium compressibility.Scattered distribution.Layer 2A0,silt:from yellowish-brown to brown with gray,mixed with a little ofclay.From medium to dense，from wed to very wed.Medium compressibility.Local distribution.Layer 2A,Silty clay:from yellowish-brown to brick red,mixed with a little of clay silt. Frome medium plastic to hard plastic.Medium compressibility.Local distribution.Layer 2A1,silty sand:light brown and yellowish-brown with gray，mixed with a little of clay silt.Medium dense,saturation.Medium compressibility.Widely distributed.Layer 3A,silty sand:gray,yellowish-brown,mixed with a little of clay middle-fine-sand and silt.Dense,saturation.Medium biased toward high compressibility.Widely distributed.Layer 3B,silty sand:gray,yellowish-brown,containing mica,mixed with a little of clay middle-fine-sand and silt.dense,saturation.Medium biased toward high compressibility.Widely distributed.Layer 3B1,Silty clay:from light brown to blue-gray,mixed with a little of clay middle-fine-sand.hard plastic.Medium compressibility.Scattered distribution. Layer 3C,silty sand:from gray to yellowish-brown,containing mica，mixed with a little of clay middle-fine-sand and silt.Dense,saturation.Low compressibility.Widely distributed.Layer 3D,silty sand:from gray to yellowish-brown,containing mica,mixed with a little of clay middle-fine-sand and silt.From slightly dense to medium dense，saturation.Just No.JT1 pore are distributed at preliminary prospecting.Medium compressibility.The physical and mechanical properties of aquifers is provided by the detailed survey report according to”Project Geotechnical Investigation Report”.2．Principles and Methods of Testing2.1 Low-Strain Pile Integrity TestingThe Sonic-Echo test is performed by striking the pile head with a light hammer and measuring the response of the pile with a sensor (accelerometer or geophone velocity transducer) coupled to the pile head. The hammer blow generates a compressive stress wave which is channeled down the pile shaft as a ‘bar-wave’. The latter is partly reflected back towards the pile head by any change in impedance within the pile. These impedance changes can be as a result of changes in pile section, concrete density or shaft-soil properties. The stress wave is transmitted through the pile at velocity, Vb (where Vb is the bar-wave velocity of propagation through the pile material) and the time lapse, t, between the hammer impulse and the arrival of the reflected waves at the pile head from pile tip is a measure of the distance traveled by the stress wave, such that:t = 2L/Vbwhere L represents the distance to the reflecting surface (pile tip in this case). If the value of Vb, is known, or can be estimated within reasonable limits, then will give an estimate of the pile length or the depth to any other reflecting surface within the pile. If the pile length is known, then a comparison can he made between (he length calculated from the test result and the known length, in order to verify that the depth to the reflecting surface is correct2.2 High Strain Dynamic (Drop-Weight) TestingPlace a weight and decoupling device over the pile head. Releasing the decoupling in the experiment,the weight fall free and impact the pile head, generated stress wave spread down along the pile. cause of the soil resistance stress wave is reflected back to the pile head, and change the motion speed ofparticle of the pile. Using the strain and acceleration sensors at a distance of 1.5 to 2 times of the pile diameter record the acceleration and stress wave of pile when the weight fall free. Using pile analyzer curve fitting calculate the bearing capacity that is equivalent to the bearing capacity under static load based on the measured curve below: Assume the pile and the soil mechanics model and model parameters of each unit, using the measurement of velocity or force curve as the input boundary conditions, Numerically solving wave equation, Inverse the force or velocity curve of the pile head. If the calculated curves doesn't match the measured curve, it means that the model and the measured curve is not reasonable, targeted to adjust the model and parameters and then calculated, Until the calculated curve and the measured curve is match and can not be improve easily. At this time, the assumption model and parameters can simulate the static load tests, according to the simulation of static load test, the bearing capacity of the pile can be analysis and calculated.3．EquipmentThe devices used in high strain and low strain dynamic testing are RS-1616K (S)-type pile dynamic testing instrument and its sensors, strain rings and other accessories produced by China Engineering Technology Co., Ltd., Wuhan, and these devices have acquired the national type approval of measuring instruments (CPA: State Bureau of Technical Supervision License No. 96R105-42), and its manufactory obtained the "measuring equipment manufacturing production permission" of the device (CMC: 96 volume of the system Hubei word 01000216-3 No.). These devices, its sensors, strain rings and other measuring are tested and certificated by the Research Institute, the certificate number: force value No. 120202795.The devices and accessories as follows4．Test Result4.1 Low-Strain Pile Integrity TestingThis detection applies low strain dynamic testing method to detect the integrity of these piles. Live recording of the measured signal curves refer to ‘low strain curves of the time domain’.Based on ‘Building pile testing technical specifications’ (JGJ106-2003), the tables of classification and decision which are the results of the detection of integrity of piles by low strain dynamic testing as follow:Table of the integrity classification of pileTable of the integrity decision of pileAccording to the ‘Classification Table of integrity of the piles ‘and ‘Decision Table of integrity of the piles’, the analyzed the live recording of the measured signal curve and the following determing results as follow: The collection table of detection of piles by low strain dynamic testing method4.2 High strain Testing for vertical bearing capacity of a single pileThis project detect 5 piles by using high strain，the hammer is weight 20kN,drop height is 0.5 to 1.0m.On the measurement of test pile and velocity curve is described in the each test piles figures ’Measured Force and the Measured Velocity Curve’。

