ordinary lay wire rope quotation

Left hand lay or right hand lay describe the manner in which the strands are laid to form the rope. To determine the lay of strands in the rope, a viewer looks at the rope as it points away from them. If the strands appear to turn in a clockwise direction, or like a right-hand thread, as the strands progress away from the viewer, the rope has a right hand lay. The picture of steel wire rope on this page shows a rope with right hand lay. If the strands appear to turn in an anti-clockwise direction, or like a left-hand thread, as the strands progress away from the viewer, the rope has a left hand lay. (The rope in the left hand lay photo shows one left hand lay rope from left to right and top to bottom, with 5 right hand lay strands, and part of a sixth in the upper left. It is not 5 right hand lay ropes adjacent to each other.)

Ordinary and Ducay"s lay describe the manner in which the wires are laid to form a strand of the wire rope. To determine which has been used, first identify if left or right hand lay has been used to make the rope. Then identify if a right or left hand lay has been used to twist the wires in each strand. (On ordinary lay, the outer wires approximately follow the alignment of the rope: with Lang"s lay they are cross at an angle of about 45�.) Lang"s laid rope is able to flex over sheaves more easily (with less damage) but it has the disadvantage of having a high torque tendency (it tends to untwist when tension load is applied) compared with ordinary laid rope. Untwisting can be dangerous with a steel-cored rope: load is shed from the strands and may cause the core to fail as it becomes higher loaded. For this reason, swivel termination units can be dangerous.

The specification of a wire rope type � including the number of wires per strand, the number of strands, and the lay of the rope � is documented using a commonly accepted coding system, consisting of a number of abbreviations.

Understand that most of the people out from the industry always face the problem of having no idea with the terms of wire rope when receiving quotation. In this update, we will explain in the most simple way and hopefully it is applicable to anyone.

6X36 = Construction of wire rope (There are quite a lot different constructions available for different application for example like, 6X25, 6X29, 6X31, 4X39, 19X7, 8X26 etc.)

RHOL = Right hand ordinary lay, it is the wire lay direction and very important to select the right direction of wire when dealing with multi-reeving, crane and hoist application.

EIPS (1960) = Extra improved plow steel and 1960 stands for the tensile strength 1960N/mm2. The figure is telling you the grade of wire rope, lower or higher tensile strength will result in different breaking strength.

UNGALVD = Ungalvanized, the surface finishing of wire rope. Galvanized and Ungalvanized are the basic surface finishing selection with different grade of lubrication.

MECH SPLICED = Mechanical splicing is the process of using hydraulic pressure to press the aluminum sleeve or metal sleeve and a loop is formed. This phrase is always telling you the terminal of both end wire rope. It can be plain, socketed, fuse tapered or eye formed.

Wire rope could have a lot of variation upon the application which I will cover in the next update. The essay above is good enough to tell the basic and hope it helps for procurement department while dealing with steel wire rope. Last but not least, selecting the right wire rope is crucial to your company"s long term expenditure and safety purposes. Do not take the risk because of cheap.

LKS ropes not only satisfy users in Asia: we traditionally also supply customers in the Alps region, Scandinavia and elsewhere via our dealers. Our tried and tested forestry ropes are usually peened in order to generate a higher metallic cross section and thus higher breaking forces, and in order to create as smooth a rope surface as possible. In particular in rocky terrain, this offers fewer contact surfaces that can be damaged. The use of peened ropes is also advantageous with multi-layer winding on rope winches. Furthermore, the service life of the rope can be significantly increased by special lubrication which, in particular, substantially reduces friction and corrosion.

The wire rope we supply for this type of work is a high quality galvanized steel wire rope which is available in two constructions; 6 x 24 and 6 x 16. They have a fibre rope core in order to give them good flexibility. This is required when using forestry rope for wrapping around trees and logs.

Rope Services Direct has its own machinery to allow us to press and splice any end fitting to your chosen rope. This will enable you to have a customised rope tailor made for your operation. It may be just a simple wire rope sling which you can use in a choker hitch, or it may be a wire rope to be used in a winch. We can help with all you forestry needs so call us on 01384 78004 for advice, enquiries or quotes.

The LKS 8-7 CP is a rope with 8 compacted outer strands and plastic padding. This combination provides high breaking forces and high stability, coupled with enhanced protection from inner rope damages and enviorenmental influences.

