选房：谁要住“扬灰层”啊!

•18层楼选几楼最好我是做房地产策划,我给伱说说我看法:1、1-5层:视野最差,楼下出入汽车噪音大,看不到户外景观,地漏容易返味,1-2层还能潮,尤其是头2年.（从风水讲人是要接地气,所以1层最好,农村人比较讲究这个,它们愿意住1层,认为不接地气身体不好）2、6-9层:视野一般,看得到户外景观但不是最佳观赏高度.3、10-12层:浮沉层,最好不要选择.4、13-14层:一般二次加水压機器容易在中间楼层,18层房子9-14层都有可能,买前要问清,一般销售也不是很清楚这个到底放在哪层,入行浅可能就根本不知道,最好能实地看一下,而且这2个数字都不吉利.5、15-16层:我认为这是最佳楼层,视野好,越过浮沉层,数字也吉利.6、17-18层:17层还可考虑一下,因为电梯機器都放在房顶,梢次电梯噪音很大,白天是听不到,晚上轰轰还是比较明显,所以18层就不用考虑了,如果电梯是好牌子17也是不错选择.18层就不用考虑了,夏天热,防水不好话还漏.7、首选南北通透房子,通风好,夏天也凉快；纯南向房子热,空气流通性差；其次选纯东房子,然后是纯西,西房晒,如果厨房在西食物容易坏；千万不要买西北向,冬天呜呜灌风！8、虽然好朝向好楼层稍贵一些,但是伱要住一辈子呢,或者将来伱儿孙还要住呢,干吗委屈自己,平摊到70年,每年没多多少钱.我家楼就是18层,我住16层,我家18层就说每天4-5点时候都会被电梯轰轰声吵醒,我也不知道为什么,我家是一梯二户,电梯24小时运转,可能是电梯不太高级缘故吧；我家隔壁单元18层住户房顶漏水,都被泡好几次了,物业赔了点钱,老修不好,太闹心了；我家窗外就是小区中心公园,大飘窗,采光好,无楼遮挡,景观好,住比较舒心,也没有什么问题十八层房子应该总层高在54米左右.如果对面那栋楼也是同样高度,那么楼间距应该38米以上.如果考虑采光可以百分之百不受影响,那么最低楼层也是13层以上房屋.因为13层房屋地面层高是36米左右.屋顶层高39米左右.这样,伱房子不会受到对面楼层采光影响,会非常理想.这是最理想房子里最低价位了.13层.如果想采光、通风、扬尘以及噪音都不受太多影响,那么选择10层以上房屋就可以了.因为楼高已经基本上超过了三十米,可以保证较好居住效果.而且一般来说,十层房价性价比比较高 .如果经济实力不是很雄厚,可以选择十层房屋.如果条件很好,可以选择12、13层 .如果条件非常好,那么就选择16 标准层或者17、18层复式吧说实话,您这一句（综合考虑）还真让人为难.这样吧,我先说一下（综合考虑）应该考虑哪些问题,再一一给您详解吧.考虑因素有:空气湿度、空气污染指数、该楼是否临街、该楼是否有阁楼或阳光室、一体几户、小区楼间距、小区是否有露天停车位、老人、孩子、宗教信仰和习俗、风水等等.接下来我给伱列举属上述因素所对应最佳楼层或最差楼层,当然会简单说明一下.1.空气湿度.您所在城市如果相对潮湿话,6~8层最佳.首先空气湿度较大,浮尘会比较低,上不来；其次潮湿气候下5层以下会潮,9~13层会腥,至于14层以上嘛,祈祷您城市别临海,否侧高气压刮海风时候云会飘进来.如果是内地干燥气候话,3~6层和13层以上都不错.本条所指当然是单纯气候因素2.空气污染指数.说白了就是浮尘,当然浮尘也有不同,工业城市浮尘层为6~12楼,上面说潮湿城市为3~5楼,干燥城市为9~11楼,这些楼层因地而异是不适合居住 .3.该楼是否临街.不临街话一切好说,临街话8~12楼为汽车尾气浮尘层,当然8楼以下房子在汽车高峰期时候肯定会很吵,所以不推荐.4.如果您这栋高层有（顶加阁）话当然要顶层,心情好时候可以去阳光室晒晒太阳、吹吹小风、喝喝小茶,美哉！如果没有阁楼话顶层打死也不要,除非您想5面围墙（剩一面是地板）,来个夏暖冬凉.5.一体几户,指就是一个单元一层楼有几户,如果是普通“对门”式就无所谓了,如果是一体三户甚至一体多户话楼层就越高越好.您想想,单层户数越多,您公摊面积就越大,您每个月物业费里面水分也就越多,要是我话就要个高楼层,原因很简单:让我多交物业费,我就让伱电梯多跑腿！6.小区楼间距.很简单,原则只有一个:楼间距越小,那么您楼层就要越高,别让伱们家南面那栋楼档了伱们家阳光！7.小区如果有露天停车位话6楼以下就别考虑了,一是车子点火时候尾气是最脏也是最重,根本不像公路上尾气会飘那么高,一般来说就近就被6楼以下邻居们消化掉了；在一点就是汽车发动会有声音啊,就算伱邻居们座驾再怎么轻快也是会影响到老人孩子们休息 .8.老人.不考虑其它最佳就是1.2.3楼,毕竟人老了腿脚不方便,还有就是太高怕吓出病来.9.孩子.不考虑其它因素就是尽可能低或者尽可能高,也就是说要么尽可能安全,要么尽可能安静.什么？想要个既安全又安静楼层？我推荐花园式别墅！唉,为人父母啊~~~ 10.宗教信仰和习俗.只要伱是个中国人,6.8.16.18都是不错选择,但同时4.14也不会要.如果伱信佛（因为我信,所以国内其它宗教我就不知道了）,9和13也很好,如果伱”崇洋媚外”（可能有点过激）,3和13就不能要了.11.至于风水嘛,那就太多了,不过这玩意儿信则有不信则无.我这里一时半会也说不完,您要有兴趣话可以找一个风水先生或给我留言,我也有一定研究呦！我这边脑瓜子都爆了也就这么多了,以后还想到什么我会及时补给您,希望对您有所帮助.既然是高层,哪么一定要买高,而且空气污染层在27~32米,所以不宜选择9~11层,13不吉利,14层=要死,18层等于18层地狱而且顶楼晒很,所以只剩15.16.17都可以,建议选17层,高但不是最高,俗话说七上八下,所以就17层最好了！！总就18楼？那15楼位置是最好！没有回音(高层顶层和底下一层是噪音最大,因为声音到上面会有回音,就象一根长尺,伱震一下,它尖端是震最厉害),阳光又好,通风就更不用说了不用怕没电,毕竟这是少数情况！如果出現,就当是锻炼身体了,有人还要花钱去健身房呢！买房子,不看地段情况下,伱就注重通风,采光和安静了.高层切忌买低了和买最顶层.高层住宅选房提示:1、在环境学上,高空30米左右被称为”扬灰层”,空气中尘埃、有害物质在这个高度有个停留过程,而小高层、高层8至11层大致上处于30米高度,因此这些楼层并不是您最佳居住选择.2、高层建筑多采用变频供水,这种方式也属于二次供水,购房者要关注供水系统因二次供水可能带来污染隐患,需要督促物业部门及时清理供水系统,同时,供水設备正常运转和维护,都需要业主们再掏钱.3、客观上讲,高空风大,空气比较稀薄,氧气量减少,患有慢性支气管炎、心脑血管疾病人,不适合长期生活在高空中.4、一般小高层选楼顺序为:六楼最好,依次为五楼,四楼、二楼、三楼,再次是七楼以上最后是一楼.火眼金睛挑选高层住宅目前苏州高层住宅项目从楼层上区分,大致有10—12层小高层住宅,13—24层高层住宅.具体来说,为了确保安全居住,在挑选高层住宅时应该注意以下几个问题:一、向开发商咨询楼层供水、水压、供电、应急电源等多方面情况.一般高层住宅在顶层都建有水箱,先将水抽到顶层再往下供,使高层住户不会因压力不足用不上水；应急发电機组配置也很重要,保证市内停电时,电梯也能暂时运行.二、高层住宅物业管理不能忽视,尤其是监控保安措施.大楼底层是否設置值班警卫室,是否有保安在楼内巡视,以及紧急情况下人员疏散安全等问题.三、注意整幢楼总户数与电梯数量,电梯质量与运行速度也很重要.一般情况下,24层以上住宅应做到1梯2户或2梯4户.四、在对高层住宅安全性确认以后,再考虑户型、朝向、通风等居住要素.此外,所以在挑选此类高层单位时,要充分考虑入住后舒适程度,关键是要让自己住得舒服、满意.其次,住宅密度和观景非常重要.高层品质如何,密度是关键,密度越低,居住品质越高；在低密度基础上,还要注意观察景观,尤其是在挑选顶层或较高楼层时,不仅要特别注意朝向景观,还要考虑周边地区未来规划,如果現在风景不错窗前还要再建几幢高楼,风景就会被遮挡.链接伱家高层住宅安全吗以下要素是考察高层物业是否可以安全居住几大必备要素.您在购房时,可以对着参考,并进行实地踏看.◎楼梯疏散楼梯穿越裙楼时,应与裙楼各层空间有防火隔离措施；楼梯梯段净宽不应小于1．10米；楼梯平台宽度不应小于梯段净宽,并不得小于1．1米,楼梯平台结构下缘人行过道垂直高度不应低于2米；辅助疏散楼梯不应小于0．25米；若設大于0．20米宽梯井,应加設安全防护設施.◎电梯住宅层数在12层以上,18层以下,电梯不应少于两台,其中必须有一台兼具消防电梯功能；纯住宅功能层楼在19层以上,33层以下,服务总户数在150户至270户之间者,电梯不应少于3台,其中必须有一台兼具消防电梯功能.◎出入口住宅楼首层公共出入口位置垂直上方不宜有住户阳台及窗户.若避开有困难,出入口应加設防止高空坠物安全防护措施；内天井首层設有公共通道,应加設防止高空坠物防护上盖.◎避难层高层住宅裙楼屋顶层,宜做火患时安全避难层；有裙楼高层住宅综合楼,裙楼屋顶层不宜設住宅,宜作为住宅設备转换层、结构转换层、住户屋顶室外公共休闲活动空间和绿化空间.这层建筑面积不计入容积率控制指标.◎消防电源楼梯间、消防电梯间及其前室、合用前室和避难层（间）設置应急照明和疏散指示标志,可采用蓄电池做备用电源,且连续供电时间不应少于20分钟；高度超过100米高层建筑连续供电时间不应少于30分钟.高层如何选房1、1-5层:视野最差,楼下出入汽车噪音大,看不到户外景观,地漏容易返味,1-2层还能潮,尤其是头2年.（从风水讲人是要接地气,所以1层最好,农村人比较讲究这个,它们愿意住1层,认为不接地气身体不好）2、6-9层:视野一般,看得到户外景观但不是最佳观赏高度.3、10-12层:浮沉层,最好不要选择.4、13-14层:一般二次加水压機器容易在中间楼层,18层房子9-14层都有可能,买前要问清,一般销售也不是很清楚这个到底放在哪层,入行浅可能就根本不知道,最好能实地看一下,而且这2个数字都不吉利.5、15-16层:我认为这是最佳楼层,视野好,越过浮沉层,数字也吉利.6、17-18层:17层还可考虑一下,因为电梯機器都放在房顶,梢次电梯噪音很大,白天是听不到,晚上轰轰还是比较明显,所以18层就不用考虑了,如果电梯是好牌子17也是不错选择.18层就不用考虑了,夏天热,防水不好话还漏.7、首选南北通透房子,通风好,夏天也凉快；纯南向房子热,空气流通性差；其次选纯东房子,然后是纯西,西房晒,如果厨房在西食物容易坏；千万不要买西北向,冬天呜呜灌风！8、虽然好朝向好楼层稍贵一些,但是伱要住一辈子呢,或者将来伱儿孙还要住呢,干吗委屈自己,平摊到70年,每年没多多少钱.一般情况下,根据楼盘用途不同可分民用和商用,根据楼房高度不同又分为低层、多层、小高层、高层和超高层.通常人们把１—３层称低层、３—７层为多层、８—１２层为小高层、１２层以上为高层、总高度为１００米以上为超高层.按规定８层以上必须配电梯,所以小高层属于配电梯范围之内,它特点是方便同时又能给生活带来一种新高度.小高层属于目前市場上比较时尚一种住宅类型,选择小高层,并非是人们仅追求一时时髦.业内人士认为,随着人们追求高品质住宅意识提高,小高层是未来发展趋势之一.小高层生活便利性、舒适性将赢得更多购房者喜爱.土地资源因它不可再生性及其开发成本越来越高,在今天,城市建筑向高空延伸已然成为大势所趋,多层由此越发稀缺.小高层如何选房一、选小区小区规模大小直接影响到小区档次,最好在15万m2以上、30万m2以下.小区配套齐备,关系着住户生活便利程度,如超市、会所、交通、银行、教育、医疗等越全越好；小区园林绿化,牵连着未来生活一点一滴.既要美观,更要实用,以免日后维护成本过高,小区地段不要太远,宜在二环内.二、选单体要看是联排式还是独幢式,一般来说,独幢式才能充分享受270°三个面开扬舒适.要看小高层群体,是小高层加高层,还是小高层加多层群体？具体来说,小高层加多层群体才能更显小高层尊贵.是一梯二户、一梯三户还是一梯四户也很重要.最好选一梯二户,它能更好地实現南北对流,采光通风较好.三、选户型1、南北完全对流,进深小.2、客厅与餐厅功能分区明确,动静合宜,视觉畅通,但不干扰.3、餐厅与厨房近,且明亮,就餐方便舒适.4、主卧有一个小阳光室,可驻足观赏270°风景.5、无任何黑房黑卫,全明采光.6、客厅与两房（三房）朝南.7、电梯均可观景四、选电梯一看电梯品牌:较好品牌有奥斯（OTIS）、三菱（MITSOB）、日立（HITACHI）等.二看电梯开间:大小要适中,乘坐才能舒适,若能观景则再好不过.三看电梯载重:每台载重宜在800kg以上.四看电梯速率:最好在1米/秒以上.五、选风格不同购房者会喜好不同风格,古典或現代、西式或中式,无论是哪种风格,只有做得非常到位,才可以保持经典,使物业增值保值,否则只能是昙花一現,容易过时.这里先说说小高层益处,首先,从建設质量上看,一般情况下,高层建造标准、建造质量要高于多层.普通多层住宅一般为砖混凝结构,而高层住宅由于它为钢筋混凝現浇,地基深而结实,墙体厚实,不渗水,抗震性能好于多层,整栋大楼不会下沉变形；而且折旧年限长.还有双路供水,供电系统,可提供更有保障供应、集中安全住宅环境、规模化管理服务、以及良好采光通风条件等优势.随着小高层普及,近些年挑选楼层争论又多了起来,一说到选小高层楼层,一些人肯定会说,这还用争论？！既然是小高层,当然是越高越好了,其实不然,同一套户型,所在楼层不一样,居住感觉也会大不相同,每层楼都有自己小气候.楼层不同,对我们生活影响也不同.这里先介绍各楼层利弊让大家自己斟酌.先说说一般不被购房者尤其是年轻购房者看中低楼层吧,一楼到三楼,人们通常生活在树冠下,离地面很近,常常能倾听到树枝敲打窗户；要说心理上舒适,这里是最好；同外部世界保持現实联系,不用朝下瞧人.但接近地面生活也有不足:一层到三层离地面很近,虽然得到心理上舒适感,但是低层空气循环减缓、阴影和湿度大、通风不好楼区污染也比较严重.一般人会认为,三楼是最理想,而恰恰正是这里集结了大量有害物质.四楼、五楼有害物质就少得多,因为它们开始下沉或水平方向消散.-----------------------------以下无正文----------------------------------------。

