Specialized in manufacturing compensators, expansion joints, baffle doors
A comprehensive scientific and technological enterprise integrating design and development, production, product sales, installation and debugging
Specialized in the production of metal compensator, non-metal compensator, baffle door equipment for 18 years
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Product introduction of metal rectangular expansion jointProduct Structure and C...
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Universal corrugated expansion joint
The universal corrugated expansion joint is a kind of flexible compensation elem...
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Single axial expansion joint
I. Structural compositionThe single axial expansion joint is mainly composed of ...
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Nantong Chuangxin Machinery Co., Ltd. is located in the plain of central Suzhou, close to Nantong and Ningjingyan Expressway with convenient transportation, and less than 2 hours drive from Shanghai, Suzhou, Wuxi, Nanjing and other large and medium-sized cities.
The company is a comprehensive scientific and technological enterprise integrating design and development, production, product sales, installation and debugging. The company has successively communicated and cooperated with the National Cement Research Institute and the general contractor!
The company's main products are metal compensator (expansion joint), non-metal compensator (expansion joint), baffle door and other series products, providing excellent and cheap complete sets of equipment for the majority of users at home and abroad.
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焊接工艺对了,膨胀节能多用三五年——现场焊接为啥不能糊弄干过现场的人都知道,金属波纹膨胀节一旦焊砸了,返工是小事,整个管道系统都得跟着遭殃。...
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Frequently asked questions
Answers to your frequently asked questions about compensators and baffle doors
为什么补偿器的端部结构比波纹本体还关键?
前两天有个做烟气脱硫项目的客户找过来,管道用的是脱硫烟气挡板门和非金属膨胀节,结果端部法兰密封垫选错了,没两个月就漏得哗哗的。你说冤不冤?补偿器端部是管道系统应力传递的“关节”,不仅要承受介质压力、温度位移,还得扛得住现场安装误差——工人稍微对不齐,端部就得硬扛。端部结构一旦出问题,波纹管再好也是白搭。所以别光盯着波纹数,端部设计才是那个“一票否决”的环节。
常见的端部结构就那么几种,但选型门道很深
最普遍的是法兰连接,适用于大多数通用型波纹膨胀节和金属软管。这里有个坑:法兰标准(HG/T、GB、ANSI)必须和管道匹配。有人图省事,买回来发现法兰螺栓孔对不上,现场扩孔或者补焊——等于给自己挖坑,密封面一变形,漏是迟早的事。
焊接端部常用于高温高压场合,比如电站行业用波纹膨胀节和高温轴向型膨胀节,直接与管道对焊,强度高但不可拆卸,检修时只能切割。这种结构对焊工手艺要求极高,焊缝探伤不过关?那还不如用法兰。
还有螺纹连接,多用于小口径橡胶补偿器或真空专用软管。但大直径管道千万别用螺纹——扭矩控制不好,直接拧裂端部,我见过DN300的橡胶补偿器,螺纹端部裂得跟蜘蛛网似的。所以螺纹只适合小口径、低压场合。
端部和导流筒的配合,是很多人忽略的细节
膨胀节端部内侧通常要加导流筒(本站问答里专门讲过导流筒的作用),它的核心任务是引导介质流向、保护波纹管免受冲刷。但导流筒的端部怎么固定?是焊死在端管上还是滑动配合?
对直埋(全埋)型膨胀节和外压单式轴向型膨胀节来说,导流筒必须与端部结构一体化设计。否则热膨胀时导流筒移位,会把波纹管刮出划痕,那划痕就是应力集中点,疲劳寿命直接对折。你猜怎么着?有些客户为了省成本去掉导流筒,结果介质直接冲击波纹管根部,一年就穿孔。省几百块,赔几万块,划算吗?
