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附錄A譯文
鋼絞線帶式輸送機的發(fā)展
托馬森 (英)
總經理
鋼絞線帶式輸送機有限公司
摘 要:早期帶式輸送機的發(fā)展被認為是與鋼絞線帶式系統(tǒng)相同的需求而發(fā)展起來的,其本質就是各種設計原理與槽形帶式輸送機突出部分的優(yōu)缺點進行比較,而這一部分的發(fā)展恰恰表明,在傳送系統(tǒng)中最可能也最有用的發(fā)展,就是對其外形輪廓的改進,這些使得在一些大型鋼絞線設計建造中,考慮安裝長達52千米的螺紋槽系統(tǒng)(2個)。
鋼絞線帶式輸送機發(fā)展
在1795年時,最初的帶式輸送機不便于操作,而且僅涉及一些簡單的外形,直到1850年后,隨著世界范圍內的谷物貨量大量增加,促使傳送帶技術有了較大的改進。
第一種形式的傳送機是在一個槽形及其內運行的水平傳送帶,其工作原理是引進導輪系統(tǒng)用滾動摩擦來替代滑動摩擦,以便減少傳送中的摩擦損失。隨著需求的不斷增長以及大量的集中裝卸貨物的需要,使得在這一時期最普遍的貨物帶式輸送機。草型帶式輸送機以及鋼絞線帶式輸送機都獲得較大發(fā)展。
在1860年后期,大量使用帶有錐形或蝶形滾動導輪的槽形帶式傳送機,直到1890年才過時被淘汰。1865年傾向于將直線集中器或跨輪引入到傳送機發(fā)明設計中,這使得托馬斯.羅賓在1896年獲得該產品的專利權,被認為是歷史上第一臺槽形帶式輸送機。從那時起,許多重大改進在跨輪傳送帶和操作結構等一些細節(jié)方面。但在1900年早期,所有的槽形帶式輸送機都具有相同的外型,在外型上并沒有改進。
同最初的機器相比,鋼絞線帶式輸送機真正意義上獲得較大成功的發(fā)展是在1952年,而在1859年,最早期的設計形式之一,如圖一所示。
圖中包括兩條平行無較差的皮帶制成膠質的傳送帶,被按一定距離貼附在彎曲的金屬表面上,使得這種帆布式槽形帶式輸送機正常運行,也有許多相似的輸送帶類型,但它們承受從動帶被剛性的貼附在主動帶上,這些基本相同的缺點……這也導致許多缺點……例如:主動帶并不能完全與草圖設計吻合,或者是潤滑劑承受重壓,最終從主動帶脫落等。
圖1
鋼絞線傳動帶系統(tǒng)成功地克服了這些缺點,并且這一技術被大范圍的用在傳送機長距離的應用中。現(xiàn)在一種單臂長54米的螺紋槽系統(tǒng)已經被考慮在設計中。
鋼絞線傳送帶系統(tǒng)設計原理的基本不同在于采用一種圓形的金屬線形式的主動帶,而不是傳統(tǒng)的將從動帶附著在主動帶上。第一步改變致力于克服通過三角皮帶輪式運行中的水平傳送帶被鋼絞線替代所產生的困難。第二步改變是著眼于鋼絞線傳送帶系統(tǒng)本身可以進行操作,這與早期設計的目標恰恰相反。主動帶主要依附于從動帶上,這些鋼絞線被放置在傳送帶表面壓制好的滑軌上,它或許是緊依靠摩擦力是鋼絞線傳送帶在主動帶上向后滑行,然而同所有帶式輸送機依靠摩擦力在傳送帶上運載貨物相比,鋼絞線時僅需滿足在傳送帶和主動鋼絞線間的摩擦力應大于在傳送帶和貨物之間的摩擦力,這應使得傳送帶制動器僅僅牢固在主動鋼絞線上。
鋼絞線帶式輸送機也可用于特殊形式的表面,在斜面?zhèn)魉蜋C整體系統(tǒng)中等級是21,一些特殊形式的可達28,在傳動鋼絞線上不存在打滑脫落的現(xiàn)象。
鋼絞線帶式輸送機伴隨著發(fā)動機進一步發(fā)展而發(fā)展的,當發(fā)動機功率達到300千瓦時(被認為是最杰出的設計);由此而開始建造長達3000米,功率8000千瓦的傳送機。
鋼絞線傳送給與槽形傳送機除在工作方式上不同,其它一些末端的輸出單元是相似的,也聯(lián)合從動帶與主動帶,一個典型的例子是上部的卸貨裝置,如圖2所示:
圖2
明顯地,除傳動單元終端設備之外的其他設備要比傳統(tǒng)的槽形帶式輸送機復雜得多,并且占據(jù)更多的空間,特別是在考慮張力等作用下更是如此,這并不是真正意義上的傳動裝置,而是僅對其功率額定值進行比較,當它滿負載時,需能控制運處的鋼絞線傳送機正常工作。
傳動鋼絞線的張力模數(shù)保持在相對低的水平是為了獲得較低的初始扭矩,并且當每個傳動鋼絞線拉緊時,張力系統(tǒng)需要占據(jù)較大的空間,并且更復雜,如圖3所示:
圖3
后期的鋼絞線帶式輸送機設計理念與傳統(tǒng)的非常相似的,在傳送機中也存在摩擦,并且垂直找平裝置是一系列的懸垂鏈,但如果應用于不同的領域,應考慮各種不同的性能,且考慮降低傳送機的摩擦損失,可以通過減少動件的數(shù)量和重量,這種損失正常值為30%,而額定的摩擦損失取決于工作中的傳送帶與貨物之間的損失,而采用滑輪裝置可大大減少這種損失,理論上測量能答曰降低10%的損失,做一基本比較,這一事實很令人吃驚。關于摩擦損失已經證實往往很難克服,并且所有的觀測數(shù)據(jù)和設計標準,顯示出不同的測試結果,另外摩擦損失取決于各種因素,此外,輸送機摩擦將隨著安裝和維護的溫度,壽命和標準變化。在一些大型設備安裝中,比較部分摩擦值至少在一個基本設計中能看到如下不同之處:
傳統(tǒng)型
鋼絞線型
回轉件數(shù)量
100
76
可動件數(shù)量
100
64
摩擦損失
100
67
鋼絞線帶式輸送機的垂直找平系統(tǒng)與槽形機設計和計算原理是相同的,必須進行反復測試確保懸垂鏈脫落這樣的事情不會發(fā)生。鋼絞線傳送帶被定義為橫向堅固縱向輕柔的帶式輸送機,而從動帶依附于兩條平行主動帶的側翼或邊緣部分。減速齒輪箱和活動單元來對主動鋼絞線進行控制,以及對不同鋼絞線拉伸張力的差別超界調整。此外,每一根主動鋼絞線在工作中允許承受不同的拉伸力。
鋼絞線傳送帶獨特的特點是體現(xiàn)在傳送帶上,最初是一種加強橡膠傳送帶,被鑄造在以450毫米為間隔的彈簧搭接片上,這些搭接片伸出起搭架輪之外,如圖4所示,并且機械的附著在金屬制動器上,橡膠傳送帶與主動鋼絞線相連,這可以被一種鑄造結構所代替,如圖5所示,一些較小的交叉搭接片以間隔100毫米的距離完全鑄造在傳動帶和制動器上,以便使主動鋼絞線僅僅固定在傳動帶邊緣。最近,已經對此作進一步改進,如圖6,當貨物在其上移動時,制動器僅僅控制主動鋼絞線,這也使得當發(fā)生超重時,增加傳送帶的穩(wěn)定性。另外可以采用更好的交叉搭接片。
圖4
圖5
圖6
長期集中使用傳送機,最終得更換傳送帶,這是很正常的,或者是由于表面的摩擦損失造成的,或許是機械性的損壞,但主要取決各個部分的壽命,例如影響橡膠、化合物壽命的因素有熱障、光照和氧化等,因此必須發(fā)展特種橡膠化合物來增加其壽命。
主動鋼絞線的特點使它可以近似的被那些金屬線大小、抗疲勞性和內部的潤滑性符合鋼絞性設計特點的金屬線所代替。有一些敘對變電鍍,同向順捻每一根細金屬線或金屬繩,通常這些金屬性能應達到直徑60毫米,并且斷面負荷達到260噸,隨著鋼絞線帶式系統(tǒng)的張力的增加應特別注意盡量減少金屬線接頭的數(shù)量,當主動鋼絞線承重100噸時,每一部分都是如此。
順著傳送帶每間隔5到10米有一個直徑大約300毫米的三角皮帶輪,顯然這些皮帶輪應具有堅固的齒輪結構,但實際上這些皮帶輪被設計為表面可替換的橡膠值得滑輪,這些滑輪成對出現(xiàn)在交接臂上,傳送帶本身能平衡每一個滑輪上的負載,如圖7所示,在所有的傳動機設計中都應基本的考慮避免鋼絞線脫軌情況發(fā)生,應謹慎的設計懸垂鏈,眾所周知,懸垂鏈本身就能避免滑落,在設計中,鋼絞線帶式系統(tǒng)應用同樣,但是若有效的防止滑落發(fā)生卻極有可能增加負載條件和限制初始扭矩。
圖7
鋼絞線帶式輸送機在設計最主要不同在于將從動傳送帶于主動鋼絞線分開較好的設計方案,應將它們和在一起,而分開它們是方便于在設計上給與更多的靈活性,并且能夠引起傳統(tǒng)帶式輸送機沒有涉及的理念,且能更廣泛的應用在許多領域,傳送帶可以是直得,也可以是彎曲的,如圖8所示,它可以允許達到320°的角度仍保持主動帶的基本特征,但得結合兩個環(huán)形從動帶,這一特征的30﹪ 被用于鋼絞線傳動帶的安裝調試。其他的設計原理廣泛應用于前面提到的,當住主動系統(tǒng)里傳送帶較足時的操作,這一獨特的特征,使得主動單元也可以同某些電子設備相連,但得將其防止在無塵干凈的環(huán)境中,這種靈活性也使得從動裝置可以放置在傳送機的任一點,也可以將貨物直接通過主動鋼絞線傳遞,鋼絞線帶式輸送機的其他部分(拉力系統(tǒng))涉及的獨特性,毫無疑問,它將比槽形帶式輸送機更復雜占據(jù)更多的空間。
圖8
存在許多原因但其最根本原因在于每一條主動鋼絞線和從動帶常須承擔設備的拉力牽引。從動帶上的拉力微不足道的,它必須滿足主動帶上的張力作用,尤其是在一個長的平面輸送機,拉里幾乎都由主動單元承受這種傳送機,在初始指令期間主動鋼絞線的拉伸運動可以替代,在整臺傳送機開動前,這種效應被儲存在從動帶拉力系統(tǒng)中,當然當傳送機停止運行時,將被釋放。在一個長達15000米的傳送機可以被拉伸80米,同槽形帶式輸送機相比,鋼絞線傳送機占據(jù)如此大的空間最主要時期必須滿足主動鋼絞線和長期拉伸和相對高的彈性拉伸作用。固定的拉伸范圍大約是1﹪,在它首次運行幾百小時后,這已被制造商消除在制造階段,但傳統(tǒng)做法還是在鋼絞線接頭處留有足夠的空間,以便于引入額外的鋼絞線時的需要模數(shù)的選擇可以控制彈力,減少彈力,減少所占空間,同時有效的彈性可以保證獲得較低的終止扭矩。
從鍛件方面的信息可以看出鋼絞線帶式系統(tǒng)同槽形帶式系統(tǒng)有許多方面完全相同,但也存在一些不同之處 。大多數(shù)的傳送機是較短的且低功率的,毫無疑問,槽形帶式輸送機帶動許多傳送機的發(fā)展,然而在一些長距離或者起吊升起來運輸貨物的領域,細膠線帶式輸送機展示其特殊優(yōu)點,且其獨特的設計時它來這些領域成為唯一選擇。