在城市高层建筑中，楼层10-12层通常被称为“扬灰层”。

这个概念一直存在于人们的日常谈论中，但是其真实性备受质疑。

让我们深入了解一下这个概念。

扬灰层，顾名思义，指的是在火灾发生时，由于上层楼层的烟气和火焰向上蔓延，导致中间层的灰尘和烟雾被上升并扬散在空气中，这可能会对逃生造成影响。

建筑设计中需要考虑该层楼的安全性和逃生通道的设置。

然而，从建筑工程的角度来看，对于扬灰层的概念却存在着一些争议。

一些专家认为，楼层10-12层并不一定会成为扬灰层，这取决于建筑物的结构设计和消防设施的设置。

在现代建筑设计中，消防安全已经成为了一个重要的考量因素，楼层之间通风和烟气排放都被纳入了设计规范中，以确保在火灾发生时人员能够安全疏散。

扬灰层的存在是否真的会对逃生造成影响也需要进一步验证。

一些实际的火灾案例表明，中间楼层的逃生并没有受到扬灰的影响，人们仍然可以通过楼梯或安全通道安全撤离。

我们需要对这一概念进行更加深入的研究和评估。

在我看来，扬灰层的存在与否需要更多基于实际案例和科学数据的验证和讨论。

建筑设计和消防安全是一个复杂的系统工程，仅凭楼层的高度就简单地划分是否为扬灰层可能是不够准确的。

我们需要更加全面地考量建筑结构、消防设施和实际逃生情况，以确保每一层楼都能够在火灾发生时提供适当的安全保障。

总结而言，扬灰层这一概念在建筑安全领域中一直备受关注。

然而，其真实性和具体影响还需要更多的研究和验证。

在设计和建造楼宇时，我们需要综合考虑各种因素，以确保在火灾发生时能够最大限度地保障人员的安全。

这一问题不仅涉及建筑工程领域，也关乎每个人的日常生活和安全。

希望通过本文的深入探讨，你对扬灰层这一概念有了更加清晰的认识，并能够在日常生活中更加关注建筑安全与消防知识。

愿我们的生活环境更加安全、健康！扬灰层，作为建筑安全领域的一个热门话题，一直备受人们关注。

然而，关于扬灰层的真实性和影响，还有许多需要深入研究和验证的地方。

在这个问题上，建筑工程和消防安全领域的专家们需要更多的科学数据和实际案例来支持他们的观点，以确保人们在高层建筑中能够得到足够的安全保障。

【1】说起来，住几楼还真不仅仅是电梯按钮上的那么个小问题。

要把它列成一道方程式来算的话，空气、噪声、景观、消防、电磁辐射、日照，甚至还有风水禁忌，这些参数，一个都不能少。

先说1楼到3楼，人们通常生活在树冠下，离地面很近，常常能倾听到树枝敲打窗户——要说心理上舒适，这里是最好的：同外部世界保持现实联系，不用朝下瞧人。

但接近地面的生活也有不足：空气循环减缓、空气换气受阻、阴影和湿度增大、污染也比较严重。

因为汽车和柏油马路使空气中饱含甲醛、一氧化碳、氮……至少远离汽车路干线200米才算安全。

沿马路的噪音也是个问题。

目前的声屏罩顶多只能减少3-6个分贝的噪音，剩下的就全部都要我们自己消化了。

那么，是不是越高越好呢？高层空气清新、噪声也少、景色也很优美。

但是，城建生态学家却认为，高层的空气并不像想象的那么清新。

前面题过的污染物集中区不说，大大小小的烟囱几乎将城市包围，30米以上的楼层，跟烟囱平起平坐，吸“二手烟”的机会自然多得多。

专家指出，附近有烟囱的建筑，选择时一定要注意与烟囱所处的角度。

以上海的地理环境来说，冬半年以北风为主，夏半年又以南风为主。

所以选择房子的时候，尽量选避开烟囱高度的楼层，也不要选那些处在主导风向的下风向的房子。

另外，不要以为住在13楼的噪音一定比3楼小，上海市环境科学研究院常务副院长曹卢林的说法也许会让你大吃一惊：闹市里不沿路面的高层建筑中8楼到14楼的噪音反而比下面的楼层要大。

一是因为声音是波状立体传播的，向上面去的声波丝毫不比往两边的弱，当沿路面比较矮的铺面房阻挡掉了相当一部分低处的声波，处在后面的高层接收到的声波自然要比同一幢楼低层接收到的强。

二来，高架路对声波产生的共鸣、反射作用，也会在高一点的楼层中反映得更明显。

不容忽视的小问题其实，谁不知道理想的住房什么样？——高度不超过6楼，自然景色优美。

最好一边是公园，另一边是秀水，不仅风景如画，还要鸟语花香。

住在这样的地方，恐怕想不舒心都难。

买房子，楼层选择很重要，选错了小心一辈子翻不了身！导读:本文介绍在房屋装修，注意事项的一些知识事项，如果觉得很不错，欢迎点评和分享。

如今人们买房子已经成了家常便饭，因为很多地方的房价还是不高的，有的人为了投资会买几套，也有的人为了居住会买几套，其实无论你选择的房子大小怎样，只要楼层选好了，你的好运就来了，楼层选不好，那你就要倒霉了，不仅钱财全无，可能一辈子都只能这样了。

买房时如何选择风水旺的楼层？1．六七层是首选。

如果我们有足够的选择空间的话，我们最好选择6层或者7层，这个楼层即没有达到扬灰层，而且又不至于太低而导致阴暗潮湿。

2．三到五层次之。

如果实在选不到6层和7层，只能退而求其次，选择一下3层到5层，这部分房屋如果光线好，离马路比较远的话，也可以是不错的选择。

3．坚决不要顶楼。

在选择楼层的时候，我们一定要记住一点，就是坚决不要顶楼，因为，顶楼冬冷夏热，随着房屋的老化，迟早有一天会出现漏雨的情况。

4．不是越高越好。

有的人喜欢高楼层，不仅感觉视线好，而且认为越高的地方空气越好，离地面越近空气越不好，所以，争相抢购高楼层，其实高层一旦停水停电也有很多的不方便。

5．不要选择一楼。

除非你想要开一些小商店之类的，否则，我们在选择楼层的时候，最好不要选择一楼，因为，一楼容易被过路行人窥探，而且吵闹又潮湿。

6．尽量不选二楼。

我们如果细心一点，不难发现，很多盗窃案件往往发生在二楼，因为，一楼的用户往往比较注意，都安上了护栏，这就导致二楼比较容易被爬上去行窃。

7．不选十层左右。

这个楼层的范围，看起来好像很不错，其实，如果这样认为就大错特错了，这段楼层正好处于扬灰层，空气相当不好，脏空气特别多。

买房什么楼层不能买？1、极端层。

极端层一般指的是顶层和底层的房屋，低层住宅采光不好，容易受潮，而且如果离马路较近，灰尘和噪音影响较大。

而顶层容易遭受“冬凉夏暖”的困扰，一旦电梯出现故障更是首当其冲的受害者。

2、设备层。

有的开发商会专门选择一层堆放设备，像厂家的供暖设施、供水、供电区域等都在这一层。

楼房住几楼最好灰尘少扬灰层的存在是指：“由于气流和建筑微环境的影响，建筑物在一定高度范围内的部分灰尘密度较大。

”但不一定是高层的9到11层，因为“其具体高度受诸多方面因素影响，在不同地区、不同城市、不同市区甚至不同小区都有差异，这跟灰尘密度、周围建筑高度和气流湍流特性都有关系”。

这就表示，不同的“扬灰层”并不相同，不能一概而论。

同时，因为要综合的科学因素太多，老百姓算不出来。

高层住宅是城市化、工业化的产物，高层住宅最大的优点，就是可以节约土地，尤其是对于我们这样的人口大国，同样的地基建造六层住宅与建十二层住宅，土地利用率可提高一倍，这显然对政府和开发商都有利(政府可以多卖点地，开发商自然更不说了)，所以近几年政府及开发商都利用各种传媒鼓吹炒作住小高层的利处，于是乎，住小高层似乎成了一时髦和潮流，小高层也如雨后春笋在各地遍地开花。

这里先说说小高层的益处，首先，从建设质量上看，一般情况下，高层的建造标准、建造质量要高于多层。

普通多层住宅一般为砖混凝结构，而高层住宅由于它为钢筋混凝现浇，地基深而结实，墙体厚实，不渗水，抗震性能好于多层，整栋大楼不会下沉变形；而且折旧年限长。

还有双路供水，供电系统，可提供更有保障的供应、集中安全的住宅环境、规模化的管理服务、以及良好的采光通风条件等优势。

随着小高层的普及，近些年挑选楼层的争论又多了起来，一说到选小高层楼层，一些人肯定会说，这还用争论？！既然是小高层，当然是越高越好了，其实不然，同一套户型，所在的楼层不一样，居住感觉也会大不相同，每层楼都有自己的小气候。

楼层不同，对我们的生活影响也不同。

这里先介绍各楼层的利弊让大家自己斟酌。

先说说一般不被购房者尤其是年轻购房者看中的低楼层吧，一楼到三楼，人们通常生活在树冠下，离地面很近，常常能倾听到树枝敲打窗户；要说心理上舒适，这里是最好的；同外部世界保持现实联系，不用朝下瞧人。

但接近地面的生活也有不足：一层到三层离地面很近，虽然得到心理上的舒适感，但是低层空气循环减缓、阴影和湿度大、通风不好的楼区污染也比较严重。

所谓的"扬灰层"纯粹是个谣言，尤其是18层到顶的高层，9-11层因为处在中间，不高也不低，着实是个好楼层，房价也相对较高。

楼层太低了的话视野、采光不好，你想想你周围都是高楼林立，你买个低层多憋闷，而且小区内的声音都能听到，比较乱，也失去了买高层的意义;太高了的话万一电梯坏了上下不方便，而且有些人从高处往下看有眩晕感，尤其是女士和儿童。

有些无良的卖房者，用这个谣言误导买房人，这几层他们自己内部人士留着住，要不就是留着涨价，还有就是通过这些所谓的"扬灰层""噪音层"等等来减小购房者的选择范围，从而尽快购买。

