wire rope construction types brands

Wire rope manufacturers produce their products in order to provide a high load capacity, versatile alternative to weaker ropes like manila rope or hemp rope. Wire rope products are used for a wide variety of motion transmission applications, among them: lifting, baling, tie down, hoisting, hauling, towing, mooring, anchoring, rigging, cargo control, guidance and counterbalance. They can also be used as railing, fencing and guardrailing.

Wire rope is a must-have for many heavy duty industrial applications. From mining to forestry to marine and beyond, there’s wire rope for almost every job. Some of the many industries in which wire rope is popular include: construction, agriculture, marine, industrial manufacturing, fitness, sports and recreation (plastic coated cables for outdoor playground equipment and sports equipment), electronics, theater (black powder coated cables for stage rigging), mining, gas and oil, transportation, security, healthcare and consumer goods.

Wire rope as we know it was invented just under 200 years ago, between 1831 and 1834. At that time, the goal was to create a rope strong enough to support work in the mines of the Harz Mountains. Invented by Wilhelm Albert, a German mining engineer, this wire rope consisted on four three-stranded wires. It was much stronger than older rope varieties, such as manila rope, hemp rope and metal chain rope.

While studying at Freiburg School of Mines, a man named L.D.B. Gordon visited the mines in the Harz Mountains, where he met Albert. After he left, Gordon wrote to his friend Robert Stirling Newall, urging him to create a machine for manufacturing wire ropes. Newall, of Dundee, Scotland, did just that, designing a wire rope machine that made wire ropes with four strands, consisting of four wires each. After Gordon returned to Dundee, he and Newall, along with Charles Liddell, formed R.S. Newall and Company. In 1840, Newall received a patent for “certain improvements in wire rope and the machinery for making such rope.”

In 1841, an American manufacturer named John A. Roebling began producing wire rope for suspension bridges. Soon after, another set of Americans, Josiah White and Erskine Hazard, started incorporating wire rope into coal mining and railroad projects, forming Lehigh Coal & Navigation Company (LC&N Co.). In 1848, wire rope from their wire rope factory in Mauch Chunk, Pennsylvania provided the lift cables needed to complete the Ashley Planes Project. This project sought to improve the performance and appearance of the freight railroad that ran through Ashley, Pennsylvania, by adding lift cables. This increased tourism and increased the railroad’s coal capacity. Before, cars took almost four hours to return; after, they took less than 20 minutes.

Wire rope likewise changed the landscape (again) in Germany, in 1874, when an engineering firm called Adolf Bleichert & Co. used wire rope to build Bi-cable aerial tramways. These allowed them to mine the Ruhr Valley. Several years later, they also used wire rope to build tramways for the German Imperial Army and the Wehrmacht. These tramways were wildly successful, opening up roads in Germany and all over Europe and the USA.

Since the 1800s, manufacturers and engineers have found ways to improve wire rope, through stronger materials and material treatments, such as galvanization, and different rope configurations. Today, wire rope makes possible many heavy industrial processes. It has become a necessity of the modern world.

Strands are made by tightly twisting or braiding individual wire together. One strand could have anywhere between two and several dozen wire filaments depending on the necessary strength, flexibility, and weight capacity.

One of the most dynamic elements of wire cables is the inner core. The strands are wrapped around the core, and it can be made of different metals, fibers, or even impregnated fiber materials. For heavy applications, cores are often made of a different strand of wire called an independent wire rope core (IWRC). An IWRC has a considerable amount of flexibility and it is still very strong. In fact, at least 7.5% of the strength increase in a wire rope can be attributed to an IWRC.

While they sometimes use other metals, like aluminum, nickel, copper, titanium, and even bronze for some applications, manufacturers primarily produce wire rope from steel. This is because steel is very strong and stretchable. Among the most common types they use are: galvanized wire, bright wire, stainless steel and cold drawn steel.

Of the wire rope steels, cold drawn carbon steel wire is most popular, although stainless steel wire rope is sometimes employed as well. Stainless steel rope is most popular for its anti-corrosive properties. Bright wire rope, a type of ungalvanized steel wire rope, is also popular. For added strength and durability, galvanized steel wire rope/galvanized steel cables are a very popular choice. Galvanized aircraft cable, for example, is always a must in aerospace.

When choosing or designing a custom wire rope for your application, suppliers consider factors such as: the environment in which the rope will function, required rust resistance, required flexibility, temperature resistance, required breaking strength and wire rope diameter. To accommodate your needs, manufacturers can do special things like: make your rope rotation resistant, color code your rope, or add a corrosion resistant coating. For instance, sometimes they specially treat and coat a cable with plastic or some other compound for added protection. This is particularly important to prevent fraying if the wire rope is often in motion on a pulley.

Manufacturers and distributors identify the differences in wire cable by listing the number of strands and the amount of wires per strand so that anyone that orders understand the strength of the cable. Sometimes they are also categorized by their length or pitch. Common examples of this include: 6 x 19, 6 x 25, 19 x 7, 7 x 19, 7 x 7, 6 x 26 and 6 x 36.

More complex wire rope identification codes connote information like core type, weight limit and more. Any additional hardware like connectors, fasteners, pulleys and fittings are usually listed in the same area to show varying strengths and degrees of fray prevention.

Cable wire rope is a heavy-duty wire rope. To give it its high strength, manufacturers construct it using several individual filaments that are twisted in strands and helically wrapped around the core. A very common example of cable wire rope is steel cable.

