湿式混凝土喷射机泵送系统设计【含CAD图纸、说明书】
1英文原文Criteria for selecting a concrete pumpThe two primary parameters, which should be known prior to selection of a pump, are the maximum desired volumetric output of concrete per hour and the peak pumping pressure, p. A nominal output of 30 m3/h is considered sufficient for routine concreting operations related to most civil engineering applications. For specialised jobs where greater output is desired, pumps with a capacity in excess of 120 have been known to be deployed. The hm3required power of the drive unit (prime mover) of the concrete pump depends on the desired delivery output of concrete, Q, and the pumping pressure, p. The delivery output and the pumping pressure are co-related by the expression for the hydraulic output, H, of the concrete pump:=sonstantpQHIf Q is expressed in and p is expressed in bars (1 bar = 0.1 ) and assuming hm3 2mNa system efficiency of 75 percent,the required power, P, of the drive unit (prime mover) of the concrete pump can be expressed in kilowatts (kW) as :Pumping pressureThe maximum pressure, which a concrete pump is able to generate, depends on the mechanical design of the unit in question, particularly the concrete valves, taper sections, delivery pipelines etc. Lorry-mounted concrete pumps which invariably have short delivery pipelines will require pumps gen-erating maximum pressures of around 7 (70 bars). 2mNHence, it follows that a typical lorry-mounted pump with a 90-kW prime mover can deliver a maximum of 90 25/70=32.14 of concrete.hm3If under certain circumstances, a pumping pres-sure of say 4.5 N/mm2 is deemed enough for the above unit, then a peak output of 90 25/45=50 of concrete can be obtained. hm3Therefore, it follows that the pump-ing pressure and the peak concrete output are inversely proportional to each other. Portable concrete pumps which may place concrete at horizontal distances of up to 1000 m or vertical distances of up to 400 m may require pumping pressures of the order of 20 (200 bars).2NTo be able to achieve a targeted output of concrete at site it is imperative to determine as accurately as possible the required pumping pressure so that together with the desired 25pP2concrete output, a rational basis for selecting a pump can be developed. The volumetric output of concrete desired would depend on the type of job at hand and the desired progress of work. The primary variables on which the pumping pressure is dependent can be listed as the total lead, delivery pipeline diameter, delivery output, concrete consistency and directional changes in the pipeline. The pumping pressure decreases from a maximum at the concrete pump to zero at the output end of the delivery pipeline.The maximum lead will include the total maximum horizontal and/or vertical distance over which the concrete is to be pumped. The maximum lead in terms of the horizontal and vertical placing distance has to be calculated by taking into account likely increase in the pumping distance due to bends and directional changes in the delivery pipe. Directional changes in the flow of pumped concrete will undoubtedly place excess demand on the pumping unit and these are accounted for by adding an equivalent horizontal length of the pipeline for different types of pipe bends.One of the established