what is the most abrasion resistant wire rope quotation

With each application, your choices of wire ropes can be many. How do you know which one works best for you? Ropes include a combination of characteristics that give them specific performance abilities. Before you choose, it pays to look closely at each rope’s special characteristics.

All wire ropes feature design characteristic tradeoffs. In most cases, a wire rope cannot increase both fatigue resistance and abrasion resistance. For example, when you increase fatigue resistance by selecting a rope with more wires, the rope will have less abrasion resistance because of its greater number of smaller outer wires. When you need wire rope with greater abrasion resistance, one choice is a rope with fewer (and larger) outer wires to reduce the effects of surface wear. But that means the rope’s fatigue resistance will decrease. That’s why you need to choose your wire rope like you would any other machine. Very carefully. You must consider all operating conditions and rope characteristics.

How do you choose the wire rope that’s best suited for your job? Following are the most common characteristics to be considered when selecting a rope for an application.

Wire rope strength is usually measured in tons of 2,000 lbs. In published material, wire rope strength is shown as minimum breaking force (MBF) or nominal (catalog) strength. These refer to calculated strength figures that have been accepted by the wire rope industry. When placed under tension on a test device, a new rope should break at a figure equal to – or higher than – the minimum breaking force shown for that rope. Certain standards allow for an acceptance strength that is 97.5% of the nominal strength to allow for testing variables. The values in this handbook apply to new, unused rope. A rope should never operate at – or near – the minimum breaking force. During its useful life, a rope loses strength gradually due to natural causes such as surface wear and metal fatigue.

Fatigue resistance involves metal fatigue of the wires that make up a rope. To have high fatigue resistance, wires must be capable of bending repeatedly under stress – for example, a rope passing over a sheave.

Increased fatigue resistance is achieved in a rope design by using a large number of wires. It involves both the basic metallurgy and the diameters of wires. 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 greater ability to bend as the rope passes over sheaves or around drums. To reduce the effects of fatigue, ropes must never bend over sheaves or drums with a diameter so small as to bend wires excessively. There are precise recommendations for sheave and drum sizes to properly accommodate all sizes and types of ropes.

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. Six strand ropes have greater crush resistance than 8 strand ropes or 19 strand ropes. Flex-X® ropes are more crush resistant than standard round-strand ropes.

Metal loss refers to the actual wearing away of metal from the outer wires of a rope, and metal deformation is the changing of the shape of outer wires of a rope. In general, resistance to metal loss by abrasion (usually called “abrasion resistance”) refers to a rope’s ability to withstand metal being worn away along its exterior. This reduces strength of a rope. The most common form of metal deformation is generally called “peening”– since outside wires of a peened rope appear to have been “hammered” along their exposed surface. Peening usually occurs on drums, caused by rope-to-rope contact during spooling of the rope on the drum. It may also occur on sheaves. Peening causes metal fatigue, which in turn may cause wire failure. The hammering – which causes the metal of the wire to flow into a new shape – realigns the grain structure of the metal, thereby affecting its fatigue resistance. The out-of-round shape also impairs wire movement when the rope bends.

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 loads to rotate. Load-induced torque can be reduced by specially designed rotation resistant ropes. In standard 6 and 8 strand ropes, the torques produced by the outer strands and the IWRC is 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. Depending upon your application, other wire rope characteristics such as stability, bendability or reserve strength may need to be considered.

6 x 26WS (Warrington Seale) – A standard 6 x 26WS design provides the best rope for a wide range of applications. In general, we recommend the use of a 6 x 26WS In any application where a 6 x 25FW is used.

As a wire rope is used, the outer wires wear through abrasion and so the rope suffers loss of cross-sectional area – this obviously reduces the breaking strength of the wire rope. Resistance to abrasive wear is therefore an important property of a wire rope.

Abrasion resistance is directly related to the design of the rope, in particular the design of the strands of the rope. In general, ropes with fewer larger wires will be more abrasion resistant than a similar rope made up of smaller wires – a 6 x 19 rope will therefore be more abrasion resistant than a 6 x 36 rope.

In a later article in this technical series we will discuss fatigue resistance in great detail but for the purposes of this discussion, we must recognise that a cyclic stress reversal occurs when a body is subjected to alternating tensile and compressive loads.

In a drilling operation, wire ropes run through sheaves constantly and so are constantly subjected to alternating tensile and compressive loads – i.e. cyclic stress reversals.