自己想想也知道，灰尘是有重量的，若只受重力和空气阻力的话，它终究是要落地的，但是因为空气的流动，灰尘受重力和风力的作用，漂浮在空中也是可能的，但不同的地区、风向以及不同的小区布局，所产生的气流都是不同的，而不同的空气湿度和温度，也影响着灰尘的浓度，所以，拿来的放之四海而皆准的"扬灰层"，实在是可笑之极，简直是无稽之谈。

中国很多家庭买房都是全家出动并"倾家荡产"，要说谨慎是必须的，但是凡事要动脑子想想，不能听风就是雨。

我当初买房也是这个情况，为了这个所谓"扬灰层"，跑了十几个小区，问了很多人，包括亲身住在这几层的，都说没有感受到扬灰，至少和其他楼层是没差别的。

我也查阅了很多资料，其中桨遥颂赠央视13套的新闻专门请专家通过实验数据说明，扬灰层根本不可信，只是谣言而已。

物理专家指出，10层左右是"扬灰层"的说法是不符合大气物理常识的。

因为在离地面三四十米高的地方，灰尘是不会停顿戒享希的。

灰尘在距离地面10公里至52公里的大气平流层都不会停下来。

也就是说，一般普通高层楼都没有所谓的扬灰层一说。

扬灰层只是一种说法，并未科学测定。

一般情况下，空气中的污染物随气流不断沉降和流动，在空中没有污染源的情况下，楼层越高，空气相对越干净。

选房要注意的十大细节
1.房间的朝向，尽量选择南北朝向，避免东西朝向。

2. 阳台的大小与朝向，考虑阳台是否能晾晒衣物，是否能够看到美景。

3. 房间的格局，避免过于复杂或者太简单，需要根据自己的实际需求来选择。

4. 楼层的高低，高层视野好但是容易受到风的影响，低层则比较安全。

5. 噪音问题，考虑周边环境的噪音情况，比如附近是否有高速公路、机场等。

6. 采光情况，选择光线充足的房间会更舒适。

7. 房间的面积，根据个人需求和经济条件来选择合适的面积。

8. 房间的装修风格，要符合自己的喜好和生活方式。

9. 周边配套设施，考虑周边是否有医院、学校、超市等基础设施。

10. 安全问题，选择安全性好的小区和房间，可以更加放心地居住。

- 1 -。

【1】说起来，住几楼还真不仅仅是电梯按钮上的那么个小问题。

要把它列成一道方程式来算的话，空气、噪声、景观、消防、电磁辐射、日照，甚至还有风水禁忌，这些参数，一个都不能少。

先说1楼到3楼，人们通常生活在树冠下，离地面很近，常常能倾听到树枝敲打窗户——要说心理上舒适，这里是最好的：同外部世界保持现实联系，不用朝下瞧人。

但接近地面的生活也有不足：空气循环减缓、空气换气受阻、阴影和湿度增大、污染也比较严重。

因为汽车和柏油马路使空气中饱含甲醛、一氧化碳、氮……至少远离汽车路干线200米才算安全。

沿马路的噪音也是个问题。

目前的声屏罩顶多只能减少3-6个分贝的噪音，剩下的就全部都要我们自己消化了。

那么，是不是越高越好呢？高层空气清新、噪声也少、景色也很优美。

但是，城建生态学家却认为，高层的空气并不像想象的那么清新。

前面题过的污染物集中区不说，大大小小的烟囱几乎将城市包围，30米以上的楼层，跟烟囱平起平坐，吸“二手烟”的机会自然多得多。

专家指出，附近有烟囱的建筑，选择时一定要注意与烟囱所处的角度。

以上海的地理环境来说，冬半年以北风为主，夏半年又以南风为主。

所以选择房子的时候，尽量选避开烟囱高度的楼层，也不要选那些处在主导风向的下风向的房子。

另外，不要以为住在13楼的噪音一定比3楼小，上海市环境科学研究院常务副院长曹卢林的说法也许会让你大吃一惊：闹市里不沿路面的高层建筑中8楼到 14楼的噪音反而比下面的楼层要大。

一是因为声音是波状立体传播的，向上面去的声波丝毫不比往两边的弱，当沿路面比较矮的铺面房阻挡掉了相当一部分低处的声波，处在后面的高层接收到的声波自然要比同一幢楼低层接收到的强。

二来，高架路对声波产生的共鸣、反射作用，也会在高一点的楼层中反映得更明显。

不容忽视的小问题其实，谁不知道理想的住房什么样？——高度不超过6楼，自然景色优美。

最好一边是公园，另一边是秀水，不仅风景如画，还要鸟语花香。

住在这样的地方，恐怕想不舒心都难。

19．航天飞机
教学目标：
1、凭借具体的语言材料，理解由生字组成的词语，了解航天飞机的一般知识和基本特点，激发儿童从小学科学，长大用科学为人类造福的志趣。

2、能正确、流利、有感情地朗读课文。

3、课内外结合，指导学生收集资料，丰富知识，扩大视眼，以“航天飞机“相关知识，学习小组合作出板报，做到读写结合。

教学重、难点：
1、通过多形式的读感悟航天飞机的基本特点。

2、有感情地朗读课文。

教学准备：
录音机、投影仪。

教学时间：
2课时
教学过程：
第一课时
一、分步板书课题，激发阅读兴趣。

1、板书：飞机。

师：同学们飞机都见过吧！
（说一说）
2、再板书：航天飞机
3、读题。

师：读了课题，你最想了解什么？
（航天飞机是什么样子的？它有什么用途呢？）
师：我们就带着这些问题来学习课文。

二、初读指导。

1、生字词的学习。

（1）学生自学。

（2）检查自学情况。

（3）生字词的书写。

（难的字词书写）
（在此过程中，我们要学会最方便的记忆方法。

）
2、课文朗读检查。

（1）小组赛读。

（2）选择自己喜欢的段落好好地读。

3、学习课文第一段。

（1）普通飞机是什么样的？
（2）用“一会儿……一会儿……一会儿……”造句。

三、作业。

1、抄写词语。

2、朗读课文。

怎样选购住房购买住房切记急躁，事先一定要做好充足的准备工作。

一、明确购房目的买房的目的有很多种。

若是为了方便孩子上学，尽量购买学区房；若是方便工作，尽量离工作地点较近；若是为了投资，应该选择更具投资价值的房子。

二、地段选择主要根据购房目的来选择。

每个人养老/工作/升值/自用/投资等各自需求不同，对地段的选择不一样。

1、一公里原则。

一公里原则是指以住房为中心，查看该住房一公里范围内配套设施是否齐全。

最好一公里范围内商场、学校、银行、医院、地铁样样都有，比较方便。

一般价格较高的房子周边配套、地理位置都比较好。

各方面配套齐全，如生活配套的菜市场、超市等，商业配套的商场、广场等，社区配套的学校、医院、银行等，小区配套的儿童乐园、健身房、公园等；交通便利，如公交车、高速、地铁等；景观好，如临江、望山、无风水上的明显忌讳等。

2、根据控规选择地段。

如果购买住房兼具投资属性，前期不一定配套要齐全，但升值空间必然大。

买房要看控规。

所谓控规，是“控制性详细规划”的简称，是指在城市建设中，政府对一个地块有着怎样的规划。

看控规，最重要的是看颜色。

重点关注的是：居住用地（黄的）和商业/办公用地（基本是红的/粉的）的颜色比例。

居住用地与商办用地的比例，直接决定了未来这片地块的发展。

如果这片地块都是黄色的居住用地，证明这里只是一个居住型的卫星城；如果这片地块大面积比例是商办地块，则商业的繁荣，必然在此提供了工作岗位，这些人群倾向于就近购房或者租房居住，未来这里的房价和租金都会有保障。

即使房价下行，由于旁边有足够的商业和工作人群，这里的房价至少跌的慢。

选择时应注意：（1）看控规。

优先选择整体地段中，商业写字楼用地比例大的。

（2）看用途。

同样很高的商业办公用地比例，选择里面真正拿来做写字楼的。

（3）看产品。

同样拿来做写字楼，选择里面楼层高、总面积大的。

（4）看时间。

同样的产品，选择住宅先盖写字楼后盖的，这样写字楼盖好住宅才升值。

买房子哪个楼层好？房子比较好楼层是几楼？导读:本文介绍在房屋买房，户型/楼层的一些知识事项，如果觉得很不错，欢迎点评和分享。

人们在买房子选房子的过程中，不仅要看周边的配套设施，而且还要看户型等一些问题，但是随着大家对楼层的关注度逐渐升温，楼层的位置也变得非常的重要，大家都是要考虑这个因素的，但是很多人不是很清楚买房子哪个楼层好？房子比较好楼层是几楼？下面就跟随小编一起学习了解一下吧。