目录一、工程概况 (1)二、地形、地质条件描述 (2)三、受检结构物检测内容 (2)四、检测设备、测试原理及判定标准 (3)五、检测数据、实测与计算分析曲线、汇总结果 (4)六、检测结论 (5)公路工程基桩动测报告一、工程概况受建工集团有限责任公司的委托，公路工程试验检测中心有限公司承担了S301大线和乡至许家乡段改建工程B16合同段的基桩承载能力检测任务，对K18+166.850洪水河大桥的基桩承载能力采用高应变法进行检测。

详见表1。

表1 工程概况二、地形、地质条件描述S301大林线安阳永和乡至许家沟乡段改建工程位于安阳市，市境版图略呈半环形，地势西高东低，属于平原微丘区。

项目区第四系和晚第三系地层总厚度达735米，下伏地层为三叠系，路区被第四系被全新统冲洪积地层广为覆盖。

依据邻近勘探资料，上部为第四系全新统冲洪积，为二元结构明显，即上层以可塑状粉质粘土为主，局部夹粉土和砂土，总厚度变化较大，最厚大于30m，一般10-20米，承载力大于100kPa，无软弱层，工程性质一般。

下层以密实状卵石层为主，夹粉土承载力大于400kPa，其工程性质较好；下部为第四系上更新统冲洪积，以硬塑粉质黏土为主，夹密实粉土，工程性质好。

项目所在地区河流属河海水系。

主要河流有漳河、淇河、卫河及其支流安阳河等，均系季节性河流。

安阳地处内陆，属温带大陆性季风气候。

主要特点是春季温暖多大风，夏季炎热雨集中，秋季凉爽日照长，冬季寒冷少雨雪。

安阳年平均气温为14℃，主要降水季节为4-9月份，集中了年降雨量的80%以上。

设计标准：1、道路等级一级公路；2、设计速度80km∕h；3、设计荷载全线桥梁设计荷载为公路-Ⅰ级；4、地震效应地震动峰值加速度为0.20g；5、设计洪水频率大中桥、小桥和涵洞为1/100。

三、受检结构物检测内容根据委托单位及设计单位的要求，按照合同规定，本次检测的主要项目包括：1、检验单桩竖向抗压承载能力；2、检验桩身完整性及均匀性。

高应变检测高应变检测是一种重要的技术，广泛应用于工程、材料科学以及生物医学领域。

它通过测量物体在受力下的变形程度，来评估物体的强度和稳定性。

本文将介绍高应变检测的原理、应用领域、相关技术和发展前景。

高应变检测的原理是基于物体受力导致的形变，利用适当的传感器进行测量。

传感器可以是电阻应变计、光纤光栅、电容应变计等。

这些传感器的工作原理各不相同，但都可以通过测量物体表面或内部的形变情况，来判断物体的应变程度。

高应变检测在工程领域有着广泛的应用。

例如，结构工程师可以利用高应变检测来评估建筑物、桥梁和其他结构的安全性能。

通过在关键部位安装传感器，可以实时监测物体的应变情况，并及时采取措施，以防止结构的破坏和崩溃。

此外，高应变检测也在材料科学领域中扮演重要角色。

材料科学家可以通过测量材料的应变程度，来评估材料的弹性、硬度和韧性等特性。

这对于合金、陶瓷、塑料等材料的研究和应用具有重要意义，有助于优化材料的性能和开发新材料。

在生物医学领域，高应变检测也发挥着重要作用。

例如，医生可以利用高应变检测来监测人体内部的血管应变，从而评估血管的健康状况。

这对于心血管疾病的早期诊断和治疗具有重要意义。

与高应变检测相关的技术也在不断发展。

例如，现代传感器技术的进步，使得高应变检测更加精确和灵敏。

同时，计算机技术的快速发展，使得高应变检测的数据处理和分析更加方便和高效。

未来，高应变检测有着广阔的发展前景。

随着科学技术的不断进步，高应变检测将在更多领域中得到应用。

例如，在航天领域，高应变检测可以用于评估航天器在发射和运行过程中的结构安全性。

在汽车工业中，高应变检测可以用于评估汽车的碰撞安全性能。

在体育领域，高应变检测可以用于评估运动员的受力情况，从而预防运动损伤。

总之，高应变检测是一项重要的技术，已经广泛应用于工程、材料科学和生物医学领域。

它通过测量物体受力导致的变形情况，来评估物体的强度和稳定性。

未来，高应变检测有着广阔的发展前景，将在更多领域中发挥重要作用。