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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Metal rectangular expansion joint
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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About Us
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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焊接式矩形非金属补偿器:为什么电厂烟风道都选它?
焊接式矩形非金属补偿器到底是什么?它和普通的非金属膨胀节有什么区别?说白了,焊接式矩形非金属补偿器是针对矩形管道系统——比如电厂烟风道、脱硫...
非金属补偿器制作工艺:从选材到成品的硬核拆解
一、非金属补偿器“非金属”到底用的啥材料?说穿了,非金属补偿器的核心就是一层又一层的“布”和“膜”。你别看它叫非金属,里面可没有一块铁皮,但...
耐负压非金属补偿器到底坑不坑?搞懂这几点,选型不翻车
一、什么是耐负压非金属补偿器?跟普通非金属补偿器有啥区别?“你们那个非金属膨胀节(织物纤维膨胀节)能不能用在负压管道上?”说白了,普通非金属...
Frequently asked questions
Answers to your frequently asked questions about compensators and baffle doors
一、高温环境下的“柔性盾牌”:非金属补偿器靠什么耐住几百度?
一说高温管道补偿,很多人第一反应是金属膨胀节。但有个东西叫非金属膨胀节(也叫织物纤维膨胀节),它靠的不是金属波纹管硬扛,而是多层复合结构——硅胶布、氟橡胶、陶瓷纤维毡、玻璃纤维布这些材料叠在一起,形成一道“柔性盾牌”。问高温非金属补偿器的作用? 说白了,就是在几百度的烟气、热风、粉尘管道里,既能密封又能吸收位移,还不怕腐蚀。
耐温极限取决于最里层的隔热层。常规硅胶布做内衬,能扛住250℃~350℃;换成氟橡胶或聚四氟乙烯补偿器那种结构,能到400℃;要是用上陶瓷纤维+耐热合金丝网,长时间运行温度可以冲到600℃甚至短期1000℃。你猜怎么着?电厂脱硫烟道里,烟气温度也就150℃~200℃,但偶尔会窜进高温烟气,非金属补偿器因为是多层柔性,反而比金属更扛得住这种温度冲击——金属波纹管一遇到局部过热可能直接塑性变形,非金属的织物层则能靠烧蚀外层来保命。
当然,不是说温度越高越好。每种材料的最高连续使用温度都有明确数据,选型时得看工况是“持续高温”还是“瞬时峰值”。前两天碰到个客户,把普通硅胶布补偿器用在350℃常开烟道上,结果三个月就脆裂了——那是选材没搞清楚。
二、吸收多向位移和降噪减振:高温管道里最难搞的“热胀冷缩”问题,它怎么解决?
高温管道的麻烦不止是温度本身,更在于热胀冷缩带来的位移。一根几十米长的烟气管,从冷态到热态,轴向伸长几厘米、横向偏摆一两毫米都很正常。金属膨胀节通常只擅长吸收轴向位移,碰到横向或角向位移就得加复杂的铰链或拉杆结构。而非金属膨胀节天生就是“软骨头”——它的织物圈带可以轻松吸收轴向、横向、角向三个方向的位移,尤其适合矩形管道。
一台火电机组的引风机出口烟道,截面3米×2米,温度200℃。如果装金属矩形膨胀节,光制造就要用厚钢板压型,重量几吨,而且只能吸收很小的角位移。改用矩型非金属膨胀节,重量只有金属的1/5,安装时甚至能用手扳动调整位置,运行时低频振动几乎被织物层彻底吸收掉——这就是它降噪减振的硬功夫。
那怎么防止泄漏?结构上一般配两道密封:外层是耐温柔性蒙皮(比如硅胶布),内层是耐腐蚀的氟橡胶或聚四氟乙烯补偿器层,中间再塞满陶瓷纤维保温棉。三重防护下,即使外层烧穿,内层还能顶一阵。所以从原理上讲,高温非金属补偿器的作用? 就是用一个多层柔性“口袋”兜住高温介质的位移和应力,顺便把振动噪音也吃掉。
三、对比金属膨胀节:哪些场景非用非金属不可?选型时别踩的坑
金属膨胀节靠波纹管弹性变形,能承受高压(几十兆帕),寿命长(理论疲劳次数上万次),但缺点很要命——怕腐蚀、怕结晶、对安装对中要求极高。非金属膨胀节承压一般也就0.1~0.3MPa(适合低压烟风道),但耐腐蚀性极强,比如在湿法脱硫后的烟气里,含有大量SO₂、SO₃和冷凝水,金属波纹管几个月就穿孔了,橡胶补偿器或橡胶四氟补偿器却能用上两三年。
哪些场景非用非金属不可?