不同工况下,端部结构的设计差异能大到离谱
比如衬四氟金属软管,端部必须做翻边包覆处理,不然四氟衬里和金属端管之间会产生缝隙,腐蚀介质渗进去就鼓包。鼓包了怎么办?只能整根换。再比如矩型非金属膨胀节,端部是框架结构,靠压条和螺栓固定织物纤维。这里的螺栓孔间距设计要算准,拧太紧压坏纤维,拧松了漏风。我见过一个钢厂项目,螺栓间距大了50mm,结果纤维被风吹得哗啦啦响,三个月就磨穿了。
还有旋转补偿器,端部其实是个旋转密封结构,用的是耐高温石墨盘根,和我们常规的焊接端部完全两码事。设计时得考虑盘根的压缩量和更换空间,不然扭力一大,密封失效。
端部失效的几个典型场景,你遇到过几个?
第一种:大口径厚壁膨胀节端部焊缝开裂。多是因为管系推力没算明白,焊缝承受了额外弯矩。设计时只算了轴向推力,忘了侧向风载和地震载荷,焊缝不裂才怪。
第二种:复式铰链横向型膨胀节端部螺栓松动,铰链板移位导致端管卡死。这种问题往往出在振动工况下,螺栓没加防松垫圈,振着振着就松了。
第三种最冤:手动插板式隔绝门和电动插板式隔绝门的端部接口,因为安装时没有留够操作空间,后期维护时板子抽不出来。设计阶段一定要把安装空间和检修通道考虑进去,别等装好了才发现扳手都塞不进去。
给个实实在在的建议:端部结构设计必须结合产品型号和标准
别想着拿一个通用方案去套所有项目。比如你选曲管压力平衡型膨胀节,端部就要承受压力推力平衡机构的重量;选空冷岛真空管道双铰链膨胀节,端部密封结构得能抽真空到多少Pa?这些参数都得在图纸阶段定死。本站产品列表里从橡胶四氟补偿器到套筒式管道膨胀节,每一种的端部设计都有讲究。出了问题再返工?那成本可不止翻倍——工期延误、停产损失,算下来够买好几套设备了。
所以,下次设计补偿器时,先想清楚端部怎么连。连接方式选不对,后面全白费。就这么简单。
先搞清楚:补偿器平面失稳到底长啥样?
说白了,平面失稳就是波纹管在受到内压或者轴向位移时,波纹管不再老老实实地沿着轴线伸缩,而是像拧麻花一样在垂直于轴线的平面里发生弯曲、扭曲甚至整体侧翻。你想象一下:一根原本直挺挺的金属波纹管,突然变成了S形或者波浪形,波纹之间出现非对称的皱褶——这就是平面失稳的典型样子。
这种失稳不是金属疲劳裂纹那种慢慢磨出来的,它往往是瞬间发生的。一旦出现,补偿器基本就报废了,严重时直接导致管道破裂、介质泄漏,甚至整个管系瘫痪。咱们在实际工程中见过的最夸张案例是:水泥行业的水泥行业金属波纹膨胀节在投运不到两个月,波纹管就像被揉过的易拉罐一样彻底拧成了团。
为什么好好的膨胀节会突然“抽风”变成这样?
哪些因素最容易把补偿器推成“平面失稳”?