Spiral rope is made up an assemblage of wires with round or curved strands. The assemblage features at least one outer layer cord pointed in the opposite direction of the wire. The big advantage of spiral ropes is the fact that they block moisture, water and pollutants from entering the interior of the rope.

Similarly, stranded rope steel wire is made up of an assemblage of spirally wound strands. Unlike spiral rope, though, its wire patterns have crisscrossing layers. These layers create an exceptionally strong rope. Stranded rope may have one of three core material types: wire rope, wire strand or fiber.

Wire rope chain, like all chains, is made up of a series of links. Because it is not solid, wire rope chain is quite flexible. At the same time, it is prone to mechanical failure.

Wire rope slings are made from improved plow wire steel, a strong steel wire that offers superior return loop slings and better security. The plow wire steel also shields rope at its connection points, which extends its working life. Wire rope slings, in general, provide their applications with increased safety, capacity and performance. Wire rope sling is a rope category that encompasses a wide range of sub-products, such as permaloc rope sling, permaloc bridle slings and endless slings. These and other wire rope slings may be accompanied by a wide variety of sling terminations, such as thimbles, chokers and hooks.

Wire rope offers its user many advantages. First, design of even distribution of weight among strands makes it ideal for lifting extremely heavy loads. Second, wire rope is extremely durable and, when matched properly to the application, can withstand great stress and elements like corrosion and abrasion. In addition, it is very versatile. Its many iterations and the ways in which the rope can treated means that users can get rope custom fit for virtually any application.

Depending on the type of wire rope with which you are working and your application, you may want to invest in different accessories. Among these accessories are: wire rope clips, steel carabiners, fittings, fasteners and connections.

To ensure that your wire rope quality remains high, you must regularly inspect them for wear and degradation. The right wire rope should be selected for a particular use. Watch out for performance-impacting damage like: rust, fraying and kinks. To make sure that they stay in tip-top shape, you should also clean and lubricate them as needed. Check for this need as a part of your regular inspection.

Rope care is about more than inspection. It’s also about making an effort to use and store them properly every time you use them. For example, never exceed your rope’s rated load and breaking strength. Doing so will not only cause the weakening of your cable, but it may even cause immediate breakage. In addition, always store your wire rope cable in a dry and warm area, away from those elements that could cause premature rusting or other damage. Finally, always carefully wind your wire rope when you’re done with it, so as to avoid kinks. If you follow all these tips and treat your wire rope assemblies well, they will reward you with a long and productive service life.

Always make sure that you purchase wire rope that matches your industry and regional standards. Some of the most widely referenced standards organizations for wire rope include: ISO, ASTM International and OSHA. Talk over your specifications and application with your wire rope supplier to figure out what’s best for you.

If you’re in the market for a wire rope or a wire rope assembly, the best way to know you’re getting something that will both perform well and be safe if by working with a vetted professional. Find one among the list we’ve provided on this page. Check out their profiles to get an idea of the services and products they offer. Pick out three or four to whom you’d like to speak, and reach out. Talk to them about your specifications, standard requirements and budget. Ask about lead times and delivery options. Once you’ve spoken with all of them, compare and contrast their answers. You’ll know you’ve found the one when you talk to a wire rope company that is willing to go above and beyond for your satisfaction.

Wire rope is a complex mechanical device that has many moving parts all working in tandem to help support and move an object or load. Wire ropes are attached to a crane or hoist and are fitted with swivels, shackles or hooks. These are suitable for lifting or lowering elevators and are also used for supporting suspension bridges or towers.

In this article, we"ll cover details on the top U.S. providers of wire ropes, along with our featured list of top wire rope suppliers on Thomasnet.com.

Below is a list of featured suppliers of wire rope from our platform. Included with these companies is their location, year established and the number of employees.

Below we have assembled information on the top suppliers of wire rope in the U.S. based on currently available public sales data. The table also includes the company name, location and the number of employees.

With the help of the provided details on the wire rope suppliers in the United States in the above tables and descriptions, we hope you can use this data to further aid your sourcing decisions.

Wire ropes are several strands of metal wire that are twisted into a helix to form a composite rope, known as a laid rope. Large diameter wire rope consists of several strands of rope laid in what is known as cabling. Wire ropes are complex mechanical devices consisting of several moving parts that work together to help support & move an object or load.

In the lifting & rigging industries, wire rope is attached to a crane or hoist & fitted with a swivel, shackle, or hook to attach to a load and move it into a controlled case. It can also be used for lifting and lowering elevators or as a means of support for suspension bridges or towers. Wire rope is a preferred lifting tool for many reasons.

Its unique design consists of several steel wires that form separate strands placed in a helical pattern around a core. These structures provide strength, flexibility, & the ability to handle bending stresses. In the strictest sense, the term wire rope refers to a diameter larger than 3/8 inch (9.52 mm), with a smaller gauge specified cable or cord.

Initially, iron wires were used, but today the main material used for wire ropes is steel. Wire rope is made from cold-drawn wires to increase strength & durability. It may be noted that as its size decreases, the strength of the wire ropes increases.

The various materials used for wire ropes are iron, cast steel, extra strong cast steel, steel, and alloy steel, in order of increasing strength. For some purposes, wire rope can also be made from copper, bronze, aluminum alloys, and stainless steel. Wire ropes were developed in the 1830s with mining hoist applications.

Wire ropes are used in cranes and elevators for dynamic lifting and lifting and for transmission of mechanical power. It is also used to transmit forces to mechanisms, such as Bowden cables or the control surface of an airplane connected to levers and pedals in the cockpit.