- 低压大截面矩形管道:电厂脱硫烟道、水泥窑尾废气管道,都是几米宽的非标截面,金属膨胀节根本做不出那么大弹性元件,只能用矩型非金属膨胀节。
- 含腐蚀性介质的管道:垃圾焚烧厂的酸性烟气、钢铁厂的高炉煤气,必须用织物纤维加氟橡胶的复合结构。
- 多向位移且空间受限处:比如管道拐弯处,金属膨胀节需要设置多个铰链组合,非金属一个就能搞定三个方向。
选型时别踩的坑主要是以下几点。第一,别把非金属膨胀节(织物纤维膨胀节)当金属用——它不能承受高压,如果管道内压超过0.5MPa,必须用金属或加限位拉杆。第二,注意介质颗粒磨蚀,如果烟气里带硬质颗粒(如水泥生料粉尘),要给非金属内层加耐磨衬板或导流筒(可以参考膨胀节导流筒的作用)。第三,安装一定要按箭头方向,别装反,否则蒙皮受拉会提前撕裂。
四、用在电厂、水泥、烟气系统里的真实案例——高温非金属补偿器能扛住哪些介质?
说几个实际工况你就有概念了。
案例1:电厂脱硫烟道 某2×300MW机组,湿法脱硫后的净烟气温度50℃~90℃,但含有大量硫酸冷凝液。之前用通用型波纹膨胀节,半年就漏。换成非金属膨胀节(内衬聚四氟乙烯补偿器),已经运行4年没换。介质:SO₂、SO₃、水蒸气、酸性冷凝液。扛得住。
案例2:水泥生产线窑尾废气 温度350℃~400℃,含粉尘浓度高达30g/Nm³。用金属波纹膨胀节?粉尘会卡在波纹里导致疲劳失效。改用矩型非金属膨胀节,内部加耐磨导流筒,粉尘顺着斜板流走,三年没出问题。介质:高温烟气、水泥生料粉尘。
案例3:垃圾焚烧发电厂一次风管道 空气被预热到250℃,管道截面大,需要吸收热膨胀和振动。直接上橡胶补偿器?橡胶受不了250℃。必须用非金属膨胀节(织物纤维膨胀节),内层氟橡胶+外层硅胶布+中间陶瓷纤维,寿命设计15年。介质:热空气、少量腐蚀性气体。
看到没?高温非金属补偿器的作用? 远不止是“温度”两个字,它要同时面对高温、腐蚀、粉尘、振动四个敌人。选对了,它就是管道的“柔性盾牌”;选错了,就是事故隐患。
五、寿命和安装要点:想让它多用几年,这几个细节工程师必须盯住
非金属补偿器的寿命理论上可达5~8年,但实际很多用了两三年就报废,根儿上出在安装和维护。
1. 安装前必须检查管道对中 非金属蒙皮没有自对中能力,管道法兰错位超过3mm,强行固定会导致蒙皮扭曲、局部应力集中。最好用拉杆临时固定,调整到位后再紧固螺栓。
2. 螺栓扭矩不能乱来 螺接面一般采用法兰压板,螺栓拧紧力矩需按产品说明书执行。拧太紧会压坏蒙皮边缘,太松又漏气。建议分3次对角预紧,最终扭矩控制在80~120N·m(具体看型号)。
3. 定期检查导流筒 如果内部有导流筒,那就要看它有没有磨穿。特别是水泥行业,导流筒磨穿后高温颗粒直接冲刷蒙皮内层,几天就能破洞。可以每年停机时用内窥镜看一下。
4. 注意保温层不要压到补偿器 有些现场在管道外包保温棉,结果保温棉直接压在非金属表面,导致热量无法散出,局部温度超标。补偿器外表面必须留出至少50mm的散热空隙。
国家标准JB/T 12235-2015对非金属膨胀节的技术要求写得清清楚楚,选型、安装、检验都要遵照执行。别图省事,也别迷信进口品牌——国产的橡胶四氟补偿器在适应复杂工况上往往更灵活。
说到底,搞清楚高温非金属补偿器的作用? 不是背定义,是理解它“柔性”“多层”“耐腐蚀”的底层逻辑。下一次你遇到高温低压、腐蚀、大截面管道,心里就有数了。
非金属矩形补偿器到底是什么?和金属的有什么区别?