Figure 1 illustrates a wire rope bending over a sheave. It is clear that the outer parts of the rope running over the sheave are in tension and the inner parts of the rope running over the sheave are in compression and as the rope moves over the sheave these stresses reverse.

It should be obvious that the smaller the diameter of the sheave the greater the magnitude (amplitude) of the stress reversal and so the more rapidly fatigue will occur in the rope.

Wire ropes experience external forces that will tend to alter or distort the shape of the rope. Crushing prevents wires and strands moving easily over one another during normal operation and this can lead to accelerated wear and reduced rope life.

Actual operating loads may vary. NEVER exceed the recommended design factor of 20% of catalogue strength. Wire Rope must have the strength required to handle the maximum load plus a design factor. The design factor is the ratio of the breaking strength of the rope to the maximum working load.

In selecting the right steel wire rope, it is important to determine how important the various properties are in relation to the application and then to assign priorities to these. It is also important to be aware of the relevant standards and regulations. If you are in any doubt, please contact our sales consultants or our Technical Department.

The tensile strength of the steel wire rope depends on the rope’s dimensions, the tensile strength of the wires and the construction. The minimum guaranteed tensile strength for the different kinds of rope is shown in the Randers Reb product catalogue.

The design of the steel wire rope does not significantly affect the tensile strength (up to approx. 5%). A change of core from fibre to steel makes slightly more difference (approx. 10%). The greatest change is achieved by changing the dimensions, usage of Compacted steel wire ropes or tensile strength of the wires (see also fig. 28).

It is often required that the steel wire rope must have a specific SWL value (Safe Working Load), also known as a WLL value (Working Load Limit). This means the steel wire rope’s tensile strength divided by the safety factor required for the relevant application.

Steel wire ropes with thick outer wires (e.g. 6x7 Standard or 6x19 Seale) provide good abrasion resistance. Lang lay ropes provide better abrasion resistance than regular lay steel wire ropes (see also fig. 28). Abrasion resistance can also be increased by using wires with greater tensile strength.

The greater the number of wires in the strand, the greater the bending fatique resistance and flexibility. Lang lay ropes provide better bending fatique resistance than regular lay steel wire ropes. Bending fatique resistance can also be increased by using pre-formed steel wire ropes (see also fig. 28).

Galvanised and rustproof wires provide excellent protection against corrosion. Lubrication with special types of grease or oil will also increase resistance to corrosion. If the steel wire rope is subjected to significant corrosive influences, it is recommended that strands with thick outer wires are used.

Steel wire ropes with fewer wires (e.g. 1x7 Standard and 1x19 Standard) are subject to the least elongation (have the greatest elasticity modulus). This type of steel wire rope is ideally suited for guy ropes, but is not suitable to be run over sheaves/blocks. If only a small degree of elongation when running over sheaves is required, 6x7 or 6x19 steel wire rope should be used, in each case with a steel core or with certain special constructions. For larger dimensions, 6x36 steel wire rope with a steel core can also be used (see also Elongation and Pre-stretching, page 8-28).

Standard 6-lay and 8-lay steel wire ropes will rotate when they hang free and carry a load. Regular lay steel wire rope provides greater resistance to rotation than lang lay steel wire rope. A steel wire rope with a steel core rotates less than a steel wire rope with a fibre core. The type of rope that provides greatest resistance to rotation is, as the name suggests, low-rotation and rotation-resistant steel wire rope (special constructions, see also ”Low-Rotation and Rotation-Resistant Steel Wire Rope”, page 8-10).

A steel core provides better support for the strands than a fibre core, which is why the risk of flattening is less in a steel wire rope with a steel core. Strands with fewer, thicker wires have greater resistance to flattening/crushing. Also, a 6-lay steel wire rope has greater crushing resistance than an 8-lay rope (see also fig. 28).

Vibrations, from wherever they might come, send shock waves through the steel wire rope, which will be absorbed by the steel wire rope at some point, and in some cases they may cause localised destruction of the steel wire rope (not necessarily on the outside). This may, for example, be at places where the steel wire rope comes into contact with a sheaf/block, or enters the drum, and by the end terminals. In general, those steel wire ropes with the greatest flexibility also have the greatest vibration resistance.

Changes in the tension of a steel wire rope, depending on the size and frequency, will reduce the rope’s life expectancy. In general, steel wire ropes with the greatest flexibility can cope better with intermittent loading. Great care should be taken in the use of end terminals or fittings, as their pulsation resistance is equally as important as the selection of the right steel wire rope.