The length of lay of a strand is the lead of an external wire measured parallel to the strand’s longitudinal axis as it makes a complete spiral around the axis of the strand.

When discussing the physical properties of wire rope, people often focus on the material, strength, and size specifications above all else. While these details are essential to understand how a product will survive in the field, they are not the only factors that drive cable performance. In fact, the lay direction of a cablehas as much impact on its functionality as any of the other aforementioned characteristics, because it determines how much a cable will rotate, twist, and kink.

Lay direction describes the relationship between the way wires are wrapped into strands, and the way those strands are wrapped into wire ropes and cables. In general, there are two different configurations of lay directions: regular lay, and lang lay, which can rotate either to the left or to the right.

In a regular lay cable, the wires and strands are laid opposite to each other. In other words, all of the wires are laid in one direction as they are made into strands, and those strands are then laid in the opposite direction of the wires as they are combined into cable. When looking along a length of regular lay cable, the wires will appear to run parallel and straight the entire way. You can tell a cableis right regular lay because the strands will all flow to the right, or clockwise direction, compared to a regular left lay cable which flows the strands in a leftward, counterclockwise direction.

In a lang lay configuration, the wires and strands are laid in the same direction. If all the wires are laid to the right as they are made into strands, then those strands will also be laid to the right as they are combined into cable. The same applies to a left lang lay configuration, where both the wires and strands would lay to the left. When looking along a length of lang lay cable, the wires will appear to angle across the rope, following the general flow of the strands. You can tell a cable is a right lang lay cable because both the wires and strands will flow rightward, in a clockwise direction. A left lang lay cable flows both wires and strands in a leftward, counterclockwise direction.

Cable is generally manufactured with a standard right regular lay because it is useful for a variety of different applications and complies with most equipment. In general, regular lay cable is more resistant to crushing forces than lang lay cable of an identical material and size, though lang lay cable is typically more flexible. Lang lay cables are usually more susceptible to pinching and kinking than regular lay, which means they are better suited to hoisting applications where the cable only moves along one axis.

In summary, the wires and strands in regular lay cable flow in opposite directions while the wires and strands in lang lay cable flow in the same direction. Lang lay cable is great for lifting, hoisting, and push-pull applications, while regular lay cable outperforms in situations where bends are required. To learn about our range of flexible, non-rotating, and non-flexible wire rope and aircraft cable, visit https://strandcore.com/products/aircraft-cable/ or contact us at https://strandcore.com/contact/.

It is important to attach steel wire ropes at the correct locations on a smooth drum as improper winding methods will cause the spreading of terns in the first layer of steel wire ropes on the drum. Then the second layer of wire ropes may be wedged between the open coils of first layer, crushing and flattening the rope as successive layers are spooled.

Generally, steel wire ropes are wound from the top of the one reel to the top of another or from the bottom to bottom. But how to start wire ropes on a drum may puzzle lots of our customers. The following illustration will give you the best solution.

The lay of wire in the strand is right, and the lay of the strand in the rope is left. This is called left hand ordinary lay (SZ) wire rope. The wire of this wire rope is not easy to separate when it is squeezed. Although its softness is not so good, this wire rope is able to bear large bending stress. This wire rope is widely used in balanced ropes for vertical shafts.

Wire rope strength in the United States is typically shown in tons of 2,000 lbs. The wire rope strength is shown as minimum breaking force (MBF). This is a calculated strength that has been accepted by the wire rope industry. When tested on a tensile machine, a new rope will break at a value equal to- or higher than – the minimum breaking force shown for that rope. The published values apply to new, unused rope. A rope should never operate at – or near- the minimum breaking force. The minimum breaking force of the rope must be divided by the design factor required for the application to determine the maximum load allowed on the rope. During its useful life, a rope loses strength gradually due to natural causes such as surface wear and metal fatigue.

