《水工建筑物》课程设计计算书——宁村水库重力坝初步设计目录一、工程等级的确定·······················································································3(一)原理··································································································3(二)计算过程····························································································3二、孔口尺寸拟定及设计洪水位、校核洪水位的确定············································3(一)堰顶高程的拟定··················································································3(二)堰顶溢流前沿宽度的拟定······································································3(三)设计洪水位、校核洪水位的计算·····························································4三、挡水坝设计······························································································4(一)坝顶高程的确定···················································································4(二)建基面高程的确定················································································5(三)坝顶宽度的确定···················································································5(四)上下游坝坡坡率及起坡点位置的确定·························································5(五)坝面优化·····························································································5(六)坝体强度稳定承载力极限状态设计····························································5(七)坝体上游面拉应力的正常使用极限状态设计················································5(八)坝体应力分析························································································5四、溢流坝设计······································································································5(一)溢流坝断面设计······················································································5(二)消能防冲设计·························································································8(三)导墙设计································································································9(四)坝体强度稳定极限状态设计······································································10(五)坝体正常使用极限状态合计······································································10五、大坝剖面优化和应力稳定分析··············································································10六、工程量与开挖量计算··························································································11七、附表···············································································································11(一)附表一:挡水坝电算方案·········································································11(二)附表二:溢流坝电算方案·········································································18宁村水库重力坝初步设计计算书一、工程等级的确定(一)原理:拟定泄水建筑物,进行调洪计算,求得校核洪水位,再根据附图1(宁村水库水位~库容关系曲线)查得水库总库容,最终根据规范《水利水电工程等级划分及洪水标准》SL252-2000确定工程等级。(二)计算过程:已知:在校核洪水(0.2%)下,Q=588m3/s;正常蓄水位126.50m;死水位106.00m。坝址岩层以砂岩为主,夹泥岩和页岩,砂岩抗压强度较高,但泥岩、页岩抗压强度稍低,其允许承载能力为0.6~0.7MPa,岩层倾向上游,岩石节理、裂隙发育,整体性稍差,并夹有软薄层,抗滑能力较低。下游河道平均水深2米左右。预计采用消能效果较好的消能工。综合地质条件、下游河道水深、枢纽布置和消能工设计,因此,通过技术经济比较后选定单宽流量q=28m3/(s·m)。则堰顶宽b=Q/q=588/28=21m由Hd=(0.7~0.95)H校,取Hd=0.85H校即Hw/Hd=0.85查图3可得m=0.490<0.502,满足要求。式中:Hd为定型设计水头,m;Hw为堰上水头,m。根据公式Q=ε1σsmnbg2H3/2,式中:ε1:侧收缩系数,与边墩、闸墩及闸墩头部的型式、堰孔的数目、堰孔的尺寸、全大大大大的水头等有关,ε1=0.96;σs:淹没系数,为自由出流σs=1;n:堰孔数,本设计中为1;m:流量系数,由计算得出m=0.490;b:堰顶宽,由计算得出b=21m;g取9.81m2/s。带入公式有:H校=[Q/(ε1smnbg2)]2/3=[588/(0.96*1*0.490*21*81.9*2)]2/3=5.65mHd=0.85H校=0.85*5.65=4.80mZ校=126.50+5.65=132.15m查水位~库容关系曲线(图1)确定总库容V总=657.6(万m3)根据工程效益、总库容查询规范SL252—2000,该工程的等别为Ⅲ等。二、孔口尺寸拟定及设计洪水位、校核洪水位的确定(一)堰顶高程的拟定因为是开敞式溢流坝身泄水,并无调节等要求,因此堰顶高程就是正常蓄水位高程,即为126.50m。(二)堰顶溢流前沿宽度的拟定因为砂岩中还夹有泥岩、页岩等,砂岩本身强度也不高,且不完整,因此从消能防冲考虑,应按破碎岩石处理,单宽流量q=20~50m3/s,又综合考虑了以上四方面的因素,初步选定单宽流量q=28m3/(s·m),按渲泄最大洪水时的流量Q校=588m3/s考虑,得到溢流前沿宽度为:L=Q校/q=588/28=21m(三)设计洪水位、校核洪水位的计算1、原理:试算法。首先假定一个堰上水头H设,计算H设/Hd值,查附图3,宁村水库Hw/Hd与流量系数m关系曲线,得出流量系数m,代入公式Q=ε1σsmnbg2H设3/2求出设计洪水H设。与资料给的设计洪水(2%)Q设=450m3/s比较,误差不超过1%即可。2、已知:由以上计算知堰顶高程为126.50m,单宽流量q=28m3/s,及前沿宽度L=21m。由确定工程等级过程推求得校核洪水位为Z校=132.15m。3、计算过程:通过多次试算结果简单列表如下:(表4)方案堰上水头H设(m)HdH设/Hd流量系数m设计洪水Q设(m3/s)设计洪水(2%)Q设(m3/s)误差一4.804.8010.501460.15450.002.25%二4.754.800.9900.500452.98450.000.66%三4.744.800.9880.500451.55450.000.34%四4.734.800.9850.500450.12450.000.03%经过多次试算,方案一、二、三不满足设计规范,方案四和方案五均满足设计要求,但方案五更为精确。故选定方案四作为设计依据。即H设=4.73m。推求设计洪水位:Z设=4.88+126.50=131.23m。三、挡水坝设计(一)坝顶高程的确定重力坝坝顶高程按坝顶上游防浪墙顶高程计,按下式计算,取其大值。防浪墙顶高程=设计洪水位+△h设防浪墙顶高程=校核洪水位+△h校其中设计洪水位、校核洪水位已计算得出,只需求△h即可。△h=h2%+hz+hc式中:h2%:累计频率为2%时的波浪高度;hz:波浪中心线高于静水位的高度;hc:安全加高,按表5选用。表5安全加高hc运用情况坝的级别123设计情况(基本情况)0.70.50.4校核情况(特殊情况)0.50.40.3根据官厅水库公式求h1%、hz:1、设计情况①高:hl=0.0166*V05/4D1/3=0.0166*275/4*31/3=1.474m由于gD/Vo2=9.81*3000/152=40.37在(20,250)之间,故为累计频率为5%的波高。h1%=1.24h5%=1.24*1.474=1.828m②波长:L=10.4(h1%)0.8=10.4*1.8280.8=16.851m③高:hz=(πh1%2/L)cth(2πH)/L=0.623m④表5得hc=0.4因此△h=h2%+hz+h=0.808+0.234+0.4=2.851mH=131.23+2.851=134.08m2、校核情况①波高:hl=0.0166*V05/4D1/3=0.0166*155/4*31/3=0.707m②波长:L=10.4(h1%)0.8=10.4*0.8770.8=9.363m③高:hz=(πh2%2/L)cth(2πH)/L=0.254m④表5得hc=0.3因此△h=h2%+hz+h=0.877+0.254+0.3=1.431mH=132.15+1.431=133.58m相比取大者,所以坝顶高程为134.08m。(二)建基面高程的确定根据该坝的地形地质条件,建基面可设在弱风化处,在高程为85m~86m附近,该设计取建基面高程为85.00m(三)坝顶宽度的确定根据《混凝土重力坝规范》SDJ21-78,坝顶宽度应根据设备布置运行检修施工和交通等需要确定,并应考虑抗震特大洪水时抢护以及