Lang lay steel wire ropes are the ones most suited to running over sheaves and are the most durable, but if they are to be used, three things must be observed:

The reason for Lang lay steel wire ropes’ excellent qualities of abrasion resistance and pliability is that the wires are affected/loaded in a different way and have a larger load-bearing surface than a regular lay steel wire rope (see fig. 29). Note that the largest wearing surface is on the Lang lay steel wire rope.

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.

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.

G411 THIMBLE EYE = Thimble eye model. Soft eye will be stated with the effective working length and the size of soft eye is based on nominal diameter x 15times according to EN131411 standard.

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.

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9/16” 6X25 swaged wire ropes are a trusted and reliable compact rope style that’s regularly used across many industries. This rope style is popular because of its resistance to abrasion, fatigue, and drum crushing when compared to other wire rope styles. If you have a project that requires strength under regular fatigue while also being able to hold up under moderate bending, this swaged style will get the job done.

Rasmussen holds a wide selection of swaged wire rope to help with any project our customers may have. With an unmatched selection and unmatched experience, we’re proud to be the go-to wire rope partner for businesses across the country.

The 6X25 wire is a commonly used wire rope within the 6X19 classification. These ropes provide excellent crushing and abrasion resistance due to their compact cross sections and minimal valleys between individual strands. 6X25 wire ropes are the highest strength rope available in the 6X19 classification and a popular wire rope within the logging industry. You can regularly see this wire class in slings, winch lines, and crane lines.

Also known as compacted wire rope, swaged wire rope is made by compacting regular wire rope into a smaller, denser diameter. With increased abrasion and wear resistance, increased crushing resistance, and higher strength compared to regular wires of a similar diameter, swaged wire rope is a reliable option for many project types.

Rasmussen’s wire rope experts are committed to using premium materials in all of our wire rope and rigging products. We carry products from industry-leading manufacturers and can help you with working load limits, cargo control, and material handling. Rasmussen is your go-to wire rope expert.

Contact an expert today to get a quote on any of our wire rope and rigging products. If you’re unsure what exact tools you’ll need for your specific job, our sales team will be happy to help. You can reach our specialists by calling (801) 972-5588. We want to hear about your project, and answer any help in any way we can. Call today!

6x37 Classification Wire Ropes have a third layer of wires which makes them more flexible, although less abrasion-resistant, than ropes of the 6x19 classification. Each strand contains numerous, small-diameter wires. As the number of wires in each strand is increased, flexibility is increased… as wires per strand decreases, flexibility is decreased.

At Carl Stahl Sava Industries, our steel mechanical cable choices include 304 and 316 stainless steel and galvanized steel cable. Sava is both a wire rope supplier and a wire rope manufacturer that is able to work withexotic steel alternatives upon request, both stainless steel and galvanized steel mechanical cable offer distinct benefits, depending upon the application. Read on to learn the differences between galvanized vs. stainless steel wire ropeand determine which custom wire rope will better serve your application requirements.

One of the greatest benefits of stainless steel wire rope is that it is suitable for nearly any application. While it may have a slightly higher cost than galvanized steel cable, stainless steel cable provides customers with greater ROI and maintains its high-strength qualities over its lifespan under most conditions. While not as strong as tungsten or tolerant of excessive temperatures, stainless steel mechanical wire rope is an incredibly effective cable construction material.

Stainless steel has high corrosion resistance due to it being treated with chromium. This additional element makes stainless steel suitable for use in moist environments, even when harmful salty conditions are present. Specifically in marine environments, for instance, stainless steel wire rope can be used for years without corroding. And in the medical devices field, stainless steel is commonly the metal of choice for many medical device instruments like endoscopes because of its high sanitization level and durability over many cycles makes it ideal.

Galvanized steel is steel that has been dipped in a zinc coating, which gives it good corrosion-resistant qualities. But even with the addition of zinc, galvanized wire rope’s strength is weaker than stainless steel because of the presence of chromium, making the cable stronger and more tolerant of corrosive elements like saltwater. Galvanized cable will rust and corrode if salty wet conditions are present. And like stainless steel, galvanized steel cable ends will also weld together if they make contact with one another.

Galvanized steel cable is often found in industrial applications, since items may brush up against the wire rope in the field, which again, are environmental conditions that galvanized steel tolerates quite well over time. For this and other reasons, Galvanized steel wire rope works exceptionally well in aerospace applications.