Wire rope is made of threads of metal wire that are braided together to form a helix. Due to its heavy, flexible and tough characteristics, as well as being weather- and corrosion-resistant, it is commonly used in the building and construction, engineering, agriculture, aircraft, and marine industries.

Each wire strand bringing equal pressure to the bundle contributes to its strength and flexibility, making it an ideal material for pulleys. In Australia, wire rope was made of iron; Today, the materials used are mainly steel. Different industries use different types of wire ropes.

This is because the suitability of a specific wire rope for an application depends on the design, size, type of braids, and other characteristics. For example, marine-grade 316 wire rope is suitable for a variety of marine applications and settings.

Stainless steel is the standard alloy used in rope and cable. Its resistance to corrosions is much higher than that of galvanized & coated ropes, although there are no differences in strength. Therefore, it is the preferred material uses in marines and water-based salt industries.

It does not readily react to chemicals from food processing, textiles, and photographic settings. Its high resistance to corrosion, heat & cold, and pulp & paper chemicals makes stainless steel wire rope a much-needed material for manufacturing precision instruments, automobiles, fishing vessels, petrochemical equipment, & other fields.

Galvanized wire ropes are also steel wire materials that have undergone a galvanizing process to increase their corrosion resistance. The finished wire is immersed in a zinc bath to coat the product completely, i.e., it is galvanized.

Zinc is used in this process because cathode protection increases the life expectancy of the wire. Although the coating will degrade over time, it is still resistant to rust, corrosion, and other harsh chemicals. Galvanized wire can be found in the industrial and construction sectors as well as in agricultural and DIY projects.

Stainless steel and galvanized wire can be PVC coated with poly-vinyl-chloride or vinyl. Coated wire rope comes in various colors such as clear, black, white, or any other color that is required in various industries. PVC coated wire is flexible, weather-resistant, and very cost-effective.

Nylon-coated wire, although not as flexible as PVC, is abrasion-resistant and ideal for businesses in extremely cold regions. Wire ropes can be assembled to suit specific applications. If you have a project requiring a specific type of wire rope, send us an inquiry, and we’ll send you a special quote.

The wire is the smallest component of wire rope, and they form the individual strands in the rope. Wire can be made from a variety of metal materials, including steel, iron, stainless steel, Monel, and bronze. Wires can be manufactured in varieties of grades that are related to wire rope strength, wear resistance, fatigue resistance, corrosion resistance, and curve.

These strings symbolize the smallest component of a wire rope and are tied together around a core to form complete wire ropes. The wire themselves can be coated but are usually available in “bright” or uncoated finishes.

Wire rope strings form two or more wires wrapped around an axial member in a geometric pattern or in combination with steel wires and other materials. These individual strands are then placed around the core in a helical pattern. Strands represent the major part that serves as the primary load-bearing unit.

A typical strand can form any number of strands, and the same goes for a rope that can have an ‘n’ number of strands. Wires made from larger diameter wires are more resistant to abrasion, while wires made of smaller diameter wires are more flexible.

The core of a wire rope runs through the center of the rope & supports the wires and helps them maintain their relative position under loading and bending stress. Cores can be made from many different materials, including natural or synthetic fibers and steel. It supports the strands and helps maintain their relative position under loading and bending stress.

Wire ropes are made from the various grades of steel wires with tensile strengths ranging from 1200 to 2400 MPa. The wires are first given special heat treatment & then cold drawn for the high strength and durability of the rope. Steel wire ropes are manufactured by special machines.

First, strands of wire such as 7, 19, or 37 are routed into a single strand, and then several strands, usually 6 or 8, are twisted around the core or center to form a rope. The core may be made of loops of hemp, jute, mica, or soft steel wire.

The core must be continuously saturated with lubricants for the long lives of the core as well as the entire rope. Asbestos or soft wire core is used when a rope is subjected to radiant heat, such as cranes working near furnaces.

However, a wire core reduces the rope’s flexibility, and such ropes are only used where they are subject to high compression, as in the case of multiple layers being injured on a rope drum.

The number of layers of wires, the numbers of wires per layer, & the size of the wire per layer all affect the strand pattern type. Wire ropes can be constructed using any one of the following patterns or can be made using two or more of the pattern below.

The Two-layer of similarly sized wire around a center whose inner layer is half the number of wires as the outer layer. Small fillers wires, equal to the numbers in the inner layer, are placed in the valleys of the inner wire.

Two layers of wires around centers with the same numbers of wires in each layer. All wire in each layer is of the same diameter. The larger outer strings rest in the valleys between the smaller inner strings.

The inner layer consists of two layers of wires around a center with one diameter of the wire, and the latter alternates two diameters of the larger and smaller wire in the outer. The larger wires in the outer layer are placed in the valleys & the smaller ones on the crowns of the inner layer.

On a prefabricated wire rope, the wire and wire are formed during the manufacturing process into the helical shape that they will take into a finished wire rope. Prefabricated rope can be beneficial in some applications where it needs to be spooled more evenly over the drum, more flexibility is required, or greater fatigue resistance is required when bending.

Direction and laying type refer to how the wires are laid to form a strand, either right or left & how the strands are laid around the regular core lay, lang lay, or alternate lay.

The wires are lined up with the axis of the rope. The direction of the wire held in the strand is opposite to the direction in the strand lay. Regular lat ropes are more resistant to crushing forces, are more naturally rotation-resistant, and also have a better spool in the drum than lang lat ropes.