买房子哪个楼层好？1、一层至三层的利与弊利：当发生意外时，比如地震、倒塌、火灾等事故，一层至三层当属最安全的楼层了。

尤其是对那些有小孩的家庭而言，更是如此。

2、四层至六层的利与弊利：对于高层住宅来说，从环境的角度来看，四层至六层安全性最好。

弊：如果电梯出现故障，或者是电梯拥挤的时候，四层至六层可能对于老年人和小孩来说，上下楼会很不方便。

3、七层、八层的利与弊利：对于高层住宅楼来说，七层、八层是＂黄金楼层＂段。

这个楼层安静，不受汽车尾气等影响，并且也不至于让人达到恐高的程度。

4、九层至十五层的利与弊利：从九层到十五层及以上楼层，是最明亮的楼层。

最高的树也达不到这个高度，因此光线不易被遮挡。

弊：如果在这几层上下有排放废弃物的管道，那么这几层所受的影响是最大的。

5、十五层以上的利与弊利：视野最好，空气最清新。

住宅楼暖气是往上升的，所以十六层以上最暖和。

弊：在一些老的小区，高层住宅楼一般水压较小，有时会出现停水的现象。

生火灾时不易逃生，并且火灾散发的有毒气体都是由下向上扩散的，因此是最危险的楼层。

房子比较好楼层是几楼？1、专家建议，购买楼房时，7层以下的位置最佳，九到十一层都不建议选。

是扬灰层。

就是地面灰尘上升到那，不动了，没法开窗的5楼的有害物质就少得多，因为它们开始下沉或往水平方向消散。

2、是不是越高越好呢？高层空气清新、噪音也少、景色也很优美。

但是，有关专家却认为，居住楼层不要超过6楼。

因为高层的空气并不像想象的那么新鲜，大大小小的烟囱几乎包围城市，30米以上难免集结起有害物质。

高层楼房挑选楼层的关键技巧一般现在很多人在买房的时候都会挑选一些高层的楼房，那么挑完了房子就该要挑选楼层了，该怎么去挑选楼层呢?以下是店铺为你整理的高层楼房如何挑选楼层，希望能帮到你。

高层楼房如何挑选楼层1.噪音楼层中部大两头小有实验研究表明，并非楼层越高噪音越小，以8~12层噪音最为集中。

考虑到外界环境的复杂性，如果噪声的主要来源仅是马路，往往底层和高层受影响较小，中间层受影响最大。

如果是地面反射，或者是对面建筑反射，高层的噪音源汇聚了各个方向的声源，会造成高层建筑中的中间楼层噪声最大。

在现实生活中，离噪音源越远，噪音就越低。

通常噪声在空气中的传播会有一个衰减过程，但声波还受周边绿化和风速的干扰，受到低层绿化、建筑物的阻挡或吸收，再经过多次折射、反射后的噪音就减小了，而高层完全暴露在声波的立体传播下，噪音相对就大。

除了交通噪音之外，住在高层的居民，往往还会被风的噪声影响到，风声也就成为噪音源。

另外，专家提醒，当前规划的小区配套也很重要，有些楼盘辟出的绿化森林带也能很好地降噪。

2.视野并非楼层越高视野越开阔楼层的高低决定了住户视野的好次。

视野范围小的住房久而久之住户压抑感强烈，舒适感降低。

根据研究表明，从视野的角度分析，16~23层之间舒适度最高。

所谓视野，简单的说就是住户从主卧和阳台，在开窗或不开窗的情况下，向外望所能看到窗外东西的范围。

楼层越低，所能看到的景观也越少，因为障碍物会阻挡到视野。

鉴于低楼层因视线死角及地面树木或周边低矮建筑的阻挡而视野不佳，毋庸置疑，楼层越高，视野也更开阔。

但顶层单位也因太阳直射，夏天过于闷热。

同时，置业顾问也提醒，有些时候并非楼层越高视野越开阔，要根据附近楼栋的遮挡情况作为参考。

购房者最好能够到具体房屋内查看，一些楼栋由于位置居中，在同一个小区同等层高的情况下也会被前面的楼栋挡住视野，因此高楼层视野是相对的。

3.通风采光户型、楼间距起决定作用通风采光受户型、朝向、楼间距等因素影响，若楼层过高，角度不对，也会影响阳光的照射。

高楼层的优劣：优点：1、视野开阔，对保护视力也有好处2、通风、采光效果好，阴雨天能节省照明用电3、受外界噪音影响小4、在梅雨季节比较干爽，不用除湿5、蚊虫较少劣势：1、夏热冬冷，夏天要比低层单位多耗费电资源和水资源。

2、如果屋顶的建筑质量有问题，首当其冲要受害，容易出现渗水、裂缝。

3、水压一般比较小，通过二次加压使水的质量没有低楼层好4、高层住宅的顶层最怕停电，公摊电梯运行费以及电梯维护费用比较多。

5、爬楼梯比较辛苦，不适合有老人的家庭。

且价格偏高低楼层的优劣：优点：1、相比高层，水的质量较好2、不用担心停电的问题，适合老人居住3、不用挤电梯，省时，方便，快捷。

4、园区景观带来的舒适感觉5、价格相对于便宜，高利用率劣势：1、采光，通风较差。

阴雨天需耗损更多电量2、容易受外界噪音影响3、在梅雨季节比较潮湿4、蚊虫比较多5、视野较差随着城市不断扩张发展，土地利用率越来越高，房地产市场也随之不停更新产品，逐步推动和更新居住建筑向小高层和高层发展，甚至超高层建筑也将在不久的将来出现。

各大城市的楼房也在不断的“长高”，高层的出现，给购房者带来更大的选择空间，对购房者来说，从多层到小高层，再到高层，可选楼层的增多，使大家面临选高层住宅顶部楼层还是选中间段楼层，或者低段楼层的疑惑。

业内人士表示，不同居住楼层都有各自的优势特点。

8层以下优势关键词：方便舒适、老人、儿童、景观、高利用率1、居住舒适：10层以下的建筑接近地面，可以看到地面人物和景物，给人以亲切安宁、有天有地的感觉，它的舒适度、方便度和空间尺度优于高层。

在通风、采光、日照等方面都可以基本满足生活需求。

2、方便家中老人儿童进出：如果家中有老人或者孩子，最好选择10层以下居住，因为老人一般行动不便，居住在高层假如遇上停电，那么进出会更加不便，家中用水也会因停电而断水，在低段楼层则不会受到影响。

退休工人高师傅住在某小区高层住宅的5楼，选择低楼层就是想着自己年龄比较大，下楼方便，便于清晨、傍晚锻炼身体、买菜。

如何选择房屋楼层如何选择房屋楼层1、1-5层：视野最差，楼下出入汽车噪音大，看不到户外景观，地漏容易返味，1-2层还能潮，尤其是头2年。

（从风水讲人是要接地气的，所以1层最好，农村人比较讲究这个，他们愿意住1层，认为不接地气身体不好）2、6-9层：视野一般，看得到户外景观但不是最佳观赏高度。

3、10-12层：浮沉层，最好不要选择。

4、13-14层：一般二次加水压的机器容易在中间楼层，18层的房子9-14层都有可能，买前要问清，一般销售也不是很清楚这个到底放在哪层，入行浅的可能就根本不知道，最好能实地看一下，而且这2个数字都不吉利。

5、15-16层：我认为这是最佳楼层，视野好，越过浮沉层，数字也吉利。

6、17-18层：17层还可考虑一下，因为电梯的机器都放在房顶，梢次的电梯噪音很大，白天是听不到的，晚上轰轰的'还是比较明显，所以18层就不用考虑了，如果电梯是好牌子17也是不错的选择。

18层就不用考虑了，夏天热，防水不好的话还漏。

7、首选南北通透的房子，通风好，夏天也凉快；纯南向房子热，空气流通性差；其次选纯东的房子，然后是纯西的，西房晒，如果厨房在西食物容易坏；千万不要买西北向的，冬天呜呜的灌风！8、虽然好朝向好楼层稍贵一些，但是你要住一辈子呢，或者将来你儿孙还要住呢，干吗委屈自己，平摊到70年，每年没多多少钱。

如何选择房屋楼层 [篇2]通常在国内，越高的楼层往往卖得越贵。

但是专家建议，购买楼房时，六七层的位置最佳。

首先，从空气质量角度来说，高度在30米以上的，空气质量反而更差。

而且，高层空气相对稀薄，患有慢性支气管炎、心脏病等某些疾病的人容易产生不适症状。

但综合考虑自己和家人的生活、工作需求合理选择适合自己的楼层，没有绝对的是与非。

一、楼层划分标准楼市上各种类型的住宅涌现出来，根据《民用建筑设计通则》（中华人民共和国建设部、中华人民共和国国家质量监督检验检疫总局2017年5月9日联合发布），将住宅建筑依层数划分为低层、多层、中高层和高层住宅。