原因就三个字——压、弯、扭。但细分下来,有几个东西是罪魁祸首:
- 内压太高:压力是平面失稳的直接推手。波纹管在承受内压时会产生环向应力,这个应力会把波纹向外鼓,当压力超过某个临界值,波纹就会失去稳定性。说白了,就像吹气球吹过头了,气球壁开始局部鼓包。
- 轴向位移过大:补偿器设计用来吸收热位移,但如果实际位移量超过设计值,波纹管被过度压缩或拉伸,波纹之间的间距变化过大,也会诱发失稳。你在现场看到那些被压得像手风琴一样褶皱不对称的膨胀节,十有八九是轴向位移超了。
- 安装偏差:这个太常见了。管道中心线对不齐,强行把膨胀节拧上去;或者固定支架没做好,导致膨胀节承受了额外的弯曲力矩。前两天碰到个客户说,他们在电站项目上装了电站行业用波纹膨胀节,结果试压时直接崩了——一查,安装时管道偏心差了两公分。
- 支撑不足:波纹管本身是柔性元件,如果没有合适的导向支架和固定支架,它就会像没骨架的蛇一样乱扭。尤其是那些长波纹、多波数的补偿器,比如通用型波纹膨胀节,如果中间缺少限位装置,平面失稳概率飙升。
平面失稳的计算公式没那么玄乎,关键看这几个参数
很多设计师一提到计算公式就头大,但平面失稳的核心计算其实不复杂。目前工程上普遍采用美国膨胀节制造商协会(EJMA)标准里的公式:
临界压力 P_cr = (0.34 × π × E × t²) / (L_b × D_m²)
其中:E——波纹管材料的弹性模量,t——波纹管单层壁厚,L_b——波纹管总长度,D_m——波纹管平均直径。
看出来了吗?真正决定失稳边界的就是四个参数:材料刚度(E)、壁厚(t)、长度(L_b)和平均直径(D_m)。长度越长、直径越大,临界压力就越低,越容易失稳。反之,壁厚越厚、材料越硬,抗失稳能力越强。
但很多人只套公式,忽略了另一个隐含条件——波距和波高比。实际工程中,波纹管的设计不仅要满足临界压力,还要考虑波数带来的累计效应。比如一个直管压力平衡型膨胀节,如果波数太多,即使单波计算合格,整体也可能失稳。所以业内有个经验值:单波失稳安全系数通常取1.5以上,整体失稳安全系数取2.0以上。
那算出来不合格怎么办?最简单的方法是减少波数或者增加壁厚。但别忘了,壁厚增加会使刚度变大,补偿能力下降。这就是个博弈——你得在补偿量、压力等级、结构尺寸之间找平衡点。
选型不对、安装不到位,算得再准也白搭——实战避坑指南
公式算得天花乱坠,一到现场全白费——这种情况我见的多了。下面几个坑,你最好避开:
- 选型时忽略温度对弹性模量的影响:很多设计师常温下算一遍,以为万事大吉。但电站管道里动辄四五百度的蒸汽,不锈钢的E值会下降30%以上。临界压力也跟着腰斩。所以在高温工况下,选高温轴向型膨胀节时必须用高温下的弹性模量复算。
- 误用拉杆当支撑:有些现场图省事,拿膨胀节拉杆当导向支架用。拉杆只能限制轴向位移,不能抵抗侧向弯曲。平面失稳初期就是侧向弯曲,拉杆根本拦不住。正确做法是安装独立的导向支架,每两到三个波距设置一个。
- 冷紧操作过火:预拉伸或预压缩(冷紧)是为了减少工作状态下的应力,但冷紧量过大,等于初始就给了波纹管一个额外位移。如果补偿器本身设计裕度不足,冷紧直接触发失稳。有个案例是空冷岛真空管道双铰链膨胀节,冷紧量超了设计值20%,投运一周就失稳了。
- 忽视介质腐蚀导致的壁厚减薄:脱硫烟道环境腐蚀性强,如果选材不当,比如用了非金属膨胀节(织物纤维膨胀节)但未考虑酸碱腐蚀,壁厚逐渐变薄,原来算的临界压力就失效了。定期测厚是保命手段。
聊聊电站和水泥行业里那些因平面失稳翻车的案例
先说电站。某300MW机组的主蒸汽管道上装了一台复式铰链横向型膨胀节,设计压力4.0MPa,温度540℃。运行半年后,巡检发现波纹管出现明显的局部鼓包,呈橘皮状。停车检查,发现波纹管已经发生了平面失稳,波纹间距从均匀的10mm变成一边8mm一边12mm。事故原因很典型:设计时用的弹性模量是常温值,没考虑高温衰减;另外,波纹管长度偏长,临界压力算出来只比工作压力高10%,安全系数不够。最后整个膨胀节报废,连带更换了前后一段管道,停产三天,损失七位数。
再说水泥。水泥行业用的水泥行业金属波纹膨胀节经常布置在预热器出口,风管直径大、温度高、含尘量大。有个项目选了单轴双挡板门搭配膨胀节,但膨胀节的导流筒(就是膨胀节导流筒具体的作用里说的那个内衬)磨损严重,导致波纹管直接暴露在高温含尘气流中。粉尘堆积在波谷,破坏了波纹管的均匀受力。再加上管道支吊架间距过大,膨胀节受到额外弯矩,最终波纹管发生了严重的扭曲失稳。现场照片看,波纹管像被揉过的纸团,惨不忍睹。解决方案是改用矩型非金属膨胀节搭配耐磨导流筒,同时增加两个导向支架。
唉,这些教训都是真金白银换来的。平面失稳计算不是纸上谈兵,它直接关系到管道系统的安全性和项目成本。你下次再做膨胀节选型或校核时,别只翻样本,把压力、温度、位移、材质、支撑条件都过一遍,再把安全系数打足——至少能避开80%的坑。
一、为什么非要搞个预位移?不设行不行?