manufacturers of pumping equipment recommends that, independent of the pipeline diameter, 90-degree bends with a radius of 1 m may be replaced by an equivalent horizontal pipeline length of 3 m2. Hence, a 30-degree bend with a radius of 1-m is equivalent to a length of 1 m. If for example, bends totaling 630 degrees are installed in a pipeline system, then the equivalent length can be computed as 630/30=21 1 m=21 m. For 90-degree bends in delivery pipelines mounted as for example, on placing booms, a radius of 0.25 m is usually adopted 2. The equivalent length for such elbow bends is recommended as 1 m2. Therefore, the horizontal pumping distance for a placing boom will be its outer reach plus the equivalent lengths for each of the 90-degree bends in the three articulated sections usually found in placing booms.The vertical pumping distance is accounted for by adding a pressure increment of approximately 0.025 (0.25 bars) for every metre difference of elevation to the 2mNpumping pressure computed for the horizontal placing distance.For a given output of pumped concrete, the flow velocity and hence the flow resistance increases with reducing delivery pipeline diameter as does the associated pumping pressure. For the purpose of illustration, for a nominal concrete output of 40 , as the delivery hm3pipeline diameter decreases in the order 150 mm, 125 mm, 112 mm and 100 mm the corresponding flow velocities increase in the order 0.6 , 0.8 , 1.1 and 1.39 , sssrespectively. To limit the pumping pressure and to minimise pipeline wear and tear it is always advisable to use larger pipeline diameters whenever higher delivery outputs are desired. The difficulty with pipelines of larger diameter is that they are difficult to handle, 3especially when they are filled with concrete. Both rigid and flexible pipes can be used for pumping concrete though rigid pipes are more popular because of the additional frictional losses and cleaning problems associated with flexible pipelines. Rigid pipelines made of steel are available in varying lengths and wall thicknesses.Individual delivery pipe lengths are available in lengths of 1 m, 2 m or 3 m with the most common wall thickness of the pipes for the range of pumping pressures usually employed (7 to 10 ) being 4 mm. For higher pumping pressures (20 and 2mN 2Nmore) pipes with wall thickness of more than 7 mm are usually recommended. Quick-locking couplings connect individual pipe lengths. A 100-mm diameter pipeline is considered ideal for short and medium placing distances (up to 200 m) and concrete outputs of up to 25 . hm3For longer placing distances and higher outputs, 125 mm diameter pipeline is considered to be the best and this pipeline size is considered to be ideal for most site applications. Pipelines of 150 mm diameter are generally used for placing concrete with a maximum aggregate size greater than 40 mm or for placing large quantities of concrete at longer distances. Relatively larger pipe diameters result in lower pumping pressures and reduced power requirements of the prime mover though at the cost of reduced maneuverability of the pipe network.The consistency of the concrete mix has an important bearing on the pumping pressure. A slump between 40 and 100-mm or a compacting factor of 0.90 to 0.95 or