高层楼房，一般哪层的灰尘大？一位从业十年的置业顾问冒着生命危险把行业秘密告诉我，他说：扬灰层根本就不存在，这只是一个伪命题，之所以会有人这样说，目的就是为了想把这几层的最好房子留在手上，以便后期快速脱销。

房子可以说对于现在的大部分人来说都是非常重要的，不仅是用来居住的，同时还是为了更好的享受生活的，毕竟房子在哪，家就在哪，有了自己的房子才能避免不断的租房。

也才能让自己有一个安定的住所，那这样的情况对于买房可以说就成为了非常重要的事情，但是这个时候大家都没有什么经验，也不知道房子每个楼层都会存在什么问题，所以很多时候就会听信置业顾问的话，这个时候就容易掉进坑里去了，特别是对于高楼层来说，选择那个楼层，什么样的户型可以说是非常关健，同时最关健的是如何避开扬灰层。

如果说你选择到这样的一个楼层那对身体的影响是非常大的。

什么是扬灰层扬灰层顾名思义，就是一栋楼当中属于灰尘最大的那一个楼层，那这个就不得不提到灰尘这个问题。

一般来说这个扬灰层就是指空气里所存在的灰尘，是属于漂浮在空中高处的灰尘，这些灰尘一般是由那些固态和液态颗粒物所产生的，灰尘粒径大约为0.1-100 微米，肉眼几乎是看不到的。

扬灰层这个词语的来源，其实是来自于2003年一篇《售楼小姐真情自白》的网文，根据当时内容网友们细心的从这篇文章中发现了扬灰层这一个词语，帖子原话是这么说的：“别以为高层中的九到十一楼不错，那你大错了，这些楼层正好是扬灰层，脏空气到这个高度就会停顿，我们是不会告诉你们的。

”但事实根据很多专家的测试，发现这个数据并不真实，这个就是纯属谣言了。

之所以会提出来这样的说活，就是为了把9-11楼留在自己手上，以方便后期自己能快速脱销。

所以现实太是这个扬灰层本身就不可能是存在的。

这几层属于扬灰层有没有科学依据上面也告诉大家了，一开始这篇文章就指出9-11楼是属于扬灰层，但可以肯定的说这个说话是完全没有科学依据的，是根本不存在的。

为什么这样说呢，请看下面的分析：1、一般来说灰尘的粒径在10微米为0.1-100 微米，这个是肉眼几乎是看不到的，那既然看不到如何去评判这几个楼层就是属于扬灰层呢。