先别被名字绕晕。咱们站里管这玩意儿叫矩型非金属膨胀节,也叫织物纤维补偿器。它跟橡胶补偿器、金属矩形膨胀节完全是三码事。橡胶补偿器靠弹性体变形,金属矩形膨胀节靠波纹伸缩,而咱们今天聊的这个——非金属矩形补偿器,用的是柔性织物蒙皮来吸收位移。简而言之,它就是专门给矩形管道“松绑”的关节件。
那跟金属波纹管比,它到底差在哪?金属波纹管做不了大尺寸矩形——工艺上要么卷板要么冲压,矩形波纹管成本上天,而且承压后应力集中得厉害。非金属这个,反而越是大尺寸越有优势,还能吸收三维位移(上下、左右、前后),顺便把振动和噪音也消了。啧,是不是有点反直觉?
核心结构就仨部件:导流筒、保温层、蒙皮
拆开一个非金属矩形补偿器,你会发现它其实挺直白。最里头是导流筒,一般用不锈钢或碳钢焊接成形,作用是把气流顺顺当当引过去,避免直接冲刷蒙皮。导流筒必须焊牢,不然高速气流一冲,几周就能把蒙皮打烂。中间夹一层保温层,通常是硅酸铝纤维棉或者陶瓷纤维,厚度根据介质温度来定。最外层是蒙皮,这是整个产品的命门。蒙皮用多层复合材料复合而成,常见的有硅胶布、氟胶布、聚四氟乙烯(PTFE)膜,有的还叠了不锈钢丝网增强。耐温等级就看蒙皮——300℃用硅胶布,500℃得上氟胶布加PTFE层。你问为什么不全部用氟胶布?贵啊,而且硅胶布的疲劳寿命更长。选型就是个取舍问题呗。
为什么矩形管道非得用这个?
前两天碰到个客户,电厂脱硫烟道,矩形截面3米×2米,工作温度180℃,压力才几千帕。他第一反应是用金属矩形膨胀节。一询价,厂家报价贵一倍不说,交货期还长。为什么?金属矩形膨胀节必须用多层波纹板叠加,每一层都要冲压成型、焊接,而且大尺寸波纹板容易失稳,得加加强筋。最后他换了矩型非金属膨胀节,造价降了40%,安装也快。你猜怎么着?用了两年,一次渗漏都没出。金属的反而因为焊缝疲劳裂过一回。所以,低压大截面场合,非金属是实打实的优选。
矩形管道热胀冷缩产生的位移量能达到几十毫米,金属波纹管没法同时吸收轴向、横向、角向三个方向的位移。非金属的蒙皮是柔性织物,理论上可以承受任意方向的位移,只要设计时留够余量。再加上织物本身有阻尼作用,能把管道振动衰减掉七八成。噪声测试数据:安装非金属补偿器后,烟道附近噪声降低15dB(A)以上。
选型最容易翻车的三个坑
压力等级。非金属矩形补偿器一般只适合低压系统,0.1MPa以内。超过这个数,蒙皮会被鼓破或者法兰螺栓被拉断。你非要用在0.3MPa的管道上?别想了,换金属的吧。
温度。蒙皮材质直接决定了耐温上限。硅胶布≤300℃,氟胶布≤350℃,加上PTFE层可以到500℃。但注意,复合蒙皮的整体耐温以最低耐温层为准。有的厂家拿硅胶布蒙皮号称耐500℃,那是扯淡。你得问清楚每层材料。
导流筒方向。导流筒通常要插入管道内部,而且必须迎着气流方向焊接。装反了或者焊缝不牢,气流直接冲击蒙皮内侧,几个月就报废。我们见过一个案例:安装时导流筒没焊透,三个月后蒙皮被撕开一条口子,整个法兰面漏气。更换一套非金属膨胀节的人工费比产品本身还贵,何必呢?