Stainless steel wire rope is a cost-effective solution that works across a range of applications, is impervious to salty wetness and is stronger than galvanized steel cable. But galvanized steel wire rope is corrosion-resistant, except when salt is present and tolerates contact with itself far better than stainless steel cable.

It"s important to remember that since each application has unique needs, these comparisons are general guidelines. Contact Sava today to discuss your project, so we can help you determine whether a stainless steel wire rope or galvanized steel wire rope is best for your cable manufacturing needs.

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7/8″ 6X31 Super Pac swaged wire rope is the ideal wire rope for applications where abrasion and drum crushing are an issue. With an IWRC or fiber core, this double-compacted product provides increased abrasion and drum crushing resistance compared to regular rope. The double compaction process for this Super-Pac swaged rope creates a wire rope that has an increased minimum breaking strength, superior fatigue resistance, and reduces drum and sheave wear.

Rasmussen holds a wide selection of swaged wire rope to help with any project our customers may have. With an unmatched selection and unmatched experience, we’re proud to be the go-to wire rope partner for businesses across the country.

The 6X31 wire class consists of 6 outer strands with 31 wires per strand. With its Warrington Seale wire pattern, this wire rope style has a high density and allows for greater crushing and abrasion resistance as well as increased strength. The increased numbers of wires per strand also make it the preferred wire for projects that require high fatigue resistance such as boom hoists and lowering ropes.

Also known as compacted wire rope, swaged wire rope is made by compacting regular wire rope into a smaller, denser diameter. With increased abrasion and wear resistance, increased crushing resistance, and higher strength compared to regular wires of a similar diameter, swaged wire rope is a reliable option for many project types.

Rasmussen’s wire rope experts are committed to using premium materials in all of our wire rope and rigging products. We carry products from industry-leading manufacturers and can help you with working load limits, cargo control, and material handling. Rasmussen is your go-to wire rope expert.

Contact an expert today to get a quote on any of our wire rope and rigging products. If you’re unsure what exact tools you’ll need for your specific job, our sales team will be happy to help. You can reach our specialists by calling (801) 972-5588. We want to hear about your project, and answer any help in any way we can. Call today!

6 strands, nominally 19 wires per strand This class is the most widely used and is found in its many variations throughout many industries. With its good combination of flexibility and wear resistance, rope in this class is suited to the specific needs of many kinds of machinery and equipment. The designation 6x19 is only nominal; the number of wires ranges from 15 to 26. The following constructions are included in this class:

6x25 Filler Wire. In this construction, there are 19 main wires in each strand, plus six small filler wires. The filler wires are located between the outer layer of 12 wires and the inner layer of six. They provide support and stability to the strand. This construction is the best combination of flexibility and abrasion resistance found in the 6x19 Class.

6x19 Warrington. Each strand is made up of 19 wires. The outer layer of 12 wires has two different sizes of wire; the inner layer of six is one size of wire. The Warrington construction is somewhat less flexible than 6x25 Filler Wire, but more flexible than 6x21 Filler Wire.

6x21 Filler Wire. Each strand is made up of 21 wires. The rope has an outer layer of 10 large wires, an inner layer of five smaller wires and a still smaller center wire. There are five filler wires, located between the outer layer of ten wires and the inner layer of five. The 6x21 Filler Wire ropes are more wear-resistant but less flexible than Warrington, and less abrasion-resistant but more flexible than 6x19 Seale constructions.

6x26 Warrington Seale. This construction is composed of 26-wire strands. It has the same size outer wires as the 6x21 Filler Wire, with an inner wire configuration similar to the 6x36 Class ropes. Thus, it combines the wear resistance of a 6x19 rope with a flexibility between 6x19 and 6x36 Class ropes.

6x19 Seale. This construction has an outer layer of nine large wires, an inner layer of nine smaller wires and a single center wire. The Seale ropes are the least flexible of the 6x19 Class ropes. However, the large outer wires, solidly supported, provide resistance to abrasion and crushing.

The 6x36 Class of wire rope is characterized by the relatively large number of wires in each strand. Ropes of this class are more flexible than the 6x19 Class, but their resistance to abrasion is less than the 6x19 Class ropes.

The designation 6x36 is only nominal, as is the case with 6x19 Class. Ropes in the 6x36 Class may contain 27 to 49 wires per strand. Improvements in wire rope design, as well as changing machine designs, resulted in the use of strands with widely varying numbers of wires and geometry.

