钢筋混凝土结构设计论文

技术论文浅谈普通钢筋混凝土结构钢筋工程工艺浅谈普通钢筋混凝土结构钢筋工程工艺摘要：钢筋工程是钢筋混凝土结构施工重要工序之一，对建筑结构承载力及安全性有重要影响。

笔者结合这几年工程实际施工经验及规X要求，就普通钢筋混凝土结构钢筋工程中原材料（常用热轧钢筋）控制、钢筋储存、钢筋下料构造要求、除锈、调直、切断、弯曲成型、钢筋安装工艺、施工过程主要注意事项进行了简单阐述。

关键词：原材料控制构造要求下料除锈调直弯曲成型钢筋绑扎引言钢筋工程是钢筋混凝土结构施工重要工序之一，对建筑结构承载力及安全性有重要影响。

笔者在具体施工过程中，发现钢筋工程中原材料控制不严格、钢筋制作不符合规X构造要求、安装工艺不正确，会严重影响结构安全性、增加材料用量、影响结构外观质量，对后续消除、降低这些影响，需要投入较大人力、物力，不利于工程进度、质量、安全、成本的控制。

在此，笔者就钢筋工程工艺做简单总结，为后续钢筋工程施工提供借鉴。

一.原材料控制1.对供货商的资质进行评审，选择合格的供应商。

2.热轧钢筋进场时，检查产品合格证、出厂检验报告和进场复验报告。

并应按批进行外观检查和力学性能试验。

每批由同一牌号、同一炉号、同一规格的钢筋组成，重量≦60t。

允许由同一牌号、同一冶炼方法、同一浇注方法的不同炉号组成混合批，但各炉号含碳量之差≦0.02％，含锰量之差≦0.15%。

从每批钢筋中抽取5%进行外观检查。

钢筋表面不能有裂纹、结疤和折叠。

当钢筋按实际重量交货时，应随机抽取10根（6m长）钢筋称重，如重量偏差大于允许偏差，则应与供应商交涉，以免损害项目利益。

从每批钢筋中随意抽取两根钢筋，每根取两个试件分别进行拉伸试验（包括伸长率、屈服点、抗拉强度）和冷弯试验。

如有一项试验结果不符合下表要求，则从同一批中另取双倍数量的试件重作各项试验。

如仍有一个试件不合格，则该批钢筋为不合格品。

3.钢筋加工过程中如发现脆断，焊接性能不良或机械性能不正常时，应进行化学成份检验或其他专项检验。

钢筋混凝土结构设计论文摘要：框架-核心筒结构设计时，应合理的选取外框与内筒的截面尺寸，避免外周框架刚度过弱而筒体的刚度过强，使之形成外周框架与核心筒协同工作的双重抗侧力结构体系。

合理的设置抗震缝，既能保证结构的规则性，又能控制结构的经济性能指标。

前言随着我国经济的发展，越来越多的人口集中到城市来，造成用地紧张、地价上涨。

由于土地资源的稀缺性及不可再生性，为了在有限的土地资源上获取更多的建筑面积，高层建筑在城市日新月异的发展中大批涌现，其中钢筋混凝土结构的高层建筑最为常见。

钢筋混凝土结构充分的发挥了钢筋和混凝土两种材料的优点，造价低廉，施工方便，耐久性强并且防火性能好。

随着建筑类型及功能的日趋多样化，钢筋混凝土高层建筑的设计逐渐成为结构设计师的重点和难点所在。

本文通过三个工程实例，探讨高层建筑中剪力墙结构及框架-核心筒结构这两种常用结构类型中需要注意的几个问题。

1工程实例1.1某公寓建筑工程概况该工程为钢筋混凝土框架－核心筒结构。

地下二层，地上十八层，建筑高度88.2m。

地下主要为自行车库及设备用房，地上主要为餐饮和酒店式公寓。

1.2设计参数抗震设防烈度为70，设计基本地震加速度值为0.15g，设计地震分组为第二组。

丙类建筑，安全等级为二级，场地土类别为IV类。

地上框架及核心筒抗震等级为二级。

分别采用依据《建筑抗震设计规范》取差值后的特征周期0.62s和水平地震影响系数最大值0.12以及该工程《工程场地地震安全性评价报告》提供的特征周期0.55s和水平地震影响系数最大值0.14分别计算，取结果较大值进行结构设计。