GEOMEMBRANES USED IN HEAP LEACH SX-EW MINING: A MANUFACTURER’S PERSPECTIVEMauricio Ossa Defilippis, SL Limitada, Santiago and Antofagasta, CHILEABSTRACTTo talk about Geosynthetics in South America is not possible without linking them to the overwhelming development of the Copper Mining industry in Chile, nowadays the biggest copper producing nation worldwide. Between 1990 and 2005 the production of copper has increased from 1,400,000 tons to 5,400,000 tons per year. At present, after 15 years of continuous developing of the mining industry through the exploration for new deposits, the persistent improvement of the mining technology and the closure of those sites where the resources has been already exhausted or are become economically nonviable, has aroused a new reality that have to be faced; the environmental impact beyond the active life of the mine. In all these stages the geosynthetic industry has played a major roll, providing suitable materials for use in such projects around the world.This paper focuses on geomembranes used for heap leach mining technology. Applications include but are not limited to barriers for pads, pounds, channels, tanks, collectors, and in-plant containment.BACKGROUNDLeach pad technology was born and patented in North America the year 1975. Coincident with this in Chile, a medium size Mining company, “Sociedad Minera Pudahuel” started a technique to develop deep repercussions in the extraction of copper from the ore. This development consisted mainly of the improvement of large scale Thin Layer Leach Pads. At the end of the 80’s “Lo Agirre” a new Copper Cathode Plant, started operations using the TLLP technology combined with the Solvent Extraction process and Electro Wining Cathode Extraction (LX - SX - EW). This plant was the very first one to apply at commercial scale the Thin Layer Leach Pad Technology. During the next two decades this process reached global importance.In contrast, the solvent extraction process was developed during the Second World War by the United States in order to obtain the uranium required for the Manhattan Project. Later, this technology was declassified and brought to service in the civil industry, particularly to the copper mining industry.The Heap Leach Solvent Extraction - Electrowining Technology - (SX-EW) at a glance. A description of the heap leach SX-EW process, from the crushing and stacking operation to the electrowinning of copper cathode, is explained below.CrushingOre from the mine (ROM) is delivered to the stockpile and placed in designated stockpiles to segregate ore on the basis of ore type and grade. This ore is fed to the crusher by a Caterpillar type front-end loader. The crusher could be a two or three stages process after which the crushed ore is conveyed to the agglomeration area.AgglomerationThe agglomeration process is intended to minimize segregation of the coarse and fine components of the ore in a heap, so that reduces short-circuiting of leach solutions in the stacked heap, and creates a uniform wetting pattern over the leaching ore.Concentrated sulfuric acid is added to the ore at a typical rate of 10 kg/t, via a spray bar at the feed end. Water or leach solution is also added through an adjacent spray bar to achieve approximately 8% total moisture. The addition of acid to the ore before irrigation ensures that the total acid requirements of the leaching process are partially satisfied. The acid has to dissolve the copper as well as other acid soluble materials. This other non-copper acid soluble material is called “gangue”. It consumes acid without generating additional copper.The Pad ConstructionThe heap leach pads are constructed, utilizing as much is possible the natural topography of the site. The pad area is cut and filled as required, and trimmed to achieve the desired slope of 0.5 to 1%. Other earthworks, including perimeter bund walls, interior drainage ditches and leak detection drains, are formed prior to final watering and rolling. The completed pad is then inspected in detail and any imperfections are rectified, before the geomembrane is installed.The base of the heap consists of a geomembrane liner. High density polyethylene or Linear Low density (HDPE or LLDPE) lining material is used throughout. The liner is between 1 mm and 1.5 mm thick over the pad and between 2 mm and 3 mm thick in the sumps and drains. Directly over the liner are installed the HDPE drainage pipes, and then a granular protective soil layer about 60 cm thick is placed directly over the geomembrane-pipe system, to protect the liner during the ore staking.The agglomerated ore usually is delivered to the leach pads by overland and modular conveyors to a final radial stacking conveyor which is capable of stacking ore up to 8.5 meters high. One of the most used stacking method is called radial stacking, and involves the ore being placed in layers approximately 200mm thick, leaving a level surface on top of the heap.Figure 1. Protective layer installation in Figure 2. View of the collection systema heap leach. in a heap leach.Staking and Heap ConstructionFor sulphide ore, there is a forced aeration system that supplies low pressure air to the base of a heap, which helps to promote bacterial oxidation reactions in the heap. The air lines are the same or similar as those used for drainage, namely 100mm slotted drainage pipe. These are installed during stacking across the face of the heap at a height of 1 m above the surface and at 2 m centers. For the oxide ore, no aeration is needed and just the drainage pipes are installed.IrrigationThe piping network for each heap comprises main lines at ground level and heap supply header pipes along the heap, which distribute solution over the surface of a stacked heap through a series of either dripper lines or sprinklers. All piping networks are HDPE throughout, and are installed manually or using special equipments. Once irrigation process has started the solution percolates down through the entire heap until it reaches the impermeable polyethylene geomembrane base of the leach pad. The pad is built on a slight slope towards a series of solution drains. This causes the solution to flow towards these drains once it has reached the geomembrane barrier at the base of the heap. Oxide ore is generally leached at irrigation rates between 4 to 8 L/hr/m2. Sulphide ore is leached between 7 to 15 L/hr/m2. Aeration of sulphide ore is continued through the lifespan of the heap.In a two-stage leach operation, the barren solution from the solvent extraction plant (“raffinate”) which has a high acid concentration, is fed to those heaps that have been leached to greater than 50% copper recovery. The solution exiting these heaps, called “intermediate leach solution” or ILS, becomes the feed to those heaps from which less than 50% of the copper has been recovered, which then produces “pregnant leach solution” or PLS suitable for solvent extraction recovery. This flow regime is regulated according the existing conditions by directing each individual heap effluent stream to either the PLS, ILS or Raffinate drains to control pond levels and solution grades.Figure 3. Detailed view of the irrigation system in a heap leach.Solvent ExtractionThe objective of the SX plant is to produce a pure copper sulphate solution suitable for the Electrowinning process. A simplified flow diagram of the leach and SX circuit is illustrated in Figure 4.Figure 4. Heap leach and SX flow diagram.Pregnant Leach Solution (PLS), containing between 1.5 to over 8g/L copper is contacted with an organic copper extractant, LIX984N; which has been diluted with a low volatility kerosene based carrier (diluent), in a two stage mixing tank. The immiscible aqueous and organic phases form an emulsion in the mixer (also known as the “organic”), which allows for extremely efficient surface contact. Copper in the PLS is extracted into the organic phase during this contact by an ion exchange reaction.The emulsion then flows into a settler where the two phases separate as they flow towards separate discharge launders. A typical mixer/settler is shown in Figures 5 and 6. The aqueous phase, stripped of copper, is now called Raffinate and discharges to the Raffinate pond where it will be returned to the leaching operation as leach solution. The organic phase, now loaded with copper, discharges to the loaded organic storage tanks. From here it is pumped to the strip stage mixer/settler.Figures 5 & 6. Two different views inside the Solvent Extraction area.The walls and the floors are lined with studded HDPE liner.In the strip stage the loaded organic is contacted with spent electrolyte solution which has been returned from the EW tankhouse. This solution contains 35-40g/L copper and 180g/L sulphuric acid. The spent electrolyte strips (removes) the copper from the organic phase into the aqueous phase during contact in the mixer. The strip reaction is the reverse of the extraction reaction. The stripped organic is then separated from the electrolyte in the settler and discharged from the strip settler to the extraction stage mixer/settler where it is again contacted with PLS to extract more copper. The electrolyte is now called strong electrolyte and contains 45-55g/L copper and 160g/L acid.The strong electrolyte is almost ready to be pumped into the EW tankhouse, but first it has to be thoroughly cleaned of any organic carryover (entrainment) and fine solid particles, both can of which lead to problems in the electrowinning circuit.Electrowining OperationThe EW circuit has to produce a high purity copper cathode at high current densities and maintain good current efficiency.Strong electrolyte leaving the discharge launder of the strip stage settler is passed through two separate stages of filtration before it reports to the tankhouse. First it is pumped into a Jameson flotation column, where any entrained organic is coalesced on tiny air bubbles and rises to the top of the column. The recovered organic is purged off within a layer of froth. The electrolyte is then pumped through Spintek multimedia filters. The filter medium consists of layers of anthracite, garnet and coarse sand, and is very effective in removing fine suspended solids and any entrained organic not removed by the Jameson column.The strong electrolyte passes through a heat exchanger where the solution temperature is raised to around 35 deg. C by the spent electrolyte returning from electrowinning tankhouse. Once heated the electrolyte reports to the scavenger electrowinning cells. The electrolyte leaving the scavenger cells reports to the circulating electrolyte tank, which is joined to the spent electrolyte tank. The circulating electrolyte is pumped to the remaining conventional cells before returning to the spent electrolyte tank. The spent electrolyte is pumped to the strip stage mixer/settler to return as strong electrolyte.Each electrowinning cell contains many stainless steel ISA Process cathode plates and a similar number of lead alloy anodes. Scavenger cells are identical to the conventional cells except that they receive flow from the solvent extraction circuit first. They remove any remaining solids or traces of entrained organic that may have passed through the filtration stages, and hence they protect the remaining cells. As electrolyte flows through the EW cells, DC power is applied to the anode/cathode electrical circuit. Under these conditions electrochemical reactions occur. The lead anode transfers electrons across to the cathode in an even dispersion pattern. As copper metal is plated, acid is produced which is then used to strip copper out of the loaded organic in the solvent extraction strip stage leading to a continuous recirculating circuit.Figure 7. View of the Pump Station in PLS pond.The Geosynthetics along the Heap Leach TechnologyThe heap leach technology makes an intensive use of the geosynthetics materials since the very beginning of the process and in every stage of it. Geomembranes, Geopipes, Geotextiles, Geonets and Studded Concrete Liners have a very important roll. They are used intensively lining millions of square meters.Though the geomembranes are the most important component in this myriad of polymers products because they are used in the most extended component of the system, the rest of the geosynthetics materials play a significant roll. Following the same order it was used in the Heap Leach process described formerly, it is possible to enunciate several important issues.Heaps: The base layer of the Heaps is lined by a geomembrane, usually a Polyethylene liner (HDPE or LLDPE) with thickness of between 1.0 mm and 1.5 mm. The geomembrane could be smooth, single side textured, double side textured, or a suitable combination according to the design parameters like the seismic activity of the site, slopes, topography etc.Conveyor Channels: The leaching solution collected by the geomembrane is diverted by means of proper disposed open channels that are fed along the pad and though the main collectors disposed in the downstream extreme of the heap. The channels are commonly lined by a thicker HDPE geomembrane and their content goes directly to the main HDPE Pipe Lines which finally discharge the leaching solution to the ponds area (ILS or PLS).Figure 8. View of drainage systems in Figure 9. View of the collector channela heap leach. in a unlined heap leach.ILS and PLS ponds: These units are compounded for the whole geosynthetics product collection. Commonly the lining system consist in a double HDPE liner 1.5 mm thick, that sandwich a drainage layer based in a HDPE geonet connected to a shaft intended as a leak detector. Sometimes the secondary liner is protected from the soil surface by means of a 400 g/m2 nonwoven geotextile. Some projects additionally consider that the PLS be also provided of a floating cover in order to keep the solution free of contaminant particles that can affect the quality of EW process. These ponds also are provided of a huge pump station that has to be lined with studded concrete liner in order