Larger wire ropes frequently incorporate a larger number of wires, resulting in a more complex geometry than found in the 6x19 or 6x36 Class wire ropes. WW’s 6x61 Class Bethlehem Mining Ropes generally are designed to comply with ASTM A 1023 geometry, although we added some innovations. WW strands the 6x61 Class Bethlehem Mining Ropes in a single operation, relying on dense, well fitted geometry to provide exceptional rope performance and the flexibility normally associated with 6x61 Class ropes.

The 6x61 Class ropes have a Seale-Filler Wire-Seale design, as shown in the cross sections below, containing from 50 to 77 wires per strand. WW further enhances Bethlehem Mining Rope performance by wire metallurgy and wire properties which are selectively modified to augment the specific rope geometries.

Many wire rope users have observed that heavily loaded ropes fail internally due to the failure of the IWRC. Such conditions illustrate that heavy IWRC stresses exist, which promote fewer fatigue cycles and create short rope life. WW designed Maxi-core to improve rope life under these conditions.

Maxi-core utilizes an IWRC design which features eight strands around a strand center. Maxi-core’s IWRC provides longer life, and, therefore, increases the overall service life of the rope. Because of its specialized IWRC, Maxi-core is resilient and able to accommodate shock loads better than conventional IWRC designs. Maxi-core also adds 33% more core support to the outer strands, thereby reducing internal stresses and promoting longer rope life. As with all Bethlehem Excavator Family Ropes, WW does not publish Maxi-core rope strengths. WW relies on specific rope improvements and specialized features to provide rope designs which give proven, superior field service.

This plastic jacket acts as a cushion or shock absorber between adjacent main strands and at main strand-to-IWRC contact points. The improved internal support is especially significant for ropes subjected to continual bending stresses and fluctuating loads (shock loading). Reduction of wear and damage at internal contact points results in longer and more predictable service life.

Compacted Strands: Beth Pac Beth Pac refers to rope manufactured by compacting each individual strand before closing the rope. In comparison to conventional wire rope, Beth Pac has a higher metallic area, improved crushing resistance and a smoother surface contacting sheaves and drums.

Beth Pac is offered in Excavator and Excavator-AR in diameters 21/4" through 23/4" in 8x36 construction for hoist ropes. Beth Pac can be combined with other Bethlehem Mining Rope features, such as En-core. For more information and help in determining your need for Beth Pac and other available sizes, please contact WW’s Sales and Engineering Departments.

BXL is furnished as right regular or lang lay, Form-set, IWRC wire rope manufactured in the 6x19, 6x36 and 8x36 Classes. Available grades are Excavator and Excavator-AR. For specific information, please refer to the table. For information on smaller diameters for mining applications, please contact our Customer Service Department.

BXL provides the characteristics common to Bethlehem Mining Rope, enhanced by the plastic-infusion. BXL starts with WW’s special wire grades used in the manufacture of mining rope. Excavator grade is designed to provide excellent resistance to bending fatigue, such as those conditions found with hoist ropes. Excavator-AR is intended for those applications where more abrasive operating conditions exist, such as in drag line applications. Enhanced by plastic infusion, BXL offers several improved features.

Improved fatigue resistance is one key feature of BXL. BXL’s polymer cushions each wire and strand, minimizing interstrand and interlayer nicking. BXL also offers improved abrasion resistance. The polymer acts as a barrier between the individual strands, preventing penetration of any adverse material, such as dust, dirt and metal particles. The polymer also distributes and reduces contact stresses between the rope and sheave, reducing the wire rope wear normally associated with uncoated wire rope. Perhaps the most important feature of BXL, however, is the polymer’s ability to maintain the balance of the rope. When a rope is in operation, or simply wound upon a drum, the rope’s components move and adjust accordingly.

Due to the nature of wire rope, this movement may cause accelerated wear, and in uncoated rope, may also produce a flattening or ovaling of the rope. The polymer in BXL minimizes this movement by locking the individual wires and strands in place. With the rope’s holding its intended shape during operation, operating stresses such as vibration are evenly distributed to all wires and strands, thereby reducing fatigue breaks and increasing service life.

This rope is particularly suitable where severe crushing and abrasion on a drum occur, or where a higher strength design is required than can be obtained with a similar round strand rope. The triangular strand shape not only provides better resistance to crushing, but also offers a greater exposed surface area for contact with sheaves, drums or underlying areas of spooled rope.

This feature, combined with Lang lay, distributes the abrasive wear over a greater number and longer length of wires. The broad, smooth surface of the rope also helps to minimize wear on drums and sheaves.