前两天碰到个客户,蒸汽管道上了直埋(全埋)型膨胀节,按图纸装完,开机半小时,法兰处直接崩了。查来查去,问题出在预位移量设定为零——等于让补偿器在冷的管道上直接硬扛热膨胀。预位移说白了就是让补偿器在安装时就提前“吃”掉一部分位移量,让它在工作温度下处于中间位置,避免一侧拉伸到极限,另一侧压缩到死。热力管道设计规范里写得明明白白:计算热伸长量后,预位移量一般取50%左右。但真实工况复杂,50%只是个起点。你不设预位移,等于让波纹管在冷态就处于极限位置,温度一上来,要么拉断要么压溃。所以别问“能不能不设”,问就是等着返工。
二、预位移量怎么算?公式不复杂,但数据别拍脑袋
Δx = α × L × ΔT × K。α是线膨胀系数,碳钢约0.012mm/m·℃,L是管段长度,ΔT是工作温度与安装温度之差,K是预位移系数(通常0.5~0.7)。但别以为套个公式就完事了。旋转补偿器和大拉杆膨胀节对预位移的敏感度完全不同。旋转补偿器本身靠旋转吸收位移,预位移量太小会导致旋转角度超限;而直管压力平衡型膨胀节对轴向位移要求更严,预位移设大了可能把波纹管压出塑性变形。所以,算完理论值,得对照本站产品资料里那篇《波纹管的刚度及计算公式》,结合具体型号的允许位移量再校核一遍。否则你算出来的数,可能正好是波纹管的疲劳极限点,一用就废。
三、不同补偿器,预位移的“性格”差很远
金属波纹膨胀节和橡胶补偿器就不是一回事。橡胶补偿器弹性模量低,预位移量设大了容易鼓包,设小了又起不到保护作用。衬四氟金属软管呢?四氟层本身怕拉伸,预位移必须优先考虑拉伸侧的安全余量。再说说电站行业用波纹膨胀节——高温高压蒸汽管道,预位移量往往要取到计算热位移的60%以上,因为启动和停炉时的温差冲击会带来额外动态位移。水泥行业金属波纹膨胀节则相反,粉尘多、温度波动慢,预位移设到40%就够用,设多了反而容易被积灰卡住。你看,同样叫补偿器,不同场景下的预位移“性格”能差出一倍去。所以千万别拿一个系数打天下。
四、安装现场,预位移到底怎么“调”出来?
纸上谈兵完了,说干活。预位移的执行通常靠拉杆或螺杆。比如大拉杆膨胀节,出厂时螺杆会锁定在预拉伸位置,安装时先把膨胀节压缩或拉伸到图纸要求的预位移量,然后锁死拉杆螺母。这里有个坑:很多人看了本站问答“膨胀节拉杆螺母怎么调整”,以为随便拧几圈就行。实际上,你得用百分表或游标卡尺测量波纹管长度变化,精确到毫米。比方说,通用型波纹膨胀节要求预压缩10mm,你用扳手拧螺杆时,必须同时监控两端法兰间距。别凭手感。另外,电动插板式隔绝门这类设备附近如果有补偿器,预位移还要考虑隔绝门开关时的机械冲击,留出额外裕量。不然关门那一下,预位移直接被打没了。
五、最要命的几个翻车案例,你猜怎么着?