Ve be time of 3 to 5 s or concrete within the consistency range K3 is generally recommended for the mix in the hopper1,3. The right consistency of the concrete mix is essential to avoid excessive frictional resistance in the delivery pipe due to stiff mixes or segregation with too wet mixes. Stiff concrete is difficult to deform and requires higher pumping pressure to pass through bends and tapered sections in the delivery pipeline.It may be noted that any variation in mix consistency or workability can easily be detected at the pumping point by observing pumping pressures. The concrete pump is thus one of the greatest aids to quality concrete; it acts as a silent quality control equipment refusing to handle any concrete which is unduly harsh, inadequately mixed, non-cohesive and not correct in consistency4. Pumpable concrete requires sufficient amount of fines, enough slump (about 80 to 100 mm), continuous grading of aggregates and uniformly and thoroughly mixed materials.It is to be appreciated that if it is desired that pumping is to be carried out at the rate of 40 , a concrete pump with a maximum pumping capacity of 40 can achieve the hm3 hm3desired output only if it works continuously for one hour. This is seldom the case in view of conditions obtained at construction sites. Actual pumping time may be 45 minutes or even 4lesser. Taking an actual pumping time of say 45 minutes into account, if the pump is to achieve a nominal out put of 40 m3/h, it must be able to place0.45/0.75 = 60 . The hm3actual pumping time of 45 minutes in this illustration can be represented in the form of a work factor for the concrete pump which in the above case works out to be 45/60=0.752. It is reasonable, for the conditions typically prevailing in sites, to take a work factor of 0.75 to 0.80 while ascertaining the actual capacity of a concrete pump.In conclusion, the selection of a concrete pump for a given job will depend primarily on the desired concrete output, the consistency of the concrete to be pumped, the maximum lead in terms of the horizontal and vertical placing distance and the diameter of the delivery pipeline. Once all these parameters are known, the problem reduces to determining the pumping pressure. Knowing the peak pumping pressure and the desired output of concrete, the power of the pump prime mover can be determined, as is illustrated with the help of the following example.Example on pump selectionIt is required to place an average of 40 of concrete at a multistoried building hm3construction site. A placing boom with a horizontal reach of 27 m distributes the concrete. Work factor for the concrete pump may be assumed as 0.75. The length of the 125mm delivery pipeline with 5 bends of 90 degrees and 2 bends of 30 degrees is 110-m. The maximum height of the building is 65 m and the end of the placing boomis approximately 4 m above the pouring point for the top most floor.The concrete slump is 100mm. For determining the required pumping pressure and hence the prime mover capacity of the concrete pump the following steps are suggested.Required concrete output (given)= 40 h3Work factor (given) = 0.75Slump of concrete (given) = 100 mmDelivery pipeline diameter (given)= 125 mmNominal concrete output = Q = 40/0.75 = 53.3 hm3Delivery pipeline