We make a full line of tail ropes customized to meet your requirements of strength and weight to balance your friction hoist system. Please contact your salesman or customer service with your specifications and we will supply a quotation to meet your needs.

The most commonly overlooked feature when choosing Wire Rope, Cable, or Strand is the material. While the emphasis on sizes and construction is important to your application, picking the right material is also detrimental to the success of your Wire Rope, Cable, or Strand products. Materials for these products come in various material options: Galvanized Steel, 302/304 Stainless Steel, 316 Stainless Steel, Bright Basics, IPS, EIPS, EEIPS, and Phos Bronze. Here is a brief outline of each materials and some of their unique properties.

Galvanized Steel is a process where Carbon Steel is coated in zinc. The metal remains ductile over long periods of use and typically has a higher breaking strength than stainless materials. Galvanized Steel offers minimal corrosion resistance due to its zinc coating. The metal is primarily used in logging, rigging, hoisting, and general industrial applications.

Stainless Steel is a metal alloy formed of iron, chromium and sometimes metals such as nickel and manganese. 302/304 are the most common grades of stainless steel. The 302/304 grades provide a high level of corrosion resistance, making it perfect for various industries such as marine rigging and hoisting.

Bright Basics is a carbon steel alloy. This material does not protect against corrosion until a lubrication coat is added. The material has a high strength level, and is ideal for a wide variety of industrial and commercial uses.

IPS is defined as Improved Plow Steel, EIPS is Extra Improved Plow Steel, while EEIPS is Extra Extra Improved Plow Steel. These steel materials have high tensile strength and are very resistant to wear.

If you are interested in learning more about these materials, check out Strand Core’s Material Guide here. Alongside the materials mentioned above, Strand Core also can offer many other material grade options for your Wire Rope, Cable, or Strand such as Nickel, Copper, Brass, Inconel and Monel through our parent company, CWI. Alternatively, if you want to check out our Wire Rope, Cable and Strand in various constructions, materials, and sizes, visit our website. If you have any questions, our team is happy to help! Reach out to us by email through sales@strandcore.com, or by phone at 800-983-9926.

For anyone in the industry, some of your most useful and frequently used tools are the slings that allow you to safely and efficiently complete your projects. Most of us have a basic understanding as to how each type of sling is constructed, but few know the real ins-and-outs of what gives a sling its strength and the amount of work behind its construction. At Lifting Gear, we go through great lengths to understand the driving force behind each piece of equipment in our fleet so we can ensure the safest and most reliable gear makes it onto our customer’s job sites.

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.

A 6X19 class wire rope contains 6 strands with 16 through 26 wires per strand. Our 6x19 class typically has either 19 (6X19) or 26 (6X26) wires per strand. It is a general purpose rope most commonly used for wire rope chokers and other rigging. 6X19 and 6X26 offfer great abrasion resistance and crush resistance when spooling.

A 6X37 class wire rope contains 6 strands with 27 through 49 wires per strand. Our 6X37 typically has 36 wires per strand. It is a general purpose wire rope with excellent flexibility for spooling. With the smaller wires per strand, the trade off for excelelnt flexibility is reduced abrasion resistance.

IWRC (Independent Wire Rope Core) wire ropes offer more crush resistance when spooling while FC (Fiber Core) wire ropes offer more flexibility. FC wire ropes are not as crush resistant when spooling compared to an IWRC wire rope.

Over the years, Usha Martin Europe successfully developed a preferred selection of trawl and purse seine fishing wire rope. All designed and produced for safe and maximum performance.

Industrial fishing ropes are subjected to a lot of wear and abrasion, especially trawling ropes. As a result, we design our fishing wire ropes towards increased abrasion resistance and reduced pulley wear.

A major deteriorating factor for fishing ropes is corrosion. Therefore, we offer our range of fishing wire ropes with choice of galvanization and lubricant to ensure further extension of rope service life. Always based upon your application and environmental circumstances. But we do not stop there. Based upon your specific application, we design and select the correct construction, including careful selection of strands and wire diameter.

Fishing wire ropes are always on supply at our facility in Dordrecht, reporting to a worldwide network of customers. Some examples are the 6×7, 6×19 and the 6×26 construction.

Would you like to invest in high-quality fishing wire rope? Then you should get in contact with us by sending an e-mail to info@ushamartineurope.com or calling +31 (0) 180745099. It is also possible for us to fabricate solutions that are tailored to your specific situation. That is how we can help a variety of sectors with our steel wire ropes.