有个电厂用了曲管压力平衡型膨胀节,预位移方向设反了——本该压缩的设成了拉伸。结果运行后波纹管被挤成麻花,直接报废。第二个:一个化工厂选了外压单式轴向型膨胀节,预位移完全照搬理论值,没考虑安装时环境温度是35℃(设计安装温度20℃),等于实际预位移量少了15%左右。两个月后,补偿器端部焊缝开裂。第三个(这个最离谱):有人把非金属膨胀节(织物纤维膨胀节)也按金属的预位移系数去算,织物纤维的蠕变特性和金属完全不同,预位移量过大导致织物层提前疲劳撕裂。所以,别偷懒,每种补偿器的产品手册里都有推荐预位移范围和修正系数,装在口袋里的东西偏偏有人不看。是不是这个道理?
六、总结一条铁律:预位移设定是个“活”,但得按规矩来
没有万能公式,但有基本逻辑:先算热伸长——对照本站的产品资料确认该类补偿器的位移能力边界——考虑安装温度修正——现场用工具精确调整——最后做冷态标记并记录。如果实在拿不准,直接找厂家要设定参数。比如压力平衡型膨胀节、复式铰链横向型膨胀节这类结构复杂的,预位移设定往往和管道应力分析挂钩,不是拧几颗螺丝的事。记住,补偿器选型对了,预位移设定错了,整个系统照样玩完。所以,下次再有人问你“补偿器预位移量设定?怎么搞”,你就把这六个字甩给他:算、对、修、调、记、问。少一步,都可能崩。
先搞清楚:补偿器为什么需要导向支架?不是你想装就能装
很多人觉得,补偿器买回来往管上一焊就完事。啧,真这么简单的话,现场哪来那么多波纹管炸裂、焊缝拉脱的事故?前两天碰到个客户,蒸汽管道上的通用型波纹膨胀节用了不到三个月就漏了,厂家派人一看——导向支架压根没装,管子直接横向摆动把波纹管拧成了麻花。修?修不了,只能换。
补偿器(膨胀节)的核心功能是吸收管道的热位移,但它本身很“软”——波纹管壁厚通常只有零点几毫米到几毫米。如果没有导向支架限制管道的横向位移和弯曲,补偿器会被迫承受设计之外的载荷,轻则失稳鼓包,重则疲劳断裂。说白了,导向支架就是给管道“划跑道”的,让位移只沿着补偿器设计的方向走。
导向支架的布置原则:间距、位置与固定点,一条条给你掰扯清楚
布置导向支架,核心就三件事:距离、位置、固定点设置。咱一个一个拆。
间距怎么定?
对于轴向型补偿器(比如通用型波纹膨胀节、外压单式轴向型膨胀节),第一个导向支架距补偿器端部的距离不应超过4倍公称直径(4DN),第二个导向支架距第一个不超过14倍公称直径(14DN)。再往后,间距可以适当加大,但最大不超过20米(针对小口径)或按管道柔性分析确定。
一根DN300的蒸汽管,导向支架间距直接干了8米,第一个支架离补偿器端部5米远。结果一升温,管道在补偿器进口处弯成了S形,焊口当场撕裂。所以,别拍脑袋,该查表查表,该算就算。
位置怎么放?
导向支架必须设置在补偿器的两侧,并且要保证支架中心线与管道中心线重合。如果支架装偏了,相当于给管道加了个初始弯曲,补偿器还没干活就已经受力了。另外,导向支架不能装在补偿器的波纹段正上方——你得给波纹管留出自由伸缩的空间。对于复式铰链横向型膨胀节这类产品,导向支架的位置还要考虑铰链的旋转中心,通常需要配合限位支架使用。
固定点(主固定支架)怎么设?