Fatigue resistance involves fatigue of the wire used to make up a rope. To have high fatigue resistance, wires must be capable of bending repeatedly under stress – for example, as a loaded rope passes over a sheave during operation. Increased fatigues resistance is achieved in a rope design by using a large number of wires. It involves both the wire properties and rope construction. In general, a rope made of many wires will have greater fatigue resistance than a same – size rope made of fewer, larger wires because smaller wires have a greater ability to bend as a rope passes over a sheave or around drums. To overcome the effects of fatigue, ropes must never bend over sheaves or drums with a diameter so small as to bend wires excessively. Standard for specific applications contain requirements for minimum sheave and drum sizes. Every rope is subject to metal fatigue from bending stress while in operation, and therefore the rope’s strength gradually diminishes as the rope is used.

Crushing is the effect of external pressure on a rope, which damages it by distorting the cross-section shape of the rope, its strands or core -or all three. Crushing resistance therefore is a rope’s ability to withstand or resist external forces, and is a term generally used to express comparison between ropes. When a rope is damaged by crushing, the wires, strands and core are prevented from moving and adjusting normally during operation. In general, IWRC ropes are more crush

resistant than fiber core ropes. Regular lay ropes are more crush resistant than lang lay ropes. 6-strand ropes have greater crush resistance than 8-strand ropes or 19-strand ropes. Compacted strand ropes are more resistant than standard round-strand ropes.

When a load is placed on a rope, torque is created within the rope as wires and strands try to straighten out. This is normal and the rope is designed to operate with this load-induced torque. However, this torque can cause both single part and multiple part hoisting systems to rotate. Load induced torque can be reduced by specially designed ropes. In standard 6 and 8- strand ropes, the torques produced by the outer strands and the IWRC are in the same direction and add together. In rotation-resistant ropes, the lay of the outer strands is in the opposite direction to the lay of the inner strands, thus the torques produced are in opposite directions and the torques subtract from each other.

Alternate Lay, sometimes referred to as reverse lay, is a standard rope where the type of lay of the outer strands is alternately regular lay followed by lang lay such that three of the outer strands are regular lay and three are lang lay.

An important consideration in wire rope construction is the way the wires have been laid to form strands and the way the strands have been laid around the core.

Lay is classified by both direction and type. The lay direction of the wires within a strand and of the strands within a rope is either left or right. Rope lay is further classified as either regular or lang. In a regular lay rope, the wires in the strands are laid in the opposite direction as the strands in the rope. In a lang lay rope, the wires in the strands are laid in the same direction as the strands in the rope.

Regular and lang lay ropes are easily identified by the appareance of the outer wires with respect to the rope axis as shown by the examples to the right.

Right regular and right lang are the most common types of lay in use. Each possesses unique characteristics important to proper selection. Wire rope can be manufactured with five types of lay.

Regular lay ropes are generally more stable and more resistant to crushing. Lang lay ropes are significantly superior in fatigue and abrasion resistance. However, lang lay ropes are more susceptible to crushing and require good winding conditions. They are also extremely prone to rotate under load; they must never be used unless both ends are restrained.

Alternate lay rope combines the best features of regular and lang lay ropes. It offers the advantages of both constructions while minimizing the disadvantages. This construction is ideal where high bending stresses (fatigue) are combined with high rope-to-sheave pressure (crushing); for example, as applied to boom hoist rope.

Combinations of lays are sometimes employed to achieve rotation resistant properties. In this 19 x 7 rope, (as well as in 8 x 19 IWRC Rotation Resistant rope), the extreme rotational property of lang lay rope is used in the core to counteract the tendency of the outer regular lay strands to rotate in the opposite direction.

Regular laydenotes rope in which the wires are twisted in one direction, and the strands in the opposite direction to form the rope. The wires appear to run roughly parallel to the center line of the rope. Due to the difference in direction between the wires and strand, regular lay ropes are less likely to untwist or kink. Regular lay ropes are also less subject to failure from crushing and distortion because of the shorter length of exposed outer wires.

Lang layis the opposite; the wires and strands spiral in the same direction and appear to run at a diagonal to the center line of the rope. Due to the longer length of exposed outer wires, lang lay ropes have greater flexibility and abrasion resistance than do regular lay ropes. Greater care, however, must be exercised in handling and spooling lang lay ropes. These ropes are more likely to twist, kink and crush than regular lay ropes.

Right or left layrefers to the direction in which the strands rotate around the wire rope. If the strands rotate around the rope in a clockwise direction (as the threads do in a right hand bolt), the rope is said to be right lay. When the strands rotate in a counterclockwise direction (as the threads do in a left hand bolt), the rope is left lay.