维护和寿命:3-5年换皮,成本低但别偷懒
坦诚说,非金属的寿命比金属短。金属波纹管设计寿命一般15-20年,非金属的蒙皮因为老化、磨损,3-5年就得换。但好处是换蒙皮就能恢复性能,不用整个拆管道。而金属波纹管一旦开裂,基本只能整体更换。所以从全生命周期看,非金属反而省钱——前提是你得按规矩维护。
换蒙皮时最容易被忽略的是法兰螺栓扭矩。拧太紧了把蒙皮压破,拧松了漏气。国家标准《非金属膨胀节》JB/T 12235-2015里明确规定了螺栓预紧力范围,比如M16螺栓推荐扭矩100-120N·m。实际操作中,建议用扭矩扳手对角分三次拧紧。还有,旧蒙皮拆下来后,法兰面必须清理干净,残留的胶渣、锈蚀都会影响新蒙皮密封效果。
另外,保温层也要检查。如果保温棉受潮或者结焦,会影响耐温性能。有些项目为了省钱,导流筒用普通碳钢,结果高温下氧化皮脱落堵塞保温层,最后蒙皮局部过热烧穿。你说冤不冤?
所以,非金属矩形补偿器是什么?它是矩形管道系统里专门应对热胀冷缩和三维位移的柔性关节。结构简单、成本可控、安装快,但前提是选型别踩坑,维护别偷懒。你正在选型还是已经遇到问题了?不妨对照上面几点自查一遍。
为啥有人会问这种问题?
说白了,大家印象里非金属补偿器(也就是非金属膨胀节)是给热风、烟气管道用的——比如电站、水泥厂的烟道,温度高、介质脏,金属波纹管扛不住腐蚀,才用织物纤维或者橡胶做的补偿器。可一到水系统,嘿,工地上师傅就犯嘀咕了:这布做的皮囊,泡水里能行吗?于是“非金属补偿器能走水吗?”这问题三天两头有人问。答案?真没你想的那么简单。
先看清楚你手里的是哪种“非金属”
别急着回答“能”或“不能”,先分清楚你手里的是哪种非金属补偿器。咱站上有个产品叫非金属膨胀节(织物纤维膨胀节),主体是多层织物+硅胶/氟胶涂层,设计初衷是耐高温、耐腐蚀性气体,但不耐长期水浸泡——水分子会渗透进纤维层,导致分层、鼓包甚至撕裂。但你要是换成橡胶补偿器或橡胶四氟补偿器,胶料本身就有防水性。尤其聚四氟乙烯补偿器,耐酸碱、耐水,走循环水完全没问题。所以问题不是“非金属”行不行,而是具体材质和结构行不行。
你拿织物纤维膨胀节装到冷却水管上,仨月不到,法兰边上就开始滴水,拆下来一看,内层织物全泡烂了。但同样工况,用橡胶补偿器,用个两三年都正常。是不是这个道理?