若想準確的定義出鋼絞線傳送帶的應用領域是有些困難的,幾乎三分之一被應用于沒有太大的競爭的領域,每一種情況下,它們被選擇是由于某一些方面的特征,基本上鋼絞線傳送帶一般不適合那些短的普通傳送機應用的領域,這主要取決于終端設備的大小,另外終端設備的花費包括傳送機的每一部分,在鋼絞線傳送系統(tǒng)的中,一般不給予考慮動力需求的花費,在摘要中,當前的鋼絞線傳送帶的競爭領域似乎是:
供率低于750千瓦的斜面輸送機,或者是長度少于3000米的水平輸送機,并不是鋼絞線傳送帶的競爭的主要領域。
當這些參量進一步提高時,鋼絞線帶式輸送機選擇的首要產品成為更有競爭力。
在水平輸送機中,摩擦損失的能量是相當大的,這邊增加了鋼絞線傳送帶的運行費用,此外在其他方面并沒有什么本質區(qū)別。
在鋼絞線帶式系統(tǒng)中較有意義的發(fā)展是對當前鍛件的改進,未來幾年這應是首要的花費,在運行費用方面,這包括對主動鋼絞線的每一根金屬線的股線都要加強,最初的試驗結果展示其抗老化、 其壽命是傳統(tǒng)金屬繩的3倍,鋼絞線帶式系統(tǒng)最近的發(fā)展表明,其完全可以同長距離的繩索運輸相競爭。雖然現(xiàn)在還沒有被考慮,當前在澳大利亞西部的Worsley Alumina Ptr:Ltd公司正在建造一個有兩個螺紋槽系統(tǒng),長達52000米鋼絞線帶式輸送機系統(tǒng)。
Worsley Alumina Ptr:Ltd位于西澳大利亞——附近,設備的整體部分由量太鋼絞線帶式輸送機串聯(lián)組成,并且經由陸路運輸將呂土巖從礦山運到精制廠。
在涼臺傳送機交叉處,貨物表皮左旋50°,通過花道進入第二個傳送機,在兩臺輸送機間,主動傳送機的角度和張力單元系統(tǒng)都應相互協(xié)調、適應。傳送機必須標準化且?guī)缀醺鞑考慵苫Q。
長度 31000米 21000米
標高 72米 14米
貨物 鋁土巖
密度 1520kb/m3
額定功率2040m.t.p.h
年產量(噸) 9.06×106
帶寬 900毫米
運行速度 6.35m/s
主動帶 57千米(直徑)
間距 4.75米
功率 5300kw 3600kw
如果條件許可,鋼絞線傳送機將能獲得進一步發(fā)展,可以將傳送帶的長度擴展到更長。
作者非常感謝得到Worsley Alumna Pty.Ltd公司的幫助和相關的資料。
本文涉及:
1.傳送帶輸送機的標高——來自Hetzel and Albright John Wiley & sons
2.帶式輸送機的抗阻力數(shù)據(jù)——來自H.P.Lachman .
附錄B外文文獻
DEVELOPMENT OF THE CABLE BELT CONVEYOR
lan Main Thomson BSc (Eng.)
Managing Director
Cable Belt Ltd
Summary
The early development of belt Conveying is discussed showing how the Cable belt system developed from the same requirements. The various design concepts are compared with those of the troughed belt conveyor highlighting the areas of advantage and disadvantage.
The areas of conveying where the Cable Belt system is most useful and the likely developments are outlined. These and other developments have led to many major conveyor installations including a 2 flight 52 km system being constructed to the Cable Belt design.
Development of the Cable Belt Conveyor
The origin of the belt conveyor is not easy to clearly identify but there are references to simple forms as early as 1795. However it was not until the dramatic increase in the world trading of grain after 1850 that major improvements were made1.