The wires make an angle with the axis of the rope. The wire lay down, and the strand lay around the core in the same direction. Lang le ropes have greater fatigue resistance and are more resistant to abrasion.

A fiber core may be made of natural or synthetic polypropylene fibers. Fiber cores offer greater elasticity than steel cores but are more susceptible to crushing and are not recommended for high heat environments. A steel core can be independent wire ropes or an individual strand.

Steel cores are bests suited for applications where the fiber core cannot provide adequate support or in an operating environment where temperatures may exceed 180 degrees Fahrenheit. Based on what we have learned above, this wire rope description will provide the following information to the user:

Wire rope classifications provide the total number of wires in each strand, as well as the nominal or an exact number of wires. These are general classifications & may or may not reflect the actual constructions of the strands. However, all wires rope of the same size & wires grade in each classification will have similar strength and weight ratings and generally similar pricing.

Some types of wire rope, particularly lang le wire rope, are more susceptible to rotation under load. Rotation-resistant wire rope is designed to resist twisting, spinning, or twisting and can be used in a single-line or multi-part system. Special care should be taken when handling, unrolling, and installing rotation-resistant wire rope. Improper handling or spooling can introduce a twist in the rope, which can lead to uncontrolled twisting.

Compact Strand Wire Rope is manufactured using strands that have been compacted, by means of passing through a die or rollers, reducing the outside diameter of the entire strand. This process occurs before the rope is closed. This process flattens the surfaces of the outer strands in the strand but also increases the density of the strand.

This resulted in a smoother outer surface and increased strength compared to comparable round wire rope compare similar diameters and assortments while also helping to increase surface life due to increased wear resistance.

A swaged wires rope differs from a compacted strand wires rope in that the diameter of a swaged wire rope is compacted or reduced by a rotary swagger machine after the wire rope is closed. A curved wire rope can be manufactured using rounded or narrower wires.

The advantages of a swaged wires rope are that they are more resistant to wear, has better crushing resistance, and has higher strength than a round strand wire rope of similar diameter and assortment. However, a swaged wire rope may have low bending fatigue resistance.

The plastic coating may be applied to the outer surface of a wire rope to provide protection from abrasion, wear, and other environmental factors that can cause corrosion. However, because you can’t see the individuals strand & wires beneath the plastic coating, they can be difficult to inspect.

Plastic-filled wire ropes are fitted with a plastic matrix where the wires and the internal spaces between the wires are filled. Plastic fillings help improve bending fatigue by reducing wear internally and externally. Plastics-filled wire rope is used for demanding lifting applications.

This type of wires rope uses an independent wires rope core (IWRC) that is either filled with plastics or coated in plastic to reduce internal wear & increase bending fatigue life.

Strands of wire rope consist of two or more wires arranged and twisted in a specific arrangement. The individual strands are then laid in a helical pattern around the core of the rope. Strands made of larger diameter wires are more resistant to abrasion, while strands made of smaller diameter wires are more flexible.

The Three Basic Wire Rope Components · Fiber Core (F.C.), usually polypropylene, sometimes hemp (H.C.) and sisal, Independent Wire Rope Core (IWRC), Wire Strand Core (WSC)

The term cable is often used interchangeably with wire rope. However, in general, wire rope refers to diameters larger than 3/8 inch. Sizes smaller than this are designated as cables or cords. Two or more wires concentrically laid around a center wire are called a strand.

The term cable is often used interchangeably with wire rope. However, in general, wire rope refers to diameters larger than 3/8 inch. Sizes smaller than this are designated as cables or cords. Two or more wires concentrically laid around a center wire are called a strand.

A fiber core can be made of natural or synthetic polypropylene fibers. Fiber cores offer greater elasticity than a steel core but are more susceptible to crushing and not recommended for high heat environments. A steel core can be an independent wire rope or an individual strand.

Rotation-resistant wire rope refers to a series of steel ropes that minimizes the tendency to spin or rotate under load. These wire ropes boast a special design – the outer layer is twisted in the reverse direction of the inner layers for counteracting torsional forces generated from multi-layers of strands.

The helix or spiral of the wires and strands in a rope is called the lay. Regular lay denotes rope in which the wires are twisted in one direction and the strands in the opposite direction from the rope. The wires appear to run roughly parallel to the center line of the rope.

We have been dealers of steel wire rope products since 1969 and we have built up a large network of suppliers around the world, so whether you need galvanized 1×19, 7×7, 6×19, 7×19, 6×36, 8×19 , 8×36, 19×7, 35×7 steel wire rope or stainless steel wire rope in the 1×19, 7×7, 7×19, 6×36 - or a special construction - then we are always ready to help.

Steel wire rope from WDI - WDI Ropes is part of the German group Westfälische Drahtindustrie GmbH, whose history dates back to the founding of the first factory in 1856. Since 1890, the company has been known under its current name: WDI. The group produces steel wire rope for many applications, for example steel wire rope for industry and building constructions, etc. We supply the, for us, most interesting part of the program - their program of steel wire rope for eg. industry, construction cranes, maritime cranes and the offshore sectors. These steel wire ropes are known under the brandname PYTHON and you will with garanty find them among our selection here on the page. If we draw parallels to the automotive industry, you can compare PYTHON steel wire rope with brands such as Audi, BMW and Mercedes.

Steel wire rope from CASAR - The company CASAR Drahtseilwerk Saar was founded in 1948. CASAR is the abbreviation for the French outline "Câbleie Sarroise". The company develops or produces special steel wire ropes for cranes and other lifting equipment - steel wire rope produced by CASAR are often preferred by many mobile crane manufacturers as well as other manufacturers of different types of cranes.