固定支架是用来承受管道盲板推力和补偿器弹性反力的。它必须设置在补偿器的两端或者管道方向改变的地方。固定支架如果不牢,整个管道系统会像蛇一样扭动。举个例子:一个DN500的蒸汽管道,压力1.6MPa,温度300℃,盲板推力算下来将近40吨。如果固定支架没用钢筋混凝土基础,而是随便焊在钢梁上,后果自己掂量。
不同补偿器类型,导向支架布置的差异大了去了——以通用型波纹膨胀节、外压单式轴向型膨胀节、复式铰链横向型膨胀节为例
你千万别指望一套支架方案通吃所有补偿器。每种膨胀节的工作机理不同,支架布置逻辑天差地别。
通用型波纹膨胀节
这种膨胀节主要吸收轴向位移,也能承受少量角向和横向位移,但设计上不建议多向混合。所以导向支架必须严格限制管道横向摆动和弯曲。第一个导向支架距膨胀节端面≤4DN,第二个≤14DN,之后每隔≤20米设置。而且膨胀节两端必须各设一个固定支架,防止管道轴向蠕动把膨胀节拉脱。
外压单式轴向型膨胀节
外压型的波纹管在外部压力下工作,稳定性更好,但它对管道导向的要求反而更苛刻——因为外压波纹管的端部是焊接在管道上的,一旦管道发生偏转,波纹管根部会承受巨大的弯曲应力。导向支架的间距要比通用型更密,通常第一个支架距膨胀节端面≤3DN,第二个≤10DN。现场施工时,我建议对外压型膨胀节两侧各增加一个辅助导向支架,别省那几根槽钢。
复式铰链横向型膨胀节
这种膨胀节靠铰链的旋转来吸收横向位移,本身不吸收轴向位移。所以导向支架的作用不是限制横向,而是保证管道在铰链平面内自由摆动,同时限制其他方向的位移。安装时,需要在铰链两侧各设一个限位支架,防止管道扭转变形。而且固定支架必须设置在铰链旋转中心线延伸的方向上,否则铰链会卡死。
现场最常犯的四个错误:导向支架装错位置、间距过大、缺少限位、忽略端部推力
干这行十几年,现场踩过的坑、见过的坑,我列四个最常见的,你看看自己中了没。
- 装错位置:导向支架直接焊在补偿器波纹管上?别笑,真有人这么干。波纹管被支架卡住无法自由伸缩,第一个热循环就开裂。
- 间距过大:前面说了,4DN和14DN是红线。超过这个数,管道失稳概率指数级上升。尤其蒸汽管道,高温下钢材弹性模量下降,更容易弯。
- 缺少限位支架:对于角向或横向型膨胀节(比如复式铰链横向型膨胀节),不装限位支架等于让它“乱晃”,铰链销轴很快磨损,波纹管也随之扭曲。
- 忽略端部推力:固定支架的设计强度必须能承受盲板推力和补偿器刚度反力。很多人只算了盲板推力,忘了补偿器本身的弹性反力。结果固定支架被推歪了,管道位移全部挤到补偿器上,报废。
实战案例:某蒸汽管线导向支架布置翻车现场——怎么调整才合规
去年我处理过一个化工厂的蒸汽管线。管线长度80米,材质20#钢,操作温度280℃,压力1.0MPa,用了4台外压单式轴向型膨胀节。投运一个月,第三台膨胀节波纹管根部出现裂纹。我到现场一看,问题出在导向支架上:第一个导向支架距离膨胀节端面5.5DN(超了),第二个距离18DN(超了),而且固定支架只是用膨胀螺栓固定在水泥地面上,螺栓已经松动。
- 拆掉原有导向支架,重新按3DN(约900mm)安装第一个支架,第二个支架按10DN(约3米)安装,之后每隔12米设置一个。
- 固定支架重新浇筑混凝土基础,预埋地脚螺栓,并校核盲板推力(约25吨)加上外压膨胀节的反力(约3吨),设计载荷取35吨。
- 在膨胀节两端各增加一个辅助导向支架,进一步约束管道摆动。
改完之后,运行半年复查,波纹管完好,焊缝无裂纹。甲方现场经理说:“早知道导向支架这么关键,当初就该让你们来做。” 是吧,有时候省下来的那点支架钱,最后全变成维修费给补回去了。
总结:导向支架不是配角,是补偿器寿命的命门
补偿器导向支架布置这件事,说复杂也复杂——得考虑管径、温度、压力、补偿器类型、现场空间;说简单也简单——记住三个数(4DN、14DN、固定支架推力),然后根据膨胀节样本上的安装说明执行。但最怕的就是“差不多先生”,随手一装,出了事故才后悔。
如果你在布置补偿器导向支架时拿不准,别自己瞎琢磨。翻翻厂家提供的安装手册,或者直接问我们。毕竟,搞错了导向支架,换再多补偿器也没用。
Find out one thing first: what will happen if the number of ripples is more or less?