走水时盯死三个硬指标:压力、温度、介质腐蚀性
先说压力——非金属补偿器一般设计压力偏低,多数在0.1~0.6MPa之间。你要是拿来接水泵出口搞个2公斤压力(约0.2MPa),那得看厂家给的参数。橡胶补偿器通常能到0.6~1.0MPa,但织物纤维的就悬了。再说温度,橡胶类一般耐温不超过120℃,氟橡胶能到200℃,但水系统里常见的是常温到80℃,基本都扛得住。最后是腐蚀性,纯水没问题,含氯离子或酸碱的废水就得选衬四氟或者专用橡胶。比如脱硫废水管道里有时会用橡胶四氟补偿器,因为它既能耐稀硫酸又能抗磨损。
说起来,前两天碰到个做暖通的朋友,想给空调冷却水管装非金属补偿器,理由是金属波纹管太贵。我直接泼了盆冷水:冷却水管道温差不大、位移量小,用单球橡胶补偿器完全够用,但你要是买成普通的织物纤维非金属膨胀节,用不了仨月就得漏。他反问:“那网站上的矩型非金属膨胀节能不能走水?”——矩形通常配烟道用,你要是非要用在水箱进出口也不是不行,但得定制内衬橡胶层,不然织物吸水后重量翻倍,法兰螺栓都吃不消。
那到底能不能走水?
说到底,非金属补偿器能不能“走水”,得看它具体是哪种“非金属”。橡胶类、四氟类的,走水是本职工作之一(前提是压力和温度匹配);织物纤维类的,尽量别碰水,实在要用必须跟厂家沟通做防水内衬。别自个儿拍脑袋,选错了轻则漏水停机,重则整个管道系统跟着遭殃。
如果你拿不准,直接翻我们站上的橡胶补偿器和聚四氟乙烯补偿器页面,或者打个电话问问技术,比瞎猜靠谱多了。毕竟,花几分钟搞清楚,比花几千块换设备划算,是不是?
What exactly is a non-metallic compensator? What is the essential difference with metal corrugated expansion joint?
Non-metallic compensators (also called fabric fiber expansion joints and non-metallic expansion joints in the industry) are not the same thing as our common metal corrugated expansion joints. The core materials of non-metallic compensator are flexible non-metallic materials such as high-temperature-resistant coated fabric, rubber and polytetrafluoroethylene, which are made into a soft joint. The metal corrugated expansion joint absorbs displacement by elastic deformation of stainless steel corrugated pipe. Different ways, application scenarios are naturally different.
For example, the metal corrugated expansion joint is like a tough guy, which can carry high pressure, but it is afraid of corrosion and fatigue. The non-metallic compensator is like a master of jiu-jitsu, which can't bear high pressure, but it is resistant to high temperatures, corrosion, and can absorb large displacements in three dimensions. You're asking tough guys to do jiu-jitsu work, isn't it realistic? The other way around is the same.
Why can it gain a firm foothold in the harsh working conditions of high-temperature flue duct, power plant desulfurization and cement kiln tail?
Resistant, big and good.ResistanceHigh temperature-the ceramic fiber layer can withstand more than 1000℃;ResistanceCorrosion-Polytetrafluoroethylene or acid-resistant rubber layer directly attacks acidic gas;LargeDisplacement-Rectangular non-metallic expansion energy saving absorbs displacement in X, Y and Z directions at the same time, and metal parts can often only absorb axial or transverse directions. In addition, the vibration reduction effect is first-class. If the fan inlet and outlet pipes are installed with it, the vibration can eat more than half.
In the desulfurization flue of power plant, although the flue gas temperature is not high, it is heavy in moisture and contains acidic condensate. It won't take long for the metal corrugated expansion joint to be pitted and perforated. Replace it with a non-metallic expansion joint (such as this station'sRubber PTFE compensatorOrNon-metallic expansion joint (fabric fiber expansion joint)), the inner layer is tetrafluorine acid-resistant, and the outer layer is fiber insulation, which is still intact after three or four years of use. Is that the truth?