Although the type of steel wire rope you choose to buy may not be from one of the well-known brands - our purchasing department ensures that you still get the best possible quality for the price. Steel wire rope purchased from us, is one of the basic elements of a safe lifting operation.

In addition to the sale of steel wire rope, we have over 25 driving services units that can carry out inspection of steel wire rope. In addition, we have workshops in Aalborg, Esbjerg, Odense and Copenhagen - where we can make repairs, carry out casting of sockets or make special solutions in steel wire rope.

The 6 x 19 classification of wire ropes includes standard 6 strand, round strand ropes with 16 through 26 wires per strand. The 6 x 36 classification of wire ropes includes standard 6 strand, round strand ropes with 27 through 49 wires per strand. Although their operating characteristics vary, all have the same weight per foot and the same nominal strength, size for size.

While the 6 x 19 ropes give primary emphasis to abrasion resistance in varying degrees, the 6 x 36 ropes are important for their fatigue resistance. This fatigue resistance is made possible by the greater number of small wires per strand.

Although there are exceptions for special applications, the constructions in 6 x 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.

In this construction, each strand has nine outer wires over nine smaller inner wires over one large center wire. A comparison of cross-sections shows that these outside wires are larger than those of the 6 x 25FW or 6 x 26WS. Therefore, its resistance to abrasion is increased, but its fatigue resistance is decreased. This is a good rope to withstand abrasion or crushing on the drum.

To most wire rope users, 6 x 19 means 6 x 25 filler wire. It is the most common rope in the 6 x 19 classification. This rope has a good balance between both abrasion resistance and fatigue resistance in relation to other ropes.

This construction has better resistance to abrasion than a 6 x 25FW. It also features a compact construction with solid support for the wires; hence, 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 x 25FW.

A standard 6 x 26WS construction 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.

In most rope sizes, only one 6 x 36 classification rope is made. These constructions were selected to provide fatigue resistance without having wires that are too small.

The greater number of wires in the 6 x 36 classification makes these ropes more susceptible to crushing. This can be minimized, however, by specifying an Independent Wire Rope Core (IWRC) and by using well-designed sheaves, grooved drums and proper operating techniques.

Rotation-resistant ropes can frequently provide the best and most economical service in specific applications when you choose, handle and use them properly.

Contra-helically laid, rotation-resistant ropes are different from standard ropes because they"re designed to reduce rope torque. Modes of failure and wear for rotation-resistant ropes can differ from those for standard rope constructions. The very nature of these ropes requires special handling, selection and usage not encountered with standard constructions. They are susceptible to kinking, crushing and unbalancing in the form of "core pops" and "birdcages" Use extreme care to avoid operational practices that can possibly lead to these conditions.

Rotation-resistant ropes should not be used with swivels that allow rope rotation -- or in single part lifts where the load can rotate. Rotation will cause a reduction in strength, unequal loading in the rope and possible rope unbalance. If any significant change in diameter is found in a short length of a rotation-resistant rope, the rope needs to be replaced.

These ropes should be replaced when you see two randomly distributed crown wire breaks in six rope diameters -- or four randomly distributed crown wire breaks in 30 rope diameters.

Because rotation-resistant ropes are special, there are separate design, maintenance, inspection and removal criteria established for them by applicable industry regulations and standards.

In an application where a single-part hoist rope is used to lift a free load -- or where rotation-resistant properties are essential for rope performance -- the 19 x 7 can be used. Its rotation-resistant characteristic is achieved by laying six strands around a core strand in one direction, then laying 12 strands around the first operation in the opposite direction. Thus, when the rope is in tension, opposing rotational forces are created between the inner and outer layers.

In addition, frequent and regular inspection for broken wires is critical when using this rope. Due to its design, the 19 x 7 construction has a relatively low reserve strength. This can result in short service life between the point in time when the broken wire removal criteria are met and when actual rope failure occurs.

In a multi-part wire rope system where the blocks have a tendency to twist -- or for a single-part hoist line that doesn"t require the degree of rotation-resistant properties found in a 19 x 7 rope -- the 8 x 25 Resistwist rope has found successful application. The rotation-resistant characteristic is achieved by laying the eight outer strands around an independent wire rope core so these strands are in the opposite direction to the lay of the core. Thus, when the rope is in tension, opposing rotational forces are created between the core and the outer strands.

Though not as rotation-resistant, the 8 x 25 Rotation Resistant rope is more stable than a 19 x 7 rope. It also has increased resistance to bending fatigue and crushing. This is achieved through the use of eight-strand construction with an independent wire rope core.

Like any application where an installation"s rope type is changed, the 8 x 25 Rotation Resistant rope should be substituted only after carefully comparing specifications and strength requirements.

Wire rope identification is not only done by its component parts, but also by its construction, i.e., by the way the wires have been laid to form strands, and by the way the strands have been laid around the core.

In Figure 3, “a” and “c” show strands as normally laid into the rope to the right in a fashion similar to the threading in a right-hand bolt. Conversely, the “left lay” rope strands (illustrations “b” and “d”) are laid in the opposite direction.

Again in Figure 3, the first two (“a” and “b”) show regular lay ropes. Following these are the types known as lang lay ropes (“c” and “d”). Note that the wires in regular lay ropes appear to line up with the axis of the rope; in lang lay rope the wires form an angle with the axis of the rope. This difference in appearance is a result of variations in manufacturing techniques: regular lay ropes are made so that the direction of the wire lay in the strand is opposite to the direction of the strand lay in the rope; lang lay ropes are made with both strand lay and rope lay in the same direction. Finally, “e” called alternate lay consists of alternating regular and lang lay strands.