A few days ago, a customer who makes steam pipes asked me, saying that the steam pipes in their factoryUniversal corrugated expansion jointIt leaked after less than half a year of use. When I removed it, I found several cuts at the root of the corrugation. I asked him how to select the type at that time, and he said, "I just matched a regular one according to the diameter of the pipe, and I didn't care too much about the number of corrugations". Tsk, this is the typical problem-the number of ripples is not determined by patting the head, and if there is more or less, something will happen.
Let's put it this way, when the number of corrugations is small, the displacement that a single corrugation has to bear will be large, the stress will be concentrated, and the fatigue life will fall by a cliff. Especially in high temperature and high pressure conditions, such as those used in power stationsHigh temperature axial expansion joint, the number of ripples is not enough, and it will crack in a few months. Conversely, what about more ripples? You think more is safer? Wrong. If there are more ripples, the overall stiffness will decrease, the pressure bearing capacity will follow, and instability will easily occur-if the ripples collapse like noodles, it will be completely wasted.
Therefore, the question of "calculating the number of compensator ripples?" is not a simple addition and subtraction, but to find a balance between the compensation amount, pressure, temperature and fatigue life. To put it bluntly,Number of corrugationsIt's a lever: it can't bear pressure a little to the left, and it can't live a little to the right.
What does the calculation formula look like? These are the core variables. Don't be scared by the formula
When it comes to formulas, many people have big heads. But don't be afraid,Compensator Ripple Number CalculationThe core logic is actually four variables: single-wave compensation amount, total compensation amount, pressure conversion coefficient and temperature correction coefficient. The formula looks like this:
Required number of corrugations = total compensation ÷ (single wave compensation × pressure coefficient × temperature coefficient)
Simple right? However, in practical applications, the "pressure coefficient" and "temperature coefficient" are the most easily overlooked.
Take the pressure coefficient, aExternal pressure single axial expansion jointThe design pressure is 1.0MPa, and the actual operating pressure is only 0.6MPa. If you calculate according to 1.0MPa, the number of corrugations will be too large, which will increase the cost in vain and reduce the stability. Conversely, if you useDirect buried (fully buried) type expansion jointOn, the pressure of underground pipelines fluctuates greatly. If you calculate according to the average value, then wait for an accident.
The temperature coefficient is more pit. Many customers take the single wave compensation amount at room temperature to set the 300℃ steam pipeline, which is definitely not allowed. At high temperature, the elastic modulus of the material decreases, and the single wave compensation ability will be discounted. Such asMetal Corrugated Expansion Joints in Cement IndustryThe flue gas temperature is often five or six hundred degrees, so it is necessary to use heat-resistant alloy and reduce the temperature, otherwise the calculated ripple number is a paper tiger.