When a lay-length is used as a unit of measure, it refers to the linear distance a single strand extends in making one complete turn around the rope. Lay-length is measured in a straight line parallel to the center line of the rope, not by following the path of the strand. The appropriate time to replace a wire rope in service is frequently determined by counting the number of broken wires in the length of one rope lay.

Wire rope is a machine! It is the workhorse that lifts the heavy loads on wire rope hoists. As a crane technician, there is an endless amount of information you should know about wire rope. The more you understand, the better resource you can be to your customers. Luckily, you don’t need to be the expert! There are others to help you out including, crane and hoist manufacturers, wire rope manufacturers, and other crane technicians. In this article, we will talk about how Demag designs wire rope hoists, selects the wire rope for models that you can buy today, and those you will still find in the field for inspections and repair.

In the world of wire rope, lay has many meanings and definitions. First, we will go through the directional meanings. Lay can refer to the direction in which the strands are twisted around the core of the wire rope. When left hand and right hand lay is referred to like this, it is describing whether the strands are twisted clockwise (left hand) or counter-clockwise (right hand) around the core. For a frame of reference, grab the wire rope in either hand with your thumb pointing up. When the strand appears as if going up to the left, this is a Left Hand lay rope. When it appears as though it is going up to the right, this is a Right Hand lay.

Lay can also refer to the cut of the groove corkscrew in the drum and the corkscrew can go to the left or right. The wire rope will start gathering on the left-hand side of the drum in the case of a left lay and the opposite for right lay. One way to determine this is to look at the drum from the end where the rope is clamped. The term lay can be used to describe the distance of a complete wrap of a strand once around the core. When conducting a wire rope inspection, knowing how to measure the lay is critical. It is measured by determining the distance starting on the outside wrapping the strand one complete time back to the same outside position. This measurement is used to determine the maximum number of broken wires allowed within a single lay and for the number of broken wires in the same strand in a lay. Always consult your inspection criteria bodies, like CMAA and HMI, for the most up-to-date standards.

Lay can also denote whether a rope is Regular Lay or Lang Lay. Regular lay and Lang lay rope are different types of wire rope and differ based on the wire orientation in the strand. Regular lay rope wire appears as though the outermost wire surface is aligned parallel with the centerline of the wire rope axis. Lang lay rope wires appears to be at a 45 degree angle with the wire rope centerline axis. Lang lay type of rope allows for more surface contact with the groove surface on the drum or sheave, increasing the support zone and decreasing the load by spreading it out over a larger area. It is more costly to manufacture, but it can be used in special cases where better wear life for the drum and sheaves is needed. Today, Regular Lay rope is commonly used unless there is a specific design need to use Lang Lay wire rope.

Countries and industries may have different standards or best practices for wire rope. In the USA, the wire rope industry recommends using a Right Hand (RH) lay rope on a Left Hand (LH) drum corkscrew and a Left Hand (LH) lay rope on a Right Hand (RH) drum corkscrew. This is recommended for good spooling of the rope, especially on a grooveless drum. In most cases, Demag designs their wire rope hoists in violation of this best practice, but for a major engineering reason that benefits the user and for additional safety.

Demag wire rope hoists are designed for RH rope on a RH drum and LH rope on a LH drum. This design creates straighter drops of wire rope down to the bottom block as using the same strand lay and corkscrew twists the strands tighter around the core. The straighter drop eliminates interference in a 4/1 reeving configuration as the rope crisscrosses during lifting. This becomes very apparent when the lift height is around the 70 foot range. To make sure that the hoist has positive spooling, the drum is designed with a partial groove and is equipped with a rope guide with pressure rollers or a ring that keeps the rope in the groove.

When it comes to hoists configured for 4/2 reeving with 2 attachment points for the same rope, only one side of the drum follows the best practice. Since there are 2 attachment points in 4/2 reeving, one drum corkscrew is RH and the other LH. Inherent from the reeving design, close to vertical lifting is achieved and crisscrossing interference is not a concern.

Due to wear on the drum and sheaves, we will never recommend changing the lay of the rope used on a hoist when the wire rope needs changed. The existing wire rope lay has already established wear patterns on the drum and sheave that could make changing the rope with a different lay dangerous. Being able to identify or find out what type of rope is used on a wire rope hoist is key to success when wire rope needs changed.