1.3结果及设计分析经计算，采用《工程场地地震安全性评价报告》参数计算结果大于采用《建筑抗震设计规范》参数的计算结果。

主要计算结果如下：第一平动周期 2.15s第一扭转周期 1.64s地震作用最大的方向角度 87.128°X方向楼层承载力与上层之比最小值 0.96Y方向楼层承载力与上层之比最小值 0.95X方向地震作用下弹性层间位移角最大值 1/1176Y方向地震作用下弹性层间位移角最大值 1/852考虑偶然偏心影响的规定水平地震力作用下，楼层竖向构件最大的水平位移和层间位移均不大于相应楼层平均值的1.2倍。

毕业设计（论文）外文文献翻译文献、资料中文题目：钢筋混凝土结构设计文献、资料英文题目：DESIGN OF REINFORCED CONCRETE STRUCTURES 文献、资料来源：文献、资料发表（出版）日期：院（部）：专业：土木工程班级：姓名：学号：指导教师：翻译日期： 2017.02.14毕业设计（论文）外文参考资料及译文译文题目：DESIGN OF REINFORCED CONCRETE STRUCTURES原文：DESIGN OF REINFORCED CONCRETESTRUCTURES1. BASIC CONCERPTS AND CHARACERACTERISTICS OF REINFORCED CONCRETEPlain concrete is formed from hardened mixture of cement, water , fine aggregate , coarse aggregate (crushed stone or gravel ) , air and often other admixtures . The plastic mix is placed and consolidated in the formwork, then cured to accelerate of the chemical hydration of hen cement mix and results in a hardened concrete. It is generally known that concrete has high compressive strength and low resistance to tension. Its tensile strength is approximatelyone-tenth of its compressive strength. Consequently, tensile reinforcement in the tension zone has to be provided to supplement the tensile strength of the reinforced concrete section.For example, a plain concrete beam under a uniformly distributed load q is shown in Fig .1.1(a), when the distributed load increases and reaches a value q=1.37KN/m , the tensile region at the mid-span will be cracked and the beam will fail suddenly . A reinforced concrete beam if the same size but has to steel reinforcing bars (2φ16) embedded at the bottom under a uniformly distributed load q is shown in Fig.1.1(b). The reinforcing bars take up the tension there after the concrete is cracked. When the load q is increased, the width of the cracks, the deflection and thestress of steel bars will increase . When the steel approaches the yielding stress ƒy , thedeflection and the cracked width are so large offering some warning that the compression zone . The failure load q=9.31KN/m, is approximately 6.8 times that for the plain concrete beam.Concrete and reinforcement can work together because there is a sufficiently strong bond between the two materials, there are no relative movements of the bars and the surrounding concrete cracking. The thermal expansion coefficients of the two materials are 1.2×10-5K-1 for steel and 1.0×10-5~1.5×10-5K-1 for concrete .Generally speaking, reinforced structure possess following features :Durability .With the reinforcing steel protected by the concrete , reinforced concreteFig.1.1Plain concrete beam and reinforced concrete beamIs perhaps one of the most durable materials for construction .It does not rot rust , and is not vulnerable to efflorescence .(2)Fire resistance .Both concrete an steel are not inflammable materials .They would not be affected by fire below the temperature of 200℃when there is a moderate amount of concrete cover giving sufficient thermal insulation to the embedded reinforcement bars.(3)High stiffness .Most reinforced concrete structures have comparatively large cross sections .As concrete has high modulus of elasticity, reinforced concrete structures are usuallystiffer than structures of other materials, thus they are less prone to large deformations, This property also makes the reinforced concrete less adaptable to situations requiring certainflexibility, such as high-rise buildings under seismic load, and particular provisions have to be made if reinforced concrete is used.(b)Reinfoced concrete beam(4)Locally available resources. It is always possible to make use of the local resources of labour and materials such as fine and coarse aggregates. Only cement and reinforcement need to be brought in from outside provinces.(5)Cost effective. Comparing with steel structures, reinforced concrete structures are cheaper.(6)Large dead mass, The density of reinforced concrete may reach2400~2500kg/pare with structures of other materials, reinforced concrete structures generally have a heavy dead mass. However, this may be not always disadvantageous, particularly for those structures which rely on heavy dead weight to maintain stability, such as gravity dam and other retaining structure. The development and use of light weight aggregate have to a certain extent make concrete structure lighter.(7)Long curing period.. It normally takes a curing period of 28 day under specified conditions for concrete to acquire its full nominal strength. This makes the progress of reinforced concrete structure construction subject to seasonal climate. The development of factory prefabricated members and investment in metal formwork also reduce the consumption of timber formwork materials.(8)Easily cracked. Concrete is weak in tension and is easily cracked in the tension zone. Reinforcing bars are provided not to prevent the concrete from cracking but to take up the tensile force. So most of the reinforced concrete structure in service is behaving in a cracked state. This is an inherent is subjected to a compressive force before working load is applied. Thus the compressed concrete can take up some tension from the load.2. HISTOEICAL DEVELPPMENT OF CONCRETE STRUCTUREAlthough concrete and its cementitious(volcanic) constituents, such as pozzolanic ash, have been used since the days of Greek, the Romans, and possibly earlier ancient civilization, the use of reinforced concrete for construction purpose is a relatively recent event, In 1801, F. Concrete published his statement of principles of construction, recognizing the weakness if concrete in tension, The beginning of reinforced concrete is generally attributed to Frenchman J. L. Lambot, who in 1850 constructed, for the first time, a small boat with concrete for exhibition in the 1855 World’s Fair in Paris. In England, W. B. Wilkinson registered a patent for reinforced concrete l=floor slab in 1854.J.Monier, a French gardener used metal frames as reinforcement to make garden plant containers in 1867. Before 1870, Monier