Under different working conditions, the number of ripples must be adjusted-give you a few real scenarios
Desulfurization flue gas baffle doorMatching corrugated expansion joint. Desulfurization flue gas has high humidity and low temperature (generally about 70℃), but contains a large amount of acidic condensate. The number of corrugations should not be too small because additional axial displacement due to fouling is to be absorbed? No, the key is to ensure that the spacing between the corrugations is large enough to avoid corrosion by fluid accumulation. In this case,Compensator Ripple Number CalculationAdd an additional corrosion margin-it is usually recommended to reserve 15% ~20% more corrugation than pure displacement calculation, and choosePTFE-lined hoseOrPTFE compensatorTo resist corrosion.
Double hinge expansion joint for air-cooled island vacuum pipeline。 The air-cooled island pipeline has a large diameter and a negative pressure operation. If the number of corrugations is too large and the stiffness is too low, the vacuum degree will deflate the corrugations. At this time, it is necessary to reduce the number of ripples or increase the wave distance. I have seen a project that used a 30-wave expansion joint, and as a result, once the vacuum was pumped, the troughs stuck directly together. Later, it was changed to a design with 18 waves and increased wave thickness, and it was done.
Corrugated expansion joint for power station industry, the main steam pipe. Operating temperature 540 ℃, pressure 10 MPa. Under this condition, the single-wave compensation amount is only about one third of that at normal temperature. The creep fatigue interaction must also be considered in the selection. The number of ripples is generally calculated by the manufacturer with finite element, so don't pat your head yourself. Before, there was a power plant diagram to save money, and I calculated it by myself according to a simple formula. As a result, the number of ripples was reduced by 30%, and the pipe burst in two months.
What do these examples illustrate? Formulas are dead, working conditions are alive. The same oneCompound hinge transverse expansion jointUsed in thermal pipe gallery and used in chemical pipeline, the number of corrugations may be twice as different.
Selection and Pit Avoidance Guide: Half of these mistakes have been stepped on by customers I have seen
Just look at the total displacement, not the displacement direction. Many people take the total thermal elongation of the pipe and substitute it into the formula, butCompensator Ripple Number CalculationWhen, the single-wave compensation amount is divided into axial, transverse and angular directions. You use an axial expansion joint to absorb the lateral displacement. No matter how many corrugations are, it will quickly distort and break.
Superstition that "the more ripples, the longer the life". Wrong! An increase in the number of corrugations reduces the displacement that a single wave is subjected to, but at the same time reduces the overall stiffness and stability. ForStraight pipe pressure balanced expansion jointThis kind of structure needs to counteract the pressure thrust, the number of corrugations must be strictly controlled. More, the pressure thrust can't be balanced; Less, main bellows overloaded.
Ignore installing pre-stretch/pre-compression. For example, a steam pipe is installed at 20°C and operates at 280°C. If it is not pre-stretched in the cold state, the expansion joint will withstand additional stretching in the hot state. You calculated the number of ripples according to the actual displacement, without considering the amount of pre-stretching, and the result was that the number of ripples was small. The correct way is to deduct the displacement generated by pre-stretching in reverse when calculating the total compensation amount. For example, if pre-stretching is 50%, the total compensation amount will be calculated as 50% of the actual displacement. Can the number of corrugations be halved? No, it can't be halved, because pre-stretching only changes the zero position, and the fatigue life still has to be calculated according to the total displacement-it is easy to be swirled here, so it is recommended to find the manufacturer to confirm.
Mixed formula for non-metallic expansion joints and metallic expansion joints.Non-metallic expansion joint (fabric fiber expansion joint)Andrubber compensatorThe logic of calculating the number of corrugations (actually bands) is completely different, because they depend on the elastic deformation of fabric or rubber, rather than the plastic deformation of metal. You take the formula of metalRubber PTFE compensatorThe result must be wrong.
UnderstandCompensator ripple number calculation?Actually, it's not that mysterious, but you can't be too confident. In case of complicated working conditions (high temperature, high pressure, corrosion, large diameter), it is much more reliable to contact the manufacturer directly to come up with a plan than to calculate it yourself for half a day. We have a library of cases of various working conditions, fromFlue gas baffle doorToSleeve type pipe expansion joint, can be referred to.
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