to resist the pump suction generated here.Raffinate pond: The conditions here are quite similar to the ponds mentioned above. However here never a floating cover is needed but skimmers specially designed for the recovery of the organic. Sometimes the liner used here is 2 mm thick as the organic tend to swell and permeate the geomembrane.Figure 10. View of the Raffinate Pond.SX areas: these areas are compounded by a series of concrete pond trains lined with very thick HDPE geomembrane liners, 3 and 5 mm depending if they are going to be used at the bottom or on the walls were they get contact with the organic solution.Tank farm: The Tank Farm is formed by many big and deep concrete tanks, lined commonly with Studded Concrete Liners and located into a depressed area also lined and able to serve as a secondary containment area.Figure 11. View of one component of the Tank Farm area.EW Plant: The Electro Wining building is more like an industrial plant where the protection provided for the geosynthetics materials rather a protective floor layer than a containment liner. The aisles are lined by rugged and thick HDPE membranes, meanwhile others areas subjected to damage by spill of acid solution are lined using reinforced PP.The Manufacturer Point of ViewSo far, this paper has presented a general description of the geosynthetics used in the mining industry, particularly of those used in the heap leach technology. The following addresses concerns of manufacturers such as SL Limitada (SL).Figures 12 & 13. The spark test detector (right) can’t help when the liner is not properlyinstalled or deployed (left).SL is aware that most processes in the mining operation require many years of almost uninterrupted service. Heap leach Technology is not complex but rather results in many different extreme situations, and each must be considered individually and then as part of an entire system. Polyethylene geomembranes (HDPE and LLDPE) have proven to be the best and most reliable product on the market and they have served under the harshest conditions in the mining industry with an unmatched record of effectiveness and endurance for almost 40 years. However polyethylene geomembranes need to be complemented with:•The knowledge of the product by the designer (properties, strong points and weak points).•An experienced CQA company that controls the installation process and feedback the design.• A clear and wise specification that requests no more or less than what is needed.The following text will show why SL believes that beyond the quality of the product, these three points always have to be present in any project. We will show each part using geomembranes in a heap leach system, the respective aggressive conditions, and then the considerations to work around the concern.Conditions that will lead the choice of the proper geomembrane in a heap leach operation. Pad Area Immediately Under the Heap: This area has to support the huge masses of ore formed by staking many levels (static heap), each one about 7 meters high or just one level (dynamic heap) where the liner is continuously stressed by the loading and unloading process achieved by huge mobile equipment. Moreover the aggressive solution constantly irrigated throughout the pad is going to be acting and leaching the ore and the antioxidants of the geomembrane so that the liner endurance has to rely essentially on the quality of the resin and in the geomembrane thickness.Under such circumstances, some critical properties that arouse concern are: environmental stress cracking, minimum thickness and not puncture resistance but the ability to endure those forces that tend to perforate the geomembrane. SL strongly believes that this fine point is critical and can not be overlooked. Puncture force is not directly related to the energy required to puncture a geomembrane.Immediately out of the pad area, there are channels that collect the leachate and stresses are almost negligible, but there is the huge solar radiation over the desert, constant flow of the acidic leachate conveyed to the ponds, and elevated temperature. As in the heaps, antioxidants will be leached from the polymer resins. To protect the liner under such circumstances carbon black and the antioxidant package will be the most effective barrier against the UV degradation and the resin type will be the most decisive property to guard against attack of the different chemical agents. In the same way, the minimum thickness plays an important roll and therefore must be considered in pad design.PLS & ILS Ponds: These units play a critical roll in the heap leach technology as they are constantly sending and receiving solution. These ponds need to be designed with a very high factor of safety. They can not be taken off line. They are critical path elements designed to endure the whole life span of the project with minimum maintenance. Their design relies on the impermeably of the system rather than the impermeability of a single material. A double liner system is used consisting of a geonet layer sandwiched between the secondary and primary geomembrane, where the geonet is connected to a detection shaft at atmospheric pressure so that any leak to the primary liner goes directly to the detection shaft where it should be pumped out as soon as possible in order to keep the atmospheric pressure condition into the drainage layer. In addition, the “pump station” built on concrete needs to be accommodated. Connections between stiff and flexible areas are always a challenge. As matter of fact, most defects are found on these ponds (extrusion weld) between the pond liner and the pump station liner as a result of the following:•The welding has to be achieved in areas where there is not enough room to handle the welding equipment (grinders, hot air guns, extrusion welders) or the QC/QA equipment (vacuum box).•There was an improper grinding and preparation of the surfaces to weld.•The welding process was achieved when the geomembrane was still expanded, causing stressed areas and trampolines.A PLS pond recently evaluated because persistent leaks existed over time, shows all the above conditions. The geomembrane (HDPE 2 mm thick) was evaluated making a laboratory test analysis. The liner was about four years old. The results were outstanding, with the liner still retaining almost 90% of the mechanical resistance and flexibility.On this example the most significant properties of the liner were:•Its resistance to the stress cracking failure.•The minimum thickness.•Carbon black content and dispersion.•Integrity endurance.The Raffinate Pond: This unit shares similar conditions to the PLS and ILS ponds; however it has an additional concern of heightened organic content. The organic which is a solution of copper extractant, diluted with low volatility kerosene based carrier, can swell the polyethylene liner and eventually make it almost unweldable and therefore difficult to repair. When a rafinate pond fails, commonly the whole liner system needs to be reconstructed at great expense, therefore good CQA supervision and a conservative design for this area is strongly recommended.SX, Tank Farm and EW Areas: Although all are different units, they all are mostly concrete structures lined with heavy HDPE liners (between 3 and 5 millimeters thick), studded concrete liner or simple HDPE plates. Therefore almost all the seams are extrusion welds. Whenever there is a failure or a leak, the reason is associated with a poor quality installation or an unpractical design. Commonly these structures, for economic reasons consist of just a single liner, therefore the acidic liner leak goes directly on the concrete attacking and degrading the structure. The dissolved concrete then could clog the leak detection devices making it inoperative. The consequences could be serious. The inner area between the liner and the concrete is communicated with the containment system. If the acidic solution occupies the same level on both sides, degradation to the underlying concrete and the steel structures could be swift and significant.Making the geomembranes to specification.It is critical that the geomembrane performs well over extended period of time in these extreme conditions. Poor geomembrane performance can result from a geomembrane that has not been manufactured to a good specification such as GRI-GM13, and installed with an effective CQA program.The standard tests that are performed in the geomembrane industry commonly are:1.Thickness, according to ASTM D51992.Tensile test, according to ASTM D66933.Tear resistance, according to ASTM D10044.Puncture resistance, according to ASTM D48335.Carbon black content, according to ASTM D1603 or D42186.Carbon black dispersion, according to ASTM D55967.Density, according to ASTM D1505 or D7928.Stress crack resistance, according to ASTM D5397 (NCTL)9.Oxidative induction Time, according to ASTM D3895 / D588510.Oven aging, according to D5721 and D389511.UV Resistance, according to GM11 and ASTM D588512.Delamination, according to in-house procedures.However, some properties are more important than others.Tests numbered 2 (tensile), 3 (tear) and 4 (puncture) are mechanical index tests whose results cannot be interpreted for a final design. We can not deduce that geomembrane A will endure bigger deformations than a geomembrane B, based on the results of tensile or tear tests. Therefore, the puncture test is a partial answer for most geomembrane applications as it considers just the force needed to puncture the geomembrane. A very significant part, but for practical reasons dismissed, is the deformation during the test. Both values combined would give the energy needed to puncture the liner (see Figure 14) what could be very important comparing two different liners. It is suggested that material should be evaluated for puncture elongation and strength.Figure 14. Curves obtained from the puncture test.Test 7 (Density) gives part of the fingerprint of the resin and therefore is useful, usually well behaved and understood. It is important in regard to diffusion and chemical resistance. This property will also reflect the general classification of the geomembrane.Tests 1 (Thickness), 5 (CB content), 6 (CB dispersion), 8 (stress crack), 9 (OIT), 10 (oven aging), and 11 (UV aging) are endurance related and key to geomembrane durability. Carbonblack content and carbon black dispersion represent the most important protection against UV radiation. Some master batch (the additive that contains the carbon black) manufacturers report that the highest efficiency is achieved between the 2.5 and 3% of carbon black in the final geomembrane (Juan Salfate, Ampacet). When combined with the adequate thickness, the resulting geomembrane could withstand the aggressive conditions that have been discussed. Stress crack resistance is tested using NCTL (Appendix A). It is a key test that will stop all unfit resins but also a few good ones. Those few resins that are disqualified by way of poor test reproducibility are an acceptable sacrifice for mining applications. Stress cracking failures are not desirable and any measure to avoid them is very welcomed. This makes the possible pool of resins and recipes smaller for a manufacturer and also explains why it is a good practice to use resins specifically manufactured for the production of geomembranes. Such a conservative measure is warranted until full knowledge of the formulation and its specific long term field performance is known.Oxidative induction time, when linked to the Aging tests (UV and Oven aging) is a very useful index that allows inference to the durability of the geomembrane. To understand better the meaning of the OIT and how it relates to the endurance of a geomembrane, the following analogy is offered: It is well known that any steel structure is subjected to oxidation. As a consequence, a layer of paint is generally placed on the structure to protect it against the elements. The quality of the protection level is judged by the paint layer thickness, how well the paint adheres to the steel and how well it endures the service conditions. In the same respect, the geomembrane needs protection against oxidation. The OIT gives an index that is analogous to the paint thickness. The UV and the oven aging test will answer how effectively it protects. There is just one more question that has not been answered; that is, how well does the antioxidant adheres to the resin matrix of the geomembrane?To meet the OIT specification in GM13 it is easy to add an adequate amount of antioxidants until the threshold is reached. However, to make the AO package effective is a matter of research and experience. The development of a new test, which answers the adherence capability of the antioxidant, is needed. There have been cases of geomembrane meeting GRI-GM13, in contact with leach solutions at elevated temperatures, where the antioxidant package was leached to the point that it could not be detected by the OIT test. This finding suggests that the degradation mechanism at work have progressed past Stage “A” induction time as discussed by Hsuan and Koerner.SIP Delamination (12), a very rare phenomena, is usually checked by an in-house test, and not reported for there is no standard test method currently available for this phenomenon. SL’s in-house procedure is an observational method and merely subjective. Delamination is observed uniquely in thick HDPE geomembranes and normally detected by performing tensile tests at a rate of 500 mm per minute. The cause of delamination is still an unsolved mystery; Struve and Allen suggest low molecular weight material in the master batch, Nobert suggests uneven cooling, Smith and Peggs suggest contamination, but all are theories at this time. However, it appears that the causes are not unique. Manufacturers care about this phenomenon because of the owners reaction against it when detected while running field tensile test during the installation process. To date, there has been no reported field failure related to the SIP phenomenon. In。