Wire rope is a complex machine, lifting the heaviest loads like space shuttles and precast concrete components. It does the heavy lifting when a load is being lifted by a crane and wire rope hoist. Having a good understanding of wire rope is essential for all crane technicians. Being able to understand what lay means and how to determine what kind of rope is on an existing hoist is just the beginning. Not only will this knowledge allow you to be a more effective technician for your customers, but you can promote safety in the industry.

I’d like to pass along some insight into what makes these slings, from their construction to the maintenance and inspections that keeps them safe but, at the same time, don’t want to make your eyes bleed. That said, today, we’ll cover wire rope and we’ll cover the other sling types in future installments.

So we all know wire rope derives its strength from the strands of wire that are twisted around a core cable, right? You may ask what else is there to know about their construction beyond that. Well, frankly, a lot.

Our rental fleet has sizes of wire rope ranging from 3/4” up to 4” in diameter for single part slings and 2-1/2″ to 11″ diameter in our 9-part braided slings, but there are larger varieties available for purchase. Each wire rope sling is made up of several strands, which is then twisted in a helix around a central strand that is often the same composition as the outer strands. A wire rope strand is typically made up of anywhere between 19 and 36 wires but can reach as high as 109 wires, which are then twisted around a core wire or strand, depending on the configuration of wire rope.

Knowing the composition of the sling you’re using gives an understanding of what the rope will be able to do or, in some cases, how it will act. Various configurations exist to combat crushing, allow for greater flexibility or reduce the chances of rotation among other things. Ensuring you’ve got the correct wire for the project can be the difference between a successful job or causing damage or complete failure. As a general rule of thumb, improving one aspect will tend to reduce another. For example, a wire rope made up of smaller diameter wires provides increased flexibility, but doesn’t offer great abrasion resistance, whereas a wire rope of larger wires increases abrasion resistance while remaining more rigid.

The most common configuration of wire rope, the 6×19 class, consists of six outer strands comprised of 15-26 wires each that are twisted around a center core of smaller diameter wires in a 6×19 configuration consisting of the same number of wires as the outer strands. This configuration offers greater abrasion and crushing resistance while sacrificing a bit of flexibility and is available in sizes ranging from 3/4″ to 1-1/8” outer diameter. The next variation, for thicker outside diameters, is the 6×36 class comprised of six outer strands made up of 27-49 wires. This configuration offers increased flexibility due to the thinner wire diameters while maintaining crushing resistance but does sacrifice some of the abrasion resistance seen on the 6×19 class. LGH has 6×19 and 6×36 wire ropes from 1-1/4” to 4” outside diameter ranging from 5.6 to 130 tons safe working load (SWL) as well as 9-part braided slings that range from 59 tons to 485 tons SWL.

The next aspect of wire rope to consider is the lay of the wires that make up the strands as well as the way the strands are laid around the core. There are two main classifications of wire rope lay seen with alternating directions within each. These classifications are Regular Lay and Lang Lay.

Regular Lay wire ropes are formed with the wires that make up the strands being twisted in one direction, either left or right, and the completed strands are then laid the opposite direction, which causes the finished product to appear like the wires are running parallel to the axis of the rope. Regular lay rope is more flexible and carries better resistance to crushing forces and is easier to splice than Lang lay rope but has a shorter lifespan. Regular lay rope also tends to spool on a drum more easily and is naturally more rotation resistant.

Both regular and Lang lay can be spun clockwise (right lay) or counterclockwise (left lay) as seen in the photo above. The starting point and spooling direction of your winch drum will determine which direction is appropriate for your project.

Lang Lay wire ropes have both the wires forming the strands and the finished strands twisted the same direction, either right or left, and causes the finished product to appear with the wires running diagonally to the axis of the rope. The advantage of Lang lay rope is the increased abrasion resistance leading to a longer lifespan, but that comes at the price of flexibility.