HSI is a leader in the wire rope manufacturing industry. Since 1930 when founder Ted Hanes began splicing wire rope for local contractors in Buffalo, we have been dedicated to constructing the highest quality wire rope available.

Wire rope is a durable piece of machinery consisting of several multi-wired strands wrapped around a central core. It is ideal for indoor and outdoor environments, as an incredibly strong and durable rope with resistance to environmental hazards like water, sunlight, heat, and chemicals.

Wire rope consists of a core around which a number of multi-wired strands are “laid” or helically bent. There are two types of cores for wire rope: fiber and wire cores. Fiber cores are made of synthetic fibers, while wire cores are either an Independent Wire Rope Core or a Strand Core. The core provides support and maintains the position of the outer strands during operation.

Any number of multi-wired strands can be laid around the core. The most common arrangement is six strands around the core, as this construction gives the best balance of positive attributes. In general, ropes constructed with more wires have increased flexibility, while ropes constructed with fewer wires have superior resistance to abrasion.

The size, grade, and construction of wire rope needed should be considered when choosing a rope for your application. To learn more about selecting the correct wire rope, wire rope design factors, and to see a comprehensive overview of wire rope, see our Wire Rope Information page.

If you have questions about which wire rope is best suited for your job, please call our product experts at 1-888-426-3755 and we will be happy to advise you on a solution.

HSI standard wire ropes come in a full range of sizes, grades, and constructions. The most common classifications for standard wire rope are 6x7, 6x19, and 6x37. They may be ordered in bright or galvanized finishes, IPS and EIPS grades, right or left lay, and regular lay or lang lay.

While all wire ropes are constructed of multi-wired strands wrapped around a core, cable laid wire ropes take this construction a step further, wrapping several wire ropes, each with their own core, around a central wire rope. This results in a rope constructed with very small wires in reference to its finished nominal dimension which will offer greatly improved flexibility and kinking resistance.

Compact wire rope consists of wire rope strands that have been compacted to reduce the diameter of the strand and increase its density. The resulting rope has superior strength and abrasion resistance compared to standard wire rope, as well increased lateral compression strength. Typical applications for compact wire rope include crane lines, as compact rope can more easily fit into a sheave; and logging applications.

Extra high strength and corrosion resistant galvanized guy strand cable is an extremely sturdy wire rope used to hold structures in place in the construction and transmission industries, as well as a safety barrier cable and guard rail strand. Typical applications include telephone poles and other positioning applications where a sturdy and non-flexible rope is needed.

Commercial grade galvanized aircraft cable is a general purpose wire rope that is used in many industries for its increased corrosion resistance and strength. The galvanized coating on this wire rope provides lubrication while adding a protective layer against abrasive environments. Contrary to its common name, aircraft control cable, commercial grade GAC cannot be used in aircraft control applications.

Rotation resistant wire ropes are constructed with outer strands twisted in the opposite direction of the inner strands, causing the layers to counteract each other’s twist. This prevents rotation of the load during applications where precise lifting or positioning is required. Rotation resistant ropes are available in a full range of sizes, grades and constructions. Swivels are not recommended for use with rotation resistant wire rope.

In stricter senses, the term wire rope refers to a diameter larger than 9.5 mm (3⁄8 in), with smaller gauges designated cable or cords.wrought iron wires were used, but today steel is the main material used for wire ropes.

Historically, wire rope evolved from wrought iron chains, which had a record of mechanical failure. While flaws in chain links or solid steel bars can lead to catastrophic failure, flaws in the wires making up a steel cable are less critical as the other wires easily take up the load. While friction between the individual wires and strands causes wear over the life of the rope, it also helps to compensate for minor failures in the short run.

Wire ropes were developed starting with mining hoist applications in the 1830s. Wire ropes are used dynamically for lifting and hoisting in cranes and elevators, and for transmission of mechanical power. Wire rope is also used to transmit force in mechanisms, such as a Bowden cable or the control surfaces of an airplane connected to levers and pedals in the cockpit. Only aircraft cables have WSC (wire strand core). Also, aircraft cables are available in smaller diameters than wire rope. For example, aircraft cables are available in 1.2 mm (3⁄64 in) diameter while most wire ropes begin at a 6.4 mm (1⁄4 in) diameter.suspension bridges or as guy wires to support towers. An aerial tramway relies on wire rope to support and move cargo overhead.

Modern wire rope was invented by the German mining engineer Wilhelm Albert in the years between 1831 and 1834 for use in mining in the Harz Mountains in Clausthal, Lower Saxony, Germany.chains, such as had been used before.

Wilhelm Albert"s first ropes consisted of three strands consisting of four wires each. In 1840, Scotsman Robert Stirling Newall improved the process further.John A. Roebling, starting in 1841suspension bridge building. Roebling introduced a number of innovations in the design, materials and manufacture of wire rope. Ever with an ear to technology developments in mining and railroading, Josiah White and Erskine Hazard, principal ownersLehigh Coal & Navigation Company (LC&N Co.) — as they had with the first blast furnaces in the Lehigh Valley — built a Wire Rope factory in Mauch Chunk,Pennsylvania in 1848, which provided lift cables for the Ashley Planes project, then the back track planes of the Summit Hill & Mauch Chunk Railroad, improving its attractiveness as a premier tourism destination, and vastly improving the throughput of the coal capacity since return of cars dropped from nearly four hours to less than 20 minutes. The decades were witness to a burgeoning increase in deep shaft mining in both Europe and North America as surface mineral deposits were exhausted and miners had to chase layers along inclined layers. The era was early in railroad development and steam engines lacked sufficient tractive effort to climb steep slopes, so incline plane railways were common. This pushed development of cable hoists rapidly in the United States as surface deposits in the Anthracite Coal Region north and south dove deeper every year, and even the rich deposits in the Panther Creek Valley required LC&N Co. to drive their first shafts into lower slopes beginning Lansford and its Schuylkill County twin-town Coaldale.