had taken a series of patents to make reinforcedconcrete pipes, slabs, and arches. But Monier had no knowledge of the working principle of this new material, he placed the reinforcement at the mid-depth of his wares. Then little construction was done in reinforced concrete. It is until 1887, when the German engineers Wayss and Bauschinger proposed to place the reinforcement in the tension zone, the use of reinforced concrete as a material of construction began to spread rapidly. In1906, C. A. P. Turner developed the first flat slab without beams.Before the early twenties of 20th century, reinforced concrete went through the initial stage of its development, Considerable progress occurred in the field such that by 1910 the German Committee for Reinforced Concrete, the Austrian Concrete Committee, the American Concrete Institute, and the British Concrete Institute were established. Various structural elements, such as beams, slabs, columns, frames, arches, footings, etc. were developed using this material. However, the strength of concrete and that of reinforcing bars were still very low. The common strength of concrete at the beginning of 20th century was about 15MPa in compression, and the tensile strength of steel bars was about 200MPa. The elements were designed along the allowable stresses which was an extension of the principles in strength of materials.By the late twenties, reinforced concrete entered a new stage of development. Many buildings, bridges, liquid containers, thin shells and prefabricated members of reinforced concrete were concrete were constructed by 1920. The era of linear and circular prestressing began.. Reinforced concrete, because of its low cost and easy availability, has become the staple material of construction all over the world. Up to now, the quality of concrete has been greatly improved and the range of its utility has been expanded. The design approach has also been innovative to giving the new role for reinforced concrete is to play in the world of construction.The concrete commonly used today has a compressive strength of 20~40MPa. For concrete used in pre-stressed concrete the compressive strength may be as high as 60~80MPa. The reinforcing bars commonly used today has a tensile strength of 400MPa, and the ultimate tensile strength of prestressing wire may reach 1570~1860Pa. The development of high strength concrete makes it possible for reinforced concrete to be used in high-rise buildings, off-shore structures, pressure vessels, etc. In order to reduce the dead weight of concrete structures, various kinds of light concrete have been developed with a density of 1400~1800kg/m3. With a compressive strength of 50MPa, light weight concrete may be used in load bearing structures. One of the best examples is the gymnasium of the University of Illinois which has a span of 122m and is constructed of concrete with a density of 1700kg/m3. Another example is the two 20-story apartment houses at the Xi-Bian-Men in Beijing. The walls of these two buildings are light weight concrete with a density of 1800kg/m3.The tallest reinforced concrete building in the world today is the 76-story Water Tower Building in Chicago with a height of 262m. The tallest reinforced concrete building in China today is the 63-story International Trade Center in GuangZhou with a height a height of 200m. The tallest reinforced concrete construction in the world is the 549m high International Television Tower in Toronto, Canada. He prestressed concrete T-section simply supported beam bridge over the Yellow River in Luoyang has 67 spans and the standard span length is 50m.In the design of reinforced concrete structures, limit state design concept has replaced the old allowable stresses principle. Reliability analysis based on the probability theory has very recently been introduced putting the limit state design on a sound theoretical foundation. Elastic-plastic analysis of continuous beams is established and is accepted in most of the design codes. Finite element analysis is extensively used in the design of reinforced concrete structures and non-linear behavior of concrete is taken into consideration. Recent earthquake disasters prompted the research in the seismic resistant reinforced of concrete structures. Significant results have been accumulated.3. SPECIAL FEATURES OF THE COURSEReinforced concrete is a widely used material for construction. Hence, graduates of every civil engineering program must have, as a minimum requirement, a basic understanding of the fundamentals of reinforced concrete.The course of Reinforced Concrete Design requires the prerequisite of Engineering Mechanics, Strength of Materials, and some if not all, of Theory of Structures, In all these courses, with the exception of Strength of Materials to some extent, a structure is treated of in the abstract. For instance, in the theory of rigid frame analysis, all members have an abstract EI/l value, regardless of what the act value may be. But the theory of reinforced concrete is different, it deals with specific materials, concrete and steel. The values of most parameters must be determined by experiments and can no more be regarded as some abstract. Additionally, due to the low tensile strength of concrete, the reinforced concrete members usually work with cracks, some of the parameters such as the elastic modulus I of concrete and the inertia I of section are variable with the loads.The theory of reinforced concrete is relatively young. Although great progress has been made, the theory is still empirical in nature in stead of rational. Many formulas can not be derived from a few propositions, and may cause some difficulties for students. Besides, due to the difference in practice in different countries, most countries base their design methods on their own experience and experimental results. Consequently, what one learns in one country may be different in another country. Besides, the theory is still in a stage of rapid。

