wire rope construction types quotation

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.

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

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

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

Wire ropes are identified primarily by construction. The number of strands and the geometric arrangement of wires within the strands make up the wire rope construction.

The more common constructions are shown above. Note that each construction can have more wires than shown, but the geometry remains the same. For example, there can be two operations ropes having more than 19 wires; there can be Seale ropes having more than 19 wires; there can be Warrington ropes having more than 19 wires and there can be Filler Wire types having more (or less) than 25 wires. Here are the basic constructions.

Each of the above possesses unique characteristics which must be considered when selecting rope or strand for a job. The specific geometric construction selected depends on the destructive factors present on the job.

The most common factors, abrasion and fatigue, create conflicting requirements. Small (more numerous) outer wires resist fatigue but are easily worn through by abrasion. Larger outer wires have superior abrasion resistance but are more quickly broken by bending and flexing. The difference in outer wire size is seen between the 6 x 19 Seal and 6 x 25 Filler Wire constructions. The nine outer wires in the Seale strands are clearly larger than the 12 outer wires in the Filler Wire strands. Other destructive factors must be considered: peening, corrosion, heat, crushing and shock loads.

Each wire rope construction falls within a classification. Classifications are identified by the number of strands and nominal number of wires. The actual number of wires must fall within a range specified for the given class. For example, ropes within the 6 x 19 class contain 6 strands made up of 15 through 26 wires of which no more than 12 are outside wire. The 6 x 19 Seale and 6 x 25 Filler Wire constructions therefore are both within this class. The more common classifications are 7 x 7, 7 x 19, 6 x 26, 6 x 36 and 19 x 7.

When buying wire rope, cable, and strandproducts, specification numbers are often listed in the description. While these numbers are significant resources, they have little meaning without knowing the requirements and details of each number. Strand Core offers products that conform to nine different specifications. By understanding the various specs, you will be able to shop for the exact requirements you need. We hope this brief guide makes getting the perfect product just a little bit easier.

This specification explains the requirements for flexible wire rope designed for aircraft control. MIL-DTL-83420 covers the requirements of carbon steel and corrosion-resistant steel for the wire rope. There are two different types of MIL-DTL-83420 Wire Rope, Type I (Non-jacketed Wire Rope) and Type II (Jacketed Wire Rope). Both Types must perform to specified levels for characteristics such as breaking strength and stretch limits.

This specification explains the requirements of non-flexible wire rope used in aircraft applications. MIL-DTL-87161 covers the requirements for carbon steel and corrosion-resistant steel for the wire strand used in aircraft application other than over sheaves. The two types of wire rope are Type I (non-flexible, 1x7 class) and Type II (non-flexible, 1x19 class). Both Types have two Constructions, one for Right Lay and the second for Left Lay. There are two composition types of the wire rope. Composition A is made of carbon steel that is zinc coated. Composition B is made of corrosion-resistant steel.

MIL-DTL-18375 covers the requirements for corrosion-resistant, nonmagnetic steel wire rope used in aircraft flight controls. The wire rope can operate within a -65 Degree F to +250 Degree F temperature range in dust, fuel, wind, and oil spills, in wash-down and other environmental stresses and aircraft experiences. All MIL-DTL-18375 wire rope must meet the breaking strength, endurance, stretch limits, ductility of steel, test load, magnetic permeability, and operating temperature range.

MIL-DTL-83140 covers the requirements for rotation-resistant preformed stainless steel wire rope intended for aircraft rescue hoists, utility, retrieval hoists or winching applications. The preformed stainless steel wire rope is available in two types. Type I is a rotation-resistant 19x7 construction that is used for hoisting (vertical) operations. Type II is a rotation-resistant 10x7 construction (7x19 IWRC) used for winching (vertical, horizontal, or at-angle) operations.

RR-W-410 covers wire ropes and wire seizing strands. The specification does not include all types of wire ropes and seizing strands but covers the most common classes, types, constructions, and sizes best suited for federal government use.

This specification covers stranded carbon steel wire ropes used for general purposes. ASTM A1023/A1023M covers various grades, constructions, and performance requirements.

All nine specifications are important to keep in mind when shopping for wire rope, cable, and strand products. Knowing the various specs means you can shop for the exact requirements you need. Strand Core recommends buying wire rope, cable, and strand that meets specific specifications, to ensure you buy a high-quality product that is thoroughly tested and capable of performing at top levels.

To find out more about each of these specifications, please visit our Specifications page here. Or check out our products page to find the wire rope, cable, or strand product for you at strandcore.com. 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.

When browsing the General Purpose Wire Rope page of our website, you may notice that we offer two different6x19 highly flexible cables, and two different 6x37 flexible cables. When looking at the product illustrations, commonly referred to as snowflakes, you may notice a large black area in the center of some wire ropes, and an additional strand in the center of others. How can they be so similar yet so different at the same time? What sets them apart is their cores, and the distinctions betweenIWRC and Fiber Core.

The term IWRC stands for Independent Wire Rope Core. An IWRC is a full wire rope that can be either the same, or different construction as the outer layer strands. It adds strength to the total length of rope, and withstands crushing forces more effectively than other types of cores. It also reduces the amount of stretch a wire rope may undergo during service. IWRC wire ropes are often found in heavy lifting applications such as dredging and logging due to these strength qualities.

To learn more about 6x19 IWRC or 6x19 Fiber Core wire rope, visit https://strandcore.com/products/general-purpose-wire-rope/ or contact us with any questions.

Industrial machines generally have heavy loads to lift and pull. Whether it’s excavators or farm machinery, wire rope is the rope that is used. Industrial wire ropes typically range from 3/8” (9.5mm) to 2-1/2” (63.5mm) in diameter, and besides heavy machining applications, wire ropes also serve as support cables for large static structures such as stadium roofs and bridges. Manufacturing a wire rope begins with steel wire that is anywhere from .6 to 8 millimeters in diameter. The first step is to wind several of these wires together, into a strand. How many wires per strand depends on the application of the wire. Different applications require various levels of flexibility and