The shortcomings are also obvious. Don't treat it as a panacea
Non-metallic compensators are not without drawbacks. The pressure capacity is pitifully low-generally no more than 0.1MPa, that is, just over one atmosphere. If you use it on a steam pipe or high pressure oil pipe, it will explode in minutes. In addition, it is afraid of sharp objects scratching, and it is easy to leak air if the flange surface is uneven during installation. In terms of life, the fiber and rubber layers will age, but according to JB/T 12235-2015 standard, the design life of regular manufacturers can cover the overhaul cycle of the unit (usually 3~5 years).
Two days ago, a cement factory purchaser spat with me, saying that the metal expansion joint in their kiln tail pipeline cracked in less than a year, and it was annoyed to death after several changes. I suggested that he replace it with a rectangular non-metallic expansion joint with a temperature of about 800 ℃ and a composite layer of ceramic fiber + silicone cloth. And guess what? Used it for more than two years without any problems. Therefore, everything is easy to say if the selection is right.
Focus on these four parameters when selecting
- Design temperature: Look at the resistance temperature of the fabric layer. For example, ceramic fiber can reach 1260℃, but the actual use should leave a margin.
- Working pressure: Non-metallic compensators are mostly used in low-pressure smoke ducts, and don't think about them if they exceed 0.1MPa.
- displacement amount: The three directions of X, Y and Z should be calculated clearly. Metal parts can be calculated as transverse axial, and non-metals can be calculated as three-dimensional.
- Media composition: The desulfurization flue gas has a large moisture content and acidity, so acid-resistant PTFE or rubber materials must be selected, such as this station'sRubber PTFE compensator。 If the cement kiln tail contains alkaline dust, then alkali-resistant coating must be used.
The national standard JB/T 12235-2015 has clear test methods for fatigue life and air tightness.
When should you choose a non-metallic compensator?
Low pressure, large displacement, high temperature, corrosive mediaOccasions, preference is given to non-metals. Specific scenarios include: the pipelines in front and behind the desulfurization flue gas baffle door, the inlet and outlet of the fan in the cement industry, the flue of the power station boiler, the air-cooled island vacuum pipeline-and so on. The air-cooled island vacuum pipeline is commonly used thereDouble hinge expansion joint for air-cooled island vacuum pipelineBut that's because the vacuum condition requires a metal seal. As for the Smoke Wind Dao, it is basically a world of non-metals.Flue gas baffle doorOrDesulfurization flue gas baffle doorUsed together, seal and compensate in one step.
Conversely, if high-pressure pipelines (such as main steam), oil media, or occasions where frequent pressure is required, honestly use metal corrugated expansion joints, such as this station'sUniversal corrugated expansion jointOrHigh temperature axial expansion joint。 Don't think about non-metal saving money and hard on it-if you choose the wrong one, it will be more expensive to repair it later than to buy a new one, and the gain will outweigh the loss.
So how about non-metallic compensators? Bottom line: Use it in the right place is an artifact, and use it in the wrong place is scrap metal. Understand your own working condition parameters, and then compare the above points, and basically don't step on pits in the selection.
Splash cold water first: No standard answer
The pressure resistance of metal expansion joint is never a fixed value. It is linked to the corrugated material, the number of layers, the wall thickness, the presence of reinforcing ring, the working temperature and the diameter. You ask "maximum withstand voltage", just like asking how fast a car can go-can Ferrari and Wuling Hongguang be the same? There are general-purpose corrugated expansion joints and large-diameter thick-walled expansion joints in this station. The latter is specially designed for high-pressure scenarios, and the pressure level differs by several orders of magnitude. Two days ago, I met a customer, and he said, "Give me a DN200 expansion joint that can carry 10MPa". I said you should tell me the temperature, what the medium is and how big the displacement is first, but he was still impatient. As a result, steam pipeline, 500℃, 3.5MPa, guess what? Choose a corrugated expansion joint for power station industry, and the conventional design pressure of 2.5~6.4MPa is enough. If it is hard to 10MPa, the fatigue life will directly cut to the ankles.