钢筋混凝土建筑结构论文3篇第一篇1建筑物的抗震评估当前，我国的《抗震建筑标准》按照建筑物的使用权限将建筑物分为三大类：使用年限三年的为A类、使用年限四年的为B类、使用年限达到五十年的为C类。

针对建筑物的种类不同，评估和鉴定也会有不同的方法。

对于现有钢筋混凝土建筑结构实行的评估能够划分为两级鉴定：一级鉴定主要对建筑的设计结构实行鉴定，综合评估对钢筋混凝土建筑结构的抗震的各项指标;二级鉴定是在一级抗震鉴定的基础上，通过精密的计算来对钢筋混凝土建筑结构实行再次抗震评估。

加固钢筋混凝土建筑结构实行之前，理应对建筑物实行准确的抗震分析评估。

如果现有钢筋混凝土建筑结构都能满足建筑的各项抗震性能指标，能够不用对现有钢筋混凝土建筑结构实行抗震加固。

如果现有钢筋混凝土建筑物的每一层均有超过85%的大梁、视为满足结构性能和层级位移性能目标。

随着时代的持续发展，人们的安全意识越来越强。

尤其是人们对建筑结构的抗震要求也越来越高。

普通的砖混的建筑容易在地震中坍塌，钢筋框架成了当今社会建筑的必然要求。

尤其是在经历过大地震以后，人们更加注重建筑结构的设计和抗震系数的高低。

当前，我国在工程实践中增加了很多建筑物抗震的方法。

这些方法对于施工更方便，工序更简单，耗用建筑材料也相对较少，既节省了人力，也在加固后充分发挥出了各自功能的优点，在实践中能够减少停产所带来的经济损失，有很强的应用性。

这里面简单介绍以下三种方法的实践应用。

2．1截面积增大加固法截面积增大来对建筑物实行抗震加固，其理论依据主要是在建筑物的弯曲面上打上混凝土，从而提升建筑物结构构件的最大承载水平。

采用增大截面积的具体方法，能够对原建筑新旧混凝土结合部位实行凿打处理，使表面更加光滑、更加平整。

把建筑物表面的不平整度控制在5以内。

在原构件的浇筑面上凿成凹槽，每隔一定的距离，乳状的水泥浆均匀的涂抹在结合处的位置上，并插上钢筋加固。

截面增大的尺寸应满足钢筋强度的设计要求，还要保持充足大的尺寸来放置附加钢板构架，并顺利浇筑混凝土。

钢筋混凝土结构设计论文摘要：随着钢筋混凝土结构在建筑、桥梁等施工领域应用日益广泛，建筑类型与结构体系也变得复杂及多样化，随之而来的安全隐患问题受到社会各界关注，这无疑给工程设计者带来了新一轮的挑战。