horizontal length (given) = 110 m (a)Number of 90 degree bends = 5; Angular measure of 90 degree bends = 90 5 = 450Number of 30 degree bends = 2; Angular measure of 30 degree bends = 30 2 = 60Total angular measure of bends = 450 + 60 = 510Number of equivalent 30 bends =510 /30 = 17Equivalent horizontal pipe lengths at 1 m for each 30 bend = 17/ 1 m = 17 m (b)5Horizontal reach of placing boom (given) = 27 m (c)Equivalent pipe length due to standard bends in placing boom (assumed) = 10 m (d)Total equivalent horizontal pipe length= (a) + (b) + (c) + (d) = 110 m + 17 m + 27 m + 10 m = 164 mFrom the nomogram in Fig 3, for 53.3 concrete output, concrete slump 100 mm, hm3delivery pipe line length 164 m and pipeline diameter 125 mm, the pumping pressure works out to be 34 bars (3.4 ).2NFig 3 Nomograph concrete pumping 2Vertical lead = 65 m + 4 m = 69 mEquivalent static pressure due to vertical lead of 69 m at 0.25 bars (0.025 ) per 2mNmetre difference in elevation = 0.25 * 69 = 17.25 bars (1.72 )2NTherefore, maximum pumping pressure = 34 + 17.25 = 51.25 bars, say 52 bars (5.2 ).2mNHence, required power of pump =Q p /25=53.3 52 / 25=110 kW or say 140 HP.6Knowing the required power of the prime mover, the required concrete output and the maximum pumping pressure, the pump with specifications nearest to the desired ones can be selected, Fig 4.Fig 4 The transit mixer in the fore-ground discharges concrete into the lorry mounted concrete pump in the background (Note: The articulated telescopic placing boom delivering concrete to the desired location).ConclusionThe influence of various parameters related to concrete characteristics and mechanical appurtenances on the pumping of concrete have been presented. The concrete output, concrete consistency, horizontal and vertical lead and the diameter of the delivery pipeline have an important bearing on the pumping pressure, which is a critical design parameter. The required power of the pump prime mover can be estimated from the desired concrete output and the pumping pressure.7References1. NE V I L L E, A.M. and BR O O K S, J.J. Concrete Technology, Longman, England, 1994 ed. p. 4382. ECKARDSTEIN, K.E.V. Pumping Concrete and Concrete Pumps, Friedrich Wilhelm Schwing GmbH, Herne, Germany, 1983, p. 133.3. _DIN 1045, Beton und Stahlbeton bau Bemessung und Ausfuehrung (Plain and Reinforced Concrete: Design and Construction), German Standards Institute, Berlin, December 1988.4. _Hand Book of Ready-Mixed Concrete, Published by The Cement Manufacturers Association, New Delhi, 20028英文翻译选择混凝土输送泵的标准在选择混凝土输送泵之前,需要知道路两个最原始的参数,它们是理想状态下每小时混凝土泵送体积的最大值和泵送压力的峰值 p。那种实际输出为 30 立方米每小时的混凝土泵,对于常规的大部分的土木工程应用是绝对可以满足的。对于那些对输出要求很高的专门的工作,已经知道部署输出能力超过 120 立方米每小时的泵。混凝土输送泵的驱动单元(原动力)所需的功率取决于预期的输出混凝土的流量 Q 和泵送时的压力 p。预期的输出量和泵送时的压力与液压的输出表达示 H 有关,并有如下表达示:=定值pQH如果 Q 用立方米每小时表达,而 p 用帕来表达(1 帕=0.1 N/mm 2),并且假设一个系统的工作效率是 75%。混凝土输送泵的驱动单元(原动力)所需的功率 P 可以用千瓦表示如下:泵送压力一个混凝土泵所能承受的最大泵送压力取决于机械设计单位的问题,特别是混凝土阀门,锥体部分,输送管道等等。总是带有很短的运输管路的车载混凝土泵车,需要泵产生最大的压力在 7 (70 bars )。因此,于是出现了一种典型的车载泵,2mN这种泵的原动力为 90 KW,却能输送最大达到 32.14 立方米每小时的混凝土。如果在某种情况下,对于上述单位,一个泵送压力为 4.5 被视为足够的,2mN那么输出的峰值能够达到 50 立方米每小时。因此,它的意思是,泵送压力及混凝土输出的峰值的数值互成反比。便携式混凝土泵可以在水平距离运送混凝土达 1000 米或 400米的最高垂直距离,这时需要的泵送压力达到 20 (200 bars)。2为了在现场能够达到预定的混凝土输出量,必须尽可能精确地确定所需要的泵送压力,加之预期的混凝土输出,所以选择泵的理性基础更可能合理。想要达到预期的混凝土输出体积应该取决于当前的工作类型和所需工作的进展。