During production, wire rope is heavily lubricated, allowing the lubricant to penetrate throughout the entire rope and into the core, which allows for slight movement of the individual wires within the rope to increase the lifespan of the rope as well as to reduce friction of the ropes as they rub against one another. From this point, maintaining proper lubrication is critical in preserving the life and structure of the wire rope and should be addressed with a combination of penetrating and coating lubricants. Penetrating lubricants reach the core and coat each strand of wire by utilizing petroleum solvent that evaporates once it reaches into the core and leaves the lubricants behind. Coating lubricants would then be used to seal the outside of the cable from moisture and reduce wear and corrosion during use.

The Discover television series “How It’s Made?” came out with an episode in 2011 showing the production of wire rope as well as crane cable and would make for an interesting view if you have five minutes available, providing further insight into the intricacies of wire rope and its composition. You can find that video here.

For more information or to rent wire rope slings and accompanying equipment, reach out to Lifting Gear Hire at www.rentlgh.com or call us at 800-878-7305.

There are many different sizes, configurations, and materials that form wire rope, and these are different types including stainless steel wire rope, galvanized wire rope, and bright wire rope.

Looking for accessories to use with wire ropes? Our rigging supplies include hardware and accessories for use with cranes, hoists & winches, and oilfield applications.

Diameter:To properly measure the diameter of steel wire ropes, measure the rope at its widest point. This is an industry standard with wire cable manufacturers and steel cable suppliers.

Grade of Steel – EIPS, EEIPS: EIPS is Extra Improved Plowed Steel and has roughly 10% more strength than IPS. EEIPS is Extra Extra Improved Plowed Steel and is approximately 10% stronger than the EIPS. We offer every variety of EIPS Wire Rope and have a one day lead time on any EEIPS ropes.

Direction of Lay: Right hand and left hand designates which way the strands wrap around the core of the steel rope. Regular lay and Lang lay specify which way the wires are formed in the helix pattern. Regular lay means the wires are rotated opposite the direction of the strands around the core. Lang lay means the wires are twisted in the same direction as the strands are wrapped around the wire rope core.

Finish – Bright Wire, Galvanized Wire, and Stainless Steel: Most wire ropes have a bright, self-colored finish hence the name. Wire ropes generally have a coating of lubricant to reduce friction and protect from corrosion. However, there are wire ropes that are galvanized, stainless steel, or coated in vinyl and other plastics.

Material of the Core: Fiber Core (FC) or Independent Wire Rope Core (IWRC) – Fiber cores are made of natural (sisal, etc.) or synthetic (polypropylene, etc.) fibers and allow for increased flexibility. IWRC offers more support to the outer strands, and have a higher resistance to crushing. IWRC also offers more resistance to heat, reduces the amount of stretch, and increases the strength of the rope.

Strands: Another variable in wire rope is how many strands make up the rope and how many wires make up one strand. For instance, a 6×26 wire rope has 6 strands around a core with 26 wires making up each strand. The 6×19 class is the most common and offers higher resistance to abrasion whereas the 6×37 class offers higher flexibility.

Although there are exceptions for special applications, the constructions in 6×36 classification are primarily designed to be the most efficient for each rope diameter. As the rope size increases, for instance, a large number of wires can be used to achieve required fatigue resistance, and still those wires will be large enough to offer adequate resistance to abrasion.

The 6×19 classification of wire ropes includes standard 6 strand, round strand ropes with 16 through 26 wires per strand. This is a good rope to withstand abrasion or crushing on the drum. Ropes with independent wire rope strands and a core (IWRC) in general, are more crush resistant than fiber core ropes.

When you purchase our 6×19 Class of wire ropes, you get more than just another rope. Manufactured in an ISO 9001 certified factory and backed by the industry’s largest staff of professional engineers, we do more than meet published specifications.

The 6×26 WS has better resistance to abrasion than a 6x25FW. It features a compact construction with solid support for the wires; therefore it has a high resistance to crushing. Its number and relative size of the inner wires add to the stability of the strand and gives it a fatigue resistance comparable to a 6×25 FW. A standard 6×26 WS construction provides the best rope for a wide range of applications. In general, we recommend the use of the 6x26WS in any application where a 6x25FW is used.

Mast Raising Lines, also called Bull Lines or Bridle Lines, are usually two pieces: each having sockets on both ends. These lines can be fabricated from either right regular lay rope or right lang lay rope. They must be fabricated from IWRC ropes.

Premium ropes may be used for specific applications. PFV cushions the strands, distributes internal stresses, keeps in wire rope lubricant and keeps out dirt and debris, extending the service life.