钢筋混凝土结构设计一直是工程设计的重点与难点，作为工程设计者一定要意识到钢筋混凝土结构设计的重要性及自身责职所在。

众所周知钢筋混凝土结构在目前建筑、桥梁等施工领域的应用是非常广泛的，也是目前最有影响力的结构形式之一。

随着社会的不断进步，我国建筑业发展迅速，城市面貌日新月异，一栋栋高楼拔地而起，造型新颖独特，工程设计也变得越来越复杂。

我们知道建筑结构设计质量与人们生命财产安全息息相关，作为工程设计者一定要劳劳把好质量这一关。

然而我们却看到，近年来施工期钢筋混凝土结构倒塌事件频频出现，这不得不引起了社会各界对钢筋混凝土结构设计安全性的热切关注。

因此，对于设计者来说如何保证建筑结构设计质量，正确掌握工程特点，采取科学合理的方案、结构形式、计算依据，已成为目前工程设计者共同且最棘手的难题。

下面笔者对钢筋混凝土结构设计中的常见问题进行了详细分析研究。

一.柱下独立基础带梁板式的地下室底板设计方面这里值得提出的是，不少设计者在地下室底析设计中往往忽视建筑物发生沉降的问题，而我们知道，建筑物发生沉降必定会带来一定的附加应力。

基于柱下独立基础带梁板式的地下室底板在一定的荷载作用下，极其容易发生沉降变形，这样一来大大增加了地下室底板承载力从而导致开裂现象出现，对底板安全性造成一定的威胁。

特别是对于采用天然地基的地下室底板来说，威胁就更大了。

那么，如何合理设计柱下独立基础带梁板式的地下室底板，使之更安全呢？这就要求设计者需根据实际情况来判断，当受沉降影响不大时，建议在地下室底板与持力层之间通过褥垫来处理解决。

另外，在钢筋混凝土的结构设计时，要充分考虑因季节变化引起的地下水位对地下室底板的不同影响，尽可能的把各种安全隐患考虑到设计中来，才可以从根本上杜绝危险事故的发生。