主要变量泵压力所依赖的可以列为:全部的导线,运输管道的直径,输出量,混凝土的稠密度和在输出管道内方向的变化。泵送压力从混凝土泵的最大值减小到运输管道的输出末端的值为零。最大的导程将包括总的最远的水平距离或是被泵送的混凝土的垂直高度。最大的导程,在水平和垂直浇注距离方面,还必须考虑到由于运输管道的弯曲和方向变化而25pP9可能增加的泵送距离。在泵送混凝土的流动过程中方向的变化,无疑会对泵机组有更高的要求,这是因为对于不同类型的管道弯曲,却增加相等管道水平长度。一家已经成立的泵送器械制造厂建议道:独立的管道直径,半径为 1 米的 90 度弯曲可能被一段等价的长为 3 米的管道所替代。因此,一个半径为 1 米的 30 度弯曲与水平长度为 1 米的管道等价。例如,在一个管道系统中总计安装的弯曲为 630 度,那么等价的长度可以这样计算出来 630/30=21 1 m=21 m,即 21 米。以运输管道中安装的 90 度弯曲为例,在浇灌吊杆上,通常采用的是半径为 0.25 米的弯曲。对于这种直角弯曲的等价长度的推荐值为 1 m 。因此,对于浇灌吊杆上的水平泵送距离,将会是外部能达到的距离加上在三个铰接部分每个 90 度弯曲所等价的长度,这种铰接在浇灌吊杆上随处可见。垂直泵送距离增加所占的压力增加大约 0.025 (0.25bar)的差异每米的高度2mN泵送压力计算出水平浇注的距离。对于给定的泵送混凝土的输出量,流速和因此产生的流动阻力随着输送管道直径的减小而增加而且也与泵送压力有关。为了说明,一个名义上混凝土输出为 40 立方米/小时的泵,当输送管道的直径按 150 mm, 125 mm, 112 mm 和 100 mm 这样的次序依次减小时,相应的流速分别地按 0.6 m/s, 0.8 m/s, 1.1 m/s 和 1.39 m/s 这样的速度增加。为了限制泵送压力,并尽量避免妨碍管道磨损和撕裂,所以当需要的输出较大时选择较大的运输管径是明智之举。对于较大管径的困难是它们很难控制,尤其是当它们灌满混凝土的时候。不管是软管还是硬管都能用来泵送混凝土,但是硬管更加普遍,因为它和软管相比,有更少的附加摩擦损耗更容易清洗。硬管由钢材制成,可以选取各种长度和壁厚。个别的输送管长度可以取 1 米,2 米,或是 3 米,最常采用的是能承受泵送压力为7-10 。2mN壁厚为 4 mm 的运输管。对于要承受更高的泵送压力(20 或者更大)的运2mN输管,通常建议选取壁厚为 7 mm。通过简易联轴器联结个别管的长度。一个直径为100mm 的运输管对于近距离和中距离(小于 200m),混凝土输出小于 25 是比较h3理想的。对于那些更远的浇注距离和更高的输出量,直径为 125mm 的运输管是最合适的,而且这种运输管的尺寸也是应用最广最理想的。对于直径为 150mm 的运输管通常被用于浇注混凝土管道的最大总大小超过 40 毫米时,或是在更远的地方浇注大量的混凝土。相对来说直径更大一些的运输管道将导致泵送压力减小,降低了对原动力的功率需求但这是以降低了管道网络的机动性为代价的。混凝土混合的稠度与泵送压力有很重要的关系。40mm100mm 的下降或是压实系数为 0.900.95 再或是时间为 3-5 秒或者混凝土稠度在 K3 范围内,这些都是在料斗中通常选择的表达形式。合适的混凝土混合稠密度对于避免运输管道中过高的摩擦阻力是非常必要的,因为太干或是太湿的混合都是不合适的。太干的混凝土很难发生变形10而且需要更大的泵送压力才能使混凝土通过管道中的弯曲和锥形部分。需要指出的是:混凝土稠度的任何变化或是可使用性,在泵送点都能通过测量泵送压力来检测。因此混凝土泵是对搞高混凝土质量的最大帮助之一,它们的作用是默默地控制混凝土的质量,阻止那些过度粗糙的、不合适当混合的、无法附着的或是稠度达不到要求的混凝土通过运输管道。可用泵吸的混凝土需要有足够数量的细颗粒,足够的衰减(大约 80100mm) ,连续的等级分配总数和统一的彻底的混合材料。如果理想的泵送速度达到 40 ,这是非常合适的。一个最大泵送能力为 40 hm3的混凝土泵想要得到预期的输出只要在它连续工作一个小时之后,然而这种情形hm3在施工现场是很难遇到的。实际的泵送时间大约是 45 分钟或是更短的时间。以泵送时间为 45 分钟为例,如果混凝土泵想要达到名义上的 40 的输出,它的浇注速度必hm3须要达到 0.45/0.75 = 60 。上述说明中的实际泵送时间 45 分钟可以看作是混凝土h3泵做功系数的一种形式,在述例子中就可以写成 45/60= 0.752。这样计算是合理的,因为这是针对泵站中最为普遍典型的的情况而言的,以 0.75-0.8 这样的做功系数来确定混凝土泵的实际工作能力。总而言之,对于给定的工作选择混凝土泵的类型最重要的是要按照理想的泵的输出量,需要泵送的混凝土的稠度,在水平和垂直泵送距离方面的最大导程和运输管道的直径。一旦这些参数都已知,接下来的问题就是确定泵送压力。如果知道泵送压力的峰值和理想的混凝土输出量,那么泵的原动力的功率就可以确定,通过下面例子的帮助阐述上述理论。混凝土泵选择示例在一个多层的建筑施工场地,要求泵送混凝土的平均速度达到 40 。浇注吊hm3标能够达到的水平泵送距离是 27m 。混凝土泵的做功系数可以假设为 0.75。直径为125mm 的运输管道的长度包括 5 个 90 的弯曲,各两个 30 的弯曲,总计长为 110 m 。建筑物的最大高度为 65 m 而且浇注吊杆末端离最高楼层距离约为 4 m 。混凝土坍落度为 100 mm 。为了确定所需的泵送压力和泵的原动力的工作能力,以下步骤是可行的。需要的输出(已给定)=40 h3做功系数(已给定)=0.75混凝土坍落度(已给定)=100 mm运输管道直径(已给定)=125 mm名义上的输出=Q=40/0.75 = 53.3 hm3运输管道的水平距离(已给定)=110 m (a)90 弯曲个数 =5 个;90 弯曲的尺寸=90 5=450 1130 弯曲个数 =2 个;30 弯曲的尺寸=30 2=60 总计弯曲尺寸=450 度+60 =510 等价为 30 的弯曲个数 =510 /30 = 1730 的弯曲等价后的水平长度=17/ 1 m = 17 m (b)浇注吊杆的水平范围(已给定)=27 m (c)由于浇注吊杆的标准弯曲的等价管长(假设的)= 10 m (d)等价的总计管的水平长度= (a) + (b) + (c) + (d) = 110 m + 17 m + 27 m+ 10 m = 164 m从图表 3 中可以看出,对应 53.3 m3/h 的输出,100 mm 的混凝土坍落度,164 m的运输管道长度和 125 mm 的管道直径,查得的泵送压力为 34 bars (3.4 N/mm2)。图 3 诺模图垂直导程= 65 m + 4 m = 69 m由垂直的 69 m 的导程而产生的等像静压力= 0.25 * 69 = 17.25 bars (1.72 )2mN因此,最大的泵送压力=34 + 17.25 = 51.25 bars, 即 52 bars (5.2 )2因此,需要的泵的功率=Q p /25=53.3 52 / 25=110 kW 或者说 140 HP12知道了所需的原动力的功率,需要的混凝土的输出和最大的泵送压力,就能够选出与这些参数最相近的混凝土泵,如图 4 所示。图 4 混凝土施工现场结论各种参数的影响与混凝土的特点与在上述的泵送过程中的机械附件有关。混凝土泵的输出,混凝土的稠度,水平和垂直的导程和运输管道的直径都对泵送压力有重要的影响,而泵送压力是关键的设计参数。泵的原动力所需的功率,能够从理想的泵送输出和泵送压力这个参数估计出来。
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