不存在。

通过对“扬灰层
”这个概念进行检索发现，这一概念最早出现在网上的一个帖子发表的所谓的售楼小姐的选房秘籍，对“扬灰层”的说法是高层居民楼中污染物易于积累、浓度较高的楼层。

实际上，无论是理论研究还是实验测量，都不存在这一概念。

有个相近的概念是“大气边界层”，在大气边界层内气溶胶或颗粒物浓度较高。

举个例子，大家坐飞机的时候会觉得天特别蓝，就是因为飞机已经飞离大气边界层。

之外。

居住建筑的9-11层在30多米高度，而大气边界层高度在数百米到数千米，这一高度远高于居住建筑的9-11层。

而且大气边界层通常具有城市高于远郊、白天高于夜晚的特点，并且随着温度、气候、风速的变化而变化，并不会停止在某一高度。

即使在大气边界层内，根据很多测量结果的研究表明，污染物的浓度总体上随高度呈递减趋势，并不是累积在某一高度。

其中，PM10浓度的递减趋势快于PM2.5，尤其在郊区等远离市中心的地区较为明显，即一般情况下，在空中没有污染源的情况下，楼层越高，空气相对越干净。

对于常见PM1，PM2.5和PM10浓度随高度的变化规律研究，有数据显示当高度达到80m左右处（约26层楼高）时，PM1、PM2.5和 PM10浓度衰减分别能达到20%、38%和40%左右。