钢筋工程毕业论文钢筋工程毕业论文钢筋工程作为土木工程的一个重要分支，旨在利用钢筋的高强度和耐久性来增强混凝土结构的承载能力和稳定性。

在这篇毕业论文中，我将探讨钢筋工程的关键概念、应用领域以及未来的发展趋势。

一、钢筋工程的关键概念1.1 钢筋的作用和分类钢筋在混凝土结构中起到增强和支撑的作用。

根据其形状和用途，钢筋可以分为普通钢筋、螺纹钢筋和预应力钢筋等。

普通钢筋主要用于加固和增强混凝土结构的抗拉能力，而螺纹钢筋则通过与混凝土的黏结力来增加结构的抗震性能。

预应力钢筋则用于在混凝土浇筑之前施加预应力，以增强结构的承载能力。

1.2 钢筋工程的设计原则钢筋工程的设计需要考虑结构的荷载、抗震性能、使用寿命和施工工艺等因素。

设计时应根据结构的功能和使用要求，合理确定钢筋的种类、数量和布置方式。

此外，还需要考虑钢筋与混凝土的黏结性能、防腐蚀措施以及施工过程中的安全性。

二、钢筋工程的应用领域2.1 建筑领域钢筋工程在建筑领域中得到了广泛的应用。

无论是高层建筑、桥梁还是隧道等大型结构，都需要通过钢筋工程来增强其承载能力和稳定性。

此外，钢筋工程还可以用于加固老旧建筑，延长其使用寿命，并提高其抗震性能。

2.2 水利工程水利工程中的堤坝、水库和渠道等结构也需要进行钢筋工程设计。

钢筋的高强度和耐久性可以有效增加这些结构的抗水压能力和稳定性。

此外，钢筋工程还可以用于加固和修复水利工程中的损坏部分，提高其整体的安全性和可靠性。

2.3 地下工程地下工程如地铁隧道、地下室等也离不开钢筋工程的应用。

钢筋的高强度和耐久性可以增加地下结构的抗压能力和稳定性。

此外，钢筋工程还可以用于加固和修复地下工程中的损坏部分，提高其整体的安全性和可靠性。

三、钢筋工程的未来发展趋势3.1 新材料的应用随着科技的进步，新型材料如高性能混凝土、纳米材料等将逐渐应用于钢筋工程中。

这些新材料具有更高的强度和耐久性，可以进一步增强结构的承载能力和稳定性。

此外，新材料的应用还可以减少对传统资源的依赖，降低环境污染。

浅析多层建筑钢筋混凝土框架结构设计摘要:伴随着建筑造型和建筑功能要求日趋多样化,无论是工业建筑还是民用建筑,在结构设计中遇到的各种难题也日益增多。

本文从结构设计计算、构造措施、设计注意事项等方面探讨了钢筋混凝土框架结构设计中需要注意的问题。

关键词:多层框架结构；结构设计；设计计算伴随着我国经济的迅猛发展,我国的多层建筑也发展迅速,设计思想也在不断更新。

钢筋混凝土框架结构是目前应用最广泛的结构形式之一。

钢筋混凝土框架结构是由楼板、梁、柱及基础4种承重构件组成的,由主梁、柱与基础构成平面框架,各平面框架再由连续梁连接起来而形成的空间结构体系。

在合理的高度和层数的情况下,框架结构能够提供较大的建筑空间,其平面布置灵活,可适合多种工艺与使用功能的要求。

但是,在框架结构设计中,仍然存在着一些概念性和实际性的问题需要设计人员予以高度重视,以确保结构设计质量[1—8]。

1 正确选取重要的结构计算参数结构设计计算时,除了有合理的结构方案、正确的结构计算简图外,正确选择抗震设防烈度和场地类别、合理选取电算软件中的其他各项参数也是十分重要的。

1.1结构的抗震等级工程设计中,各类房屋建筑首先应当确定建筑类别。

对于丙类建筑,其地震作用均按本地区抗震设防烈度计算。

对于乙类建筑,（建筑抗震设计规范）文献[2]规定:地震作用应符合本地区抗震设防烈度的要求,但是抗震措施(主要体现为抗震等级)在一般情况下,当抗震设防烈度为6～8度时,应符合本地区抗震设防烈度提高一度的要求;当为9度时,应符合比9度抗震设防更高的要求。

实际设计中经常发生抗震等级选错的情况,如:位于8度区的某乙类建筑,应按9度由（抗震设计规范）文献[2]确定其抗震等级为一级。

当8度地区的乙类建筑的高度超过文献[2]规定的范围时,还应采取比一级抗震等级更有效的抗震措施。

1.2设计基本地震加速度（抗震设规范）文献[2]规定:抗震设防烈度为7度时,设计基本地震加速度值分别为0.1g和0.15g两种,抗震设防烈度为8度时,设计基本地震加速度值分别为0.2g和0.3g两种。

对钢筋混凝土结构设计的探讨摘要：在建筑结构中钢筋混凝土的应用也及其普遍，混凝土的出现已有近百年的历史，混凝土是当今建筑结构中主要的建筑材料，由于混凝土具有很高的抗压性及耐候性，一直被建筑业所沿用，混凝土结构在建筑结构及桥梁结构中被普遍采用，在混凝土结构中加入钢材便组成了钢筋混凝土结构，本文主要对钢筋混凝土的特性和作用做一些阐述，让钢筋混凝土在建筑结构中长久沿用发展。

关键词：钢筋混泥土;结构;设计abstract: in the construction and application of reinforced concrete and common concrete, the emergence of nearly a hundred years history, concrete is the main building materials in the construction structure, because the concrete has high compressive resistance and weather resistance, has been used by building industry, concrete structure is widely used in building structures and bridges structure, adding steel in concrete structure will be composed of a reinforced concrete structure, the main characteristics and the role of reinforced concrete to do some elaborate, for reinforced concrete structures in the long-term use development. keywords: reinforced concrete; structure; design中图分类号：s611文献标识码：a 文章编号：1混凝土结构配合比设计是保证钢筋混凝土强度的主要因素混凝土具有很高的抗压强度，这与其混凝土的骨料级配与粗细程度有着密切的关系，不同的骨料级配严重影响着混凝土结构的性能，混凝土的基本骨料主要有水泥、沙子、石子、还有水组成，在不同的建筑结构中根据结构设计的需要还需掺入少量的外加剂，但外加剂的含量要严格控制，不能超过其含量的5%，混凝土在制作的过程中要根据工程的需要对混凝土的和易性、抗压强度、耐久性进行控制，合理的选择材料并按要求进行配合比设计，建筑工程中常采用水灰比法则进行混凝土配合比设计，组成材料的用量采用绝对体积法计算。