Flex-X® 9 features compacted strands and swaging for extra drum crushing resistance and increased stability. Its high-density strands deliver extra strength and resistance to abrasion. Flex-X® 9 is manufactured with a dual compaction process to produce a compact cross-section with minimum voids and greater surface area on outer wires that contact drums, sheaves and the rope, itself during operation. The high-density compacted strands minimize nicking at strand-to-strand contact points. Flex-X® 9 was specifically designed for boom hoist applications and tubing line applications where drum crushing is a challenge.

Flex-X® 6 users receive superior performance and increased service life in many applications compared to the ropes they had previously employed. When compared to conventional six-strand ropes, Flex-X® 6 ropes provide greater surface area and more steel per given diameter. This increases rope stability and strength. This results in a longer service life and less sheave and drum wear.

Flex-X® 19, a Category 2 rotation resistant rope, is made from 19 strands. Six strands are laid around a core strand in one direction, and then 12 strands are laid around this first operation in the opposite direction. Because of its tightly compacted smooth design, Flex-X® 19 offers more crushing resistance than standard 19×7 rope, higher strength-to-diameter, resistance to bending fatigue, exceptional stability, reduced wear to sheaves and drums, and improved handling, operating and spooling characteristics.

Galvanized steel wire rope 6×19S 6×19W is 6×19 classification, widely used for robust and abrasion-resistant, lifting and towing applications, it features right-hand ordinary lay wire rope with construction 9+9+1 Fibre Core or IWR with flexibility as well as durability abrasion resistance or crushing on the drum, but its fatigue resistance is decreased.

Wire rope can be seen everywhere around us, it is made of strands or bundles of individual wires constructed around an independent core, suitable for hoisting, towing, and anchoring heavy loads.

Wire rope is specified by the number of strands in the rope, the number of wires in each strand, and the strands are then twisted to form a rope construction.

The wire rope core is in the center of the rope and provide the rope stability, it is the foundation for the wire rope. Cores can be supplied with natural or synthetic fibers and steel core. For example, the 6×19 FC wire rope means that the rope has 6 strands, and there are 19 wires in each strand, the numbers 6×19 is followed by a letter combination, it means the core of the wire rope, FC means fiber core.

IWRC is commonly manufactured from 7 strands, while the WSC is manufactured from either 7 or 9 wires. Steel cores have a higher resistance to drum crushing and where less stretch and more strength is required.

The 6×19 FC wire rope means that the rope has 6 strands, and there are 19 wires in each strand, however, 6 x 19 wire rope may not reflect the actual construction, for 6 x 21 wire rope, and 6 x 26 are designated as being in the 6 x 19 classification, despite none of their constructions contain 19 wires.

There are many different wire rope grades, the higher grade, the higher min breaking strength, commonly the grades of wire rope are available include Improved Plow Steel (IPS), Extra Improved Plow Steel (EIPS), Extra Extra Improved Plow Steel (EEIPS), and metric wire rope grades can be designated as 1770n/mm²(Improved Plow Steel), 1960n/mm²(Extra Improved Plow Steel) and 2160n/mm²(Extra Extra Improved Plow Steel).

There are main three protective coatings on the wire rope, zinc-coated (galvanized) wire rope for harsh environment, uncoated steel (bright) wire rope for most running supplied, and stainless steel wire rope for marine and architectural applications.

The type and direction of lay wire rope mean the wires are laid around the strands(regular lay or lang lay) and the direction in which the strands are laid around the core(a right or left hand).

Regular lay is also referred to as ordinary lay. The strands are twisted in one direction, either left or right across the core and the wires are laid in opposite direction to the lay of the strands, which causes the finished product to appear like the wires are running parallel to the axis of the rope.

The regular lay wire rope is more flexible and carries better resistance to crushing forces and is more naturally rotation-resistant and spool better on a drum than lang lay wire rope.

The lang lay wire rope indicates that the wire lay and strand lay around the core in the same direction, either right or left and causes the finished product to appear with the wires to form an angle with the axis of the rope. Thes lang lay ropes are generally more flexible and have increased abrasion resistance leading to a longer lifespan than regular lay ropes, which can be used in construction, excavating, and mining applications.