The German engineering firm of Adolf Bleichert & Co. was founded in 1874 and began to build bicable aerial tramways for mining in the Ruhr Valley. With important patents, and dozens of working systems in Europe, Bleichert dominated the global industry, later licensing its designs and manufacturing techniques to Trenton Iron Works, New Jersey, USA which built systems across America. Adolf Bleichert & Co. went on to build hundreds of aerial tramways around the world: from Alaska to Argentina, Australia and Spitsbergen. The Bleichert company also built hundreds of aerial tramways for both the Imperial German Army and the Wehrmacht.

In the last half of the 19th century, wire rope systems were used as a means of transmitting mechanical powercable cars. Wire rope systems cost one-tenth as much and had lower friction losses than line shafts. Because of these advantages, wire rope systems were used to transmit power for a distance of a few miles or kilometers.

Steel wires for wire ropes are normally made of non-alloy carbon steel with a carbon content of 0.4 to 0.95%. The very high strength of the rope wires enables wire ropes to support large tensile forces and to run over sheaves with relatively small diameters.

In the mostly used parallel lay strands, the lay length of all the wire layers is equal and the wires of any two superimposed layers are parallel, resulting in linear contact. The wire of the outer layer is supported by two wires of the inner layer. These wires are neighbors along the whole length of the strand. Parallel lay strands are made in one operation. The endurance of wire ropes with this kind of strand is always much greater than of those (seldom used) with cross lay strands. Parallel lay strands with two wire layers have the construction Filler, Seale or Warrington.

In principle, spiral ropes are round strands as they have an assembly of layers of wires laid helically over a centre with at least one layer of wires being laid in the opposite direction to that of the outer layer. Spiral ropes can be dimensioned in such a way that they are non-rotating which means that under tension the rope torque is nearly zero. The open spiral rope consists only of round wires. The half-locked coil rope and the full-locked coil rope always have a centre made of round wires. The locked coil ropes have one or more outer layers of profile wires. They have the advantage that their construction prevents the penetration of dirt and water to a greater extent and it also protects them from loss of lubricant. In addition, they have one further very important advantage as the ends of a broken outer wire cannot leave the rope if it has the proper dimensions.

Stranded ropes are an assembly of several strands laid helically in one or more layers around a core. This core can be one of three types. The first is a fiber core, made up of synthetic material or natural fibers like sisal. Synthetic fibers are stronger and more uniform but cannot absorb much lubricant. Natural fibers can absorb up to 15% of their weight in lubricant and so protect the inner wires much better from corrosion than synthetic fibers do. Fiber cores are the most flexible and elastic, but have the downside of getting crushed easily. The second type, wire strand core, is made up of one additional strand of wire, and is typically used for suspension. The third type is independent wire rope core (IWRC), which is the most durable in all types of environments.ordinary lay rope if the lay direction of the wires in the outer strands is in the opposite direction to the lay of the outer strands themselves. If both the wires in the outer strands and the outer strands themselves have the same lay direction, the rope is called a lang lay rope (from Dutch langslag contrary to kruisslag,Regular lay means the individual wires were wrapped around the centers in one direction and the strands were wrapped around the core in the opposite direction.

Multi-strand ropes are all more or less resistant to rotation and have at least two layers of strands laid helically around a centre. The direction of the outer strands is opposite to that of the underlying strand layers. Ropes with three strand layers can be nearly non-rotating. Ropes with two strand layers are mostly only low-rotating.

Stationary ropes, stay ropes (spiral ropes, mostly full-locked) have to carry tensile forces and are therefore mainly loaded by static and fluctuating tensile stresses. Ropes used for suspension are often called cables.

Track ropes (full locked ropes) have to act as rails for the rollers of cabins or other loads in aerial ropeways and cable cranes. In contrast to running ropes, track ropes do not take on the curvature of the rollers. Under the roller force, a so-called free bending radius of the rope occurs. This radius increases (and the bending stresses decrease) with the tensile force and decreases with the roller force.

Wire rope slings (stranded ropes) are used to harness various kinds of goods. These slings are stressed by the tensile forces but first of all by bending stresses when bent over the more or less sharp edges of the goods.

Technical regulations apply to the design of rope drives for cranes, elevators, rope ways and mining installations. Factors that are considered in design include:

Donandt force (yielding tensile force for a given bending diameter ratio D/d) - strict limit. The nominal rope tensile force S must be smaller than the Donandt force SD1.

The wire ropes are stressed by fluctuating forces, by wear, by corrosion and in seldom cases by extreme forces. The rope life is finite and the safety is only ensured by inspection for the detection of wire breaks on a reference rope length, of cross-section loss, as well as other failures so that the wire rope can be replaced before a dangerous situation occurs. Installations should be designed to facilitate the inspection of the wire ropes.