The first form of conveyor was a flat belt running in a trough which was quickly improved by the introduction of straight idlers to replace sliding friction by rolling friction. The need to increase the capacity and centralise the material load led to the appearance at the same time of both of the most common forms of heavy duty belt conveyors, the troughed belt conveyor and the Cable Belt conveyor.
In the late 1860's the use in troughed belt conveyors of straight rollers with conical or dished ends was obsolete until the early 1890's. The introduction in 1865 of inclined straight 'concentrator' idlers led to the conveyor in the Thomas Robins Jnr. patent of 1896, which is regarded as the first troughed belt conveyor. Since that date whilst there have been many important improvements in the detail of the idler, belt and drive construction, the basic concept of the troughed belt conveyor is the same as outlined in the work completed in the early 1900's.
The Cable Belt conveyor principle whilst of earlier origin was not developed in a truly successful form until 1952.
One of the earliest forms was that developed in 1859 and shown in the sketch fig. 1. This consisted of two parallel endless leather or rubber belts to which were attached at intervals curved meta1 spreaders supporting a canvas trough. There were many other similar conveyors but they all suffered from the same basic defect that the carrying belt was rigidly attached to the driving belts. This led to the disadvantages that the drive belts do not stretch alike and that the spreader bars are stressed and eventually break free from the drive belts.
The Cable Belt system successfully overcame these defects and since its introduction has generally been accepted in the conveyor field for Long distance applications. A substantial proportion of the single flight conveyors over 5 km long that have been installed are now of the Cable Belt design.
The fundamental design differences made in the Cable Belt system were to use a round drive belt in the form of a wire rope, and not to attach the carrying belt to the drive belts. The first of these changes was aimed at getting over the difficulty of training to run in parallel a pair of flat belts by substituting positively located round cables running in grooved pulleys.