Core parameters affecting withstand voltage
Corrugated material is the first threshold. The allowable stress of 304 stainless steel is about 137MPa at room temperature, which is slightly higher than that of 316L. However, at 600℃, Inconel 625 can still maintain its strength, and 304 is already as soft as noodles. Number of corrugated layers-the compressive capacity of single layer is limited, and multi-layer corrugation can distribute stress through interlayer friction, but at the cost of increasing stiffness and poor ability to compensate displacement. The wall thickness from 0.5mm to 2.0mm, with every increase of 0.5mm, the withstand pressure can be increased by about 30% ~50%, but the fatigue life may also be decreased, because the thick-walled corrugation is more likely to produce stress concentration in the trough. The reinforcement ring, to put it bluntly, is to add a hoop between the corrugations to prevent excessive deformation of the trough, which is almost necessary under high pressure conditions.
Medium temperature is a hidden killer. The yield strength of the material decreases by 20% ~30% for every 100℃ increase in temperature. For example, the single-layer corrugated expansion joint of DN200 can carry 1.6MPa at room temperature, but may only leave 1.0MPa at 400℃. You select the model according to normal temperature, and the expansion joint will bulge directly when the scene runs at high temperature. If this account is not clear, the design will be in vain.
Which products of this site can carry high pressure?
Corrugated expansion joints used in power station industry, with a common design pressure of 2.5MPa ~6.4MPa, are specially matched for steam pipelines and steam turbine units in power plants. Stainless steel or Inconel are mostly used as materials, and some have lining cylinders and guide cylinders. Large diameter thick-walled expansion joint, the wall thickness is more than 3mm, plus multi-layer corrugation and reinforcing ring, the maximum can reach 10MPa or even higher. In addition, there is a kind of artifact-external pressure single axial expansion joint. Structurally, the bellows is placed outside, so that the medium pressure can resist a rigid inner cylinder from the inside. The bellows only bears the bending stress caused by axial displacement, and does not directly bear the internal pressure. Therefore, its pressure resistance is much stronger than that of ordinary internal pressure expansion joints. But don't think that high pressure is invincible-the higher the pressure, the shorter the fatigue life, which is a dead hole.
The game between pressure resistance and fatigue life
You have to let the expansion joint carry 10MPa, OK, but the number of cycles may drop from 10,000 to 2000. In actual engineering, many customers ask "What is the highest resistance?" I usually ask: "How long do you plan to use it?" Under high pressure conditions, the material is prone to cracks in the trough stress concentration zone. A real case: A high-temperature and high-pressure pipeline in a chemical plant selected an expansion joint with a pressure of 8MPa, but it leaked in half a year. Check the reason, the design pressure is 5MPa, but the pressure fluctuates frequently during actual operation, starting and stopping once a day, and the fatigue life is only enough for 300 cycles. Later, the external pressure single axial expansion joint was changed, and the pressure level was reduced to 4MPa, but the life time was increased to 10,000 times, and there was no problem after three years of use. When selecting a model, you should balance design pressure with life expectancy, rather than staring at a number.
Selection suggestion: Don't pat your head
First, clarify the working pressure, temperature, medium and displacement-for example, for steam pipelines, the temperature is 500℃ and the pressure is 3.5MPa at full load, so you have to use a high-temperature axial expansion joint or a special model for power stations, and check the fatigue life. The best way is to send the working condition parameters to the manufacturer and let them calculate. The rotary compensator and double hinge transverse expansion joint of this station also have their own applicable scenarios. Don't take high pressure as the only standard. The rotary compensator is suitable for long-distance directly buried pipelines, and the double hinge transverse expansion joint can absorb lateral displacement and angular displacement, but their pressure resistance is generally not as high as that of large-diameter thick-walled expansion joint. If you are in the cement industry, the flue gas pipeline has high temperature and dust, and the metal corrugated expansion joint in the cement industry is lined with wear-resistant lining. Pressure resistance is not the main contradiction, but wear resistance and temperature resistance are. In summary, what is the highest pressure resistance of metal expansion joints? Ask about design life and working conditions first, then talk about pressure.
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