Lifting installations for passenger transportation require that a combination of several methods should be used to prevent a car from plunging downwards. Elevators must have redundant bearing ropes and a safety gear. Ropeways and mine hoistings must be permanently supervised by a responsible manager and the rope must be inspected by a magnetic method capable of detecting inner wire breaks.

The end of a wire rope tends to fray readily, and cannot be easily connected to plant and equipment. There are different ways of securing the ends of wire ropes to prevent fraying. The common and useful type of end fitting for a wire rope is to turn the end back to form a loop. The loose end is then fixed back on the wire rope. Termination efficiencies vary from about 70% for a Flemish eye alone; to nearly 90% for a Flemish eye and splice; to 100% for potted ends and swagings.

When the wire rope is terminated with a loop, there is a risk that it will bend too tightly, especially when the loop is connected to a device that concentrates the load on a relatively small area. A thimble can be installed inside the loop to preserve the natural shape of the loop, and protect the cable from pinching and abrading on the inside of the loop. The use of thimbles in loops is industry best practice. The thimble prevents the load from coming into direct contact with the wires.

A wire rope clip, sometimes called a clamp, is used to fix the loose end of the loop back to the wire rope. It usually consists of a U-bolt, a forged saddle, and two nuts. The two layers of wire rope are placed in the U-bolt. The saddle is then fitted to the bolt over the ropes (the saddle includes two holes to fit to the U-bolt). The nuts secure the arrangement in place. Two or more clips are usually used to terminate a wire rope depending on the diameter. As many as eight may be needed for a 2 in (50.8 mm) diameter rope.

The mnemonic "never saddle a dead horse" means that when installing clips, the saddle portion of the assembly is placed on the load-bearing or "live" side, not on the non-load-bearing or "dead" side of the cable. This is to protect the live or stress-bearing end of the rope against crushing and abuse. The flat bearing seat and extended prongs of the body are designed to protect the rope and are always placed against the live end.

An eye splice may be used to terminate the loose end of a wire rope when forming a loop. The strands of the end of a wire rope are unwound a certain distance, then bent around so that the end of the unwrapped length forms an eye. The unwrapped strands are then plaited back into the wire rope, forming the loop, or an eye, called an eye splice.

A Flemish eye, or Dutch Splice, involves unwrapping three strands (the strands need to be next to each other, not alternates) of the wire and keeping them off to one side. The remaining strands are bent around, until the end of the wire meets the "V" where the unwrapping finished, to form the eye. The strands kept to one side are now re-wrapped by wrapping from the end of the wire back to the "V" of the eye. These strands are effectively rewrapped along the wire in the opposite direction to their original lay. When this type of rope splice is used specifically on wire rope, it is called a "Molly Hogan", and, by some, a "Dutch" eye instead of a "Flemish" eye.

Swaging is a method of wire rope termination that refers to the installation technique. The purpose of swaging wire rope fittings is to connect two wire rope ends together, or to otherwise terminate one end of wire rope to something else. A mechanical or hydraulic swager is used to compress and deform the fitting, creating a permanent connection. Threaded studs, ferrules, sockets, and sleeves are examples of different swaged terminations.

A wedge socket termination is useful when the fitting needs to be replaced frequently. For example, if the end of a wire rope is in a high-wear region, the rope may be periodically trimmed, requiring the termination hardware to be removed and reapplied. An example of this is on the ends of the drag ropes on a dragline. The end loop of the wire rope enters a tapered opening in the socket, wrapped around a separate component called the wedge. The arrangement is knocked in place, and load gradually eased onto the rope. As the load increases on the wire rope, the wedge become more secure, gripping the rope tighter.

Poured sockets are used to make a high strength, permanent termination; they are created by inserting the wire rope into the narrow end of a conical cavity which is oriented in-line with the intended direction of strain. The individual wires are splayed out inside the cone or "capel", and the cone is then filled with molten lead-antimony-tin (Pb80Sb15Sn5) solder or "white metal capping",zincpolyester resin compound.

Donald Sayenga. "Modern History of Wire Rope". History of the Atlantic Cable & Submarine Telegraphy (atlantic-cable.com). Archived from the original on 3 February 2014. Retrieved 9 April 2014.

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Zinc Coated Wire Ropes – Galvanising Zinc coatings provide sacrificial protection to the underlying steel wire for protection against corrosion where the rope is exposed to corrosive agents – salt, water, moisture, weather etc.

Various coat weights of zinc are available for particular applications; Cookes is ready to advise on the alternative procedures for achieving corrosion protection of wire rope appropriate to the particular environment and manner of usage.

Looking for wire rope? Trinity Sling has been known as the go-to supplier for overhead lifting supplies and rigging for decades. Since its inception, Trinity has produced rigging and lifting solutions for many different industries, like construction, manufacturing, oilfield and fracing, transportation, and architectural railing. Today, the company continues to expand its reach, supplying across North America while calling North Texas home.

Trinity Sling distributes the highest quality wire rope both from domestic and European manufacturers. Trinity’s domestic supplier, Washington Wire Rope, manufactures general purpose and oilfield ropes in the USA to industry standards. Among their products that Trinity carries are crane ropes, drill lines, sand lines and tubing lines for construction and oilfield applications. Trinity also carries Verope-branded crane ropes, European-engineered specialty ropes for all types of cranes used in construction and manufacturing.

Trinity Sling has built strong vendor relationships with Washington Wire Rope and Verope in order to be a great supplier both to our new and existing customers. Our staff understands deadlines and RFQs and works diligently to partner with our customers to provide products of high quality that they can count on.