Early Belt Conveyor Fig 1
The second change was the point that allowed the Cable Belt system to operate successfully in contrast to the other earlier attempts. The carrying belt merely rests on the drive cables, these cables sitting within shoes which are moulded on the be1t surfaces. It may seem that depending on friction alone the Cable Belt is liable to have the belt slip backwards on the drive cables. However as all belt conveyors depend on friction between the belt and the material carried to allow them to operate at all, the only requirement is that the friction between the belt and the drive cables should be greater than between the belt and the material. This was achieved by shaping the belt shoes to grip the drive cables.
It has been possible using Cable Belt belting with specially formed surfaces to run on slope conveyor systems where the overall grade is 21° and with particular sections of 28°, without experiencing slipping of the belt on the drive cables.
Whilst the Cable Belt conveyor was developed at a time when the powers available of up to 300 kW were regarded as outstanding the basic concept is still retained even when now, single conveyors of 30000 metre length and 8000 kW power are being built.
The terminal units are similar to those in a conventional troughed conveyor except that they also serve to separate and rejoin the carrying belt and drive cables. A typical example of a head discharge unit is shown in fig. 2.
Obviously the terminals other than the drive unit are more complex than in a conventional troughed conveyor and take up more space particularly in the case of the tensioning arrangements. This is not true of the drive as for a comparable power rating it is compact and has the advantage that it can be located remote from the Cable Belt conveyor belt line.
Head Discharge Unit Fig 2
As the modulus of elasticity of the drive cables is kept relatively low in order to allow the use of very low starting torques and each drive cable is tensioned, the tension system does require substantial take-up space and is more complex as is illustrated in fig. 3.
Typical Tensioning Arrangement Fig 3
The concepts behind the design of the Cable Belt conveyor are very similar to a conventional conveyor in that there is conveyor friction and the vertical alignment is a series of catenaries but of course the factors used vary considerably because of the different characteristics.
The conveyor friction losses are considerably reduced principally because of the significantly lower number and weight of moving parts in a comparable system.
This reduction is normally in the order of 30%. In addition the friction losses due to the working of belt and material as they pass over the idlers are significantly less. it has been determined empirically that there is in the order of a 10% reduction in the friction losses.
The establishing of the facts, even on a comparative basis, with regard to conveyor friction has proved difficult as all the data is empirical and the various design standards can show markedly different results. In addition conveyor friction will vary with temperature, age and standards of installation and maintenance. However in a recent major installation it has been possible to compare the friction values, at least on a design basis and as can be seen below these bear out the differences.
Conventional
Cable Belt
Number of Rotating Parts
100
76
Weight of Moving Parts
100
64
Friction Losses
100
67
In determining the vertical alignment of the Cable Belt system whilst the formulae and calculation are the same, great care must be exercised as it is not possible to allow 'lift off' in catenaries to occur.
Early Cable Belt Belting Fig 4
Intermediate Cable Belt Belting Fig 5
Modern Cable Belt Belting Fig 6
The Cable Belt is best defined as a belt conveyor with a laterally rigid but longitudinally flexible carrying belt which is supported at or near its edges on two parallel endless looms of drive cable, these cables in turn being supported at intervals by grooved pul1eys. The integral reduction gear and drive unit drives both drive cab1es and incorporates a differential to equalise tensions in the cables. In addition each of the drive cable circuits is separately tensioned to allow for the differential stretch of these during operation.
The unique feature of the Cable Belt system is the belt. Originally this was a fabric reinforced rubber belt which had moulded into it spring steel straps at 450 mm intervals. These straps protruded beyond the edges of the bell as illustrated in fig. 4, and had mechanically attached to them a metal shoe with rubber Lining where it gripped the drive cable. This was superseded by a one piece moulded construction shown in fig. 5. where smaller cross section straps at intervals of 100 mm were moulded entirely within the belt and the shoes to grip the drive cables were continuous mouldings along the edge of the belt.
Typical 4 Pulley Line Stand Fig 7
Recently a further change was made, illustrated in fig. 7whereby the shoes which grip the drive cable on the material carrying run have been moved inwards. This increases the stability of the belt when subjected to overloading and in addition allows the use of smaller cross section straps.
Angle Station Fig 8
It is normal that on a typical long centre conveyor the eventual replacement of the belt is not for reasons of abrasion of the surface or mechanical damage, but due to the various ageing processes that affect rubber compounds such as heat, sunlight, and ozone. As a result it has been necessary to develop special synthetic rubber compounds that are inherently resistant to ageing.
The specification of the drive cables whilst similar superficially to a normal wire rope are specially made to a Cable Belt specification with design criteria laid down for individual wire size, fatigue life and internal lubrication. They are of galvanised construction, Lang's Lay with either a fibre or wire rope core. Currently they are used in sizes up to 60 mm diameter and breaking loads of 260 tonnes. As this is the tension reinforcing member of the Cable Belt system great attention is paid to reducing the number of splices and drive cables of up to 100 tonnes weight for each section have been used.
Along the line of the conveyor it is supported at intervals of between 5 and 10 metres by grooved pulleys approximately 300 mm in diameter. Previously these pulleys were of a hardened steel construction but the current design is for a pulley with a replacement rubber lined tread. These pulleys are mounted in pairs on articulated arms which allow the conveyor to self align and equalise the loads on each pulley as can be seen in fig. 8.
Whilst this condition is normally avoided in all conveyor design, it is essential, to prevent derailment of the drive cables, to design catenaries correctly and conservatively.
As is well known the normal catenary formulae are approximations which allow a factor of safety against 'lift off'. In designing the Cable Belt system the same formulae and factors are used, but effectively the protection against 'lift off' is increased by determining worst possible loading conditions and limiting the starting torques. This situation is helped in that the conveyor friction is such and modulus of the drive cables is selected to ensure that there is virtually no additional breakaway torque required even to start a long flat overland Cable Belt system.
The major difference in designing a Cable Belt conveyor lies in the separation of the carrying belt and the drive cables. Whilst good design practice requires that they should be kept together, the ability to separate them does give considerable flexibility in design and allows the introduction of concepts unknown in the conventional belt conveyor. The most widely used of these is in the many circumstances where a straight line route or one incorporating curves is not feasible, and the unit known as an angle station is employed. As can be seen from fig. 9 this allows any angle up to 320° to be accommodated and still retain the feature of a single drive but incorporate two separate carrying belt circuits. This feature is used in about 30% of the Cable Belt installations. The other concept that is widely used is as mentioned earlier, the ability to place the drive unit remote from the belt line. This feature, which is unique, allows the drive unit and its associated electrical equipment to be located in a position with easy access for maintenance but away from the dust and dirt associated with a conveyor discharge or return belt line. This flexibility also allows the drive unit to be placed at any point in the conveyor, including if necessary on the material carrying run of the drive cables.
The other part of the Cable Belt design that is unique is the tensioning system and there is no doubt that this is more complex and takes greater space than would be required in a troughed belt conveyor. There are several reasons for this but the principal reason is the necessity to provide equipment to separately tension each drive cable and the carrying belt. Whilst the tension in the carrying belt is nominal it is still necessary to cater for the drive cable tension movement, particularly in long flat conveyors which, of necessity, are tensioned at or near the drive unit. In such conveyors the tension movement of the drive cables is substantial during the start sequence. Before the whole conveyor is moving the effect is that it is necessary to 'store' in the carrying belt tension system a length of belt equivalent to the elastic stretch of the drive cables. This of course is released when the conveyor stops. In a typical 15000 metre long conveyor this stretch can be up to 80 metres.
The main reason for taking up a greater space than a troughed belt conveyor is the necessity to cater for both the permanent stretch and the relatively high elastic stretch of the drive cables. The permanent stretch of about 1% which occurs in the first few hundred hours of running could be eliminated during manufacture but it conveniently provides the necessary space for splicing of the cable as well as generating extra cable which can be used when resplicing is necessary The choice of the modulus that governs the elastic stretch is a compromise between minimising the stretch to reduce the space requirements and having sufficient stretch to ensure very low 'breakaway' torques.
As can be seen from the foregoing information the Cable Belt system while fulfilling the same role in many ways is quite different from the troughed belt conveyor. As most conveyors are of short length and low horsepower there is no doubt that the troughed belt conveyor is the correct solution for many conveyor applications. However in those areas of long lengths or high lifts the Cable Belt system often shows decisive advantages and in those cases where its unique design concepts can be used it may be the only choice.
To define the precise applications which a Cable Belt system is suitable for is difficult, as nearly one third of the systems installed are in applications in which they were not the most competitive solution. In each case they were chosen for one of the unusual features that the system offers. As a general rule the Cable Belt in its current form is not technically suitable for short centre conveyors mainly due to the size of the terminals. In addition to the cost of the terminal equipment the main cost component of any belt conveyor, the belt, in the Cable Belt system has a constant cost irrespective of the power requirements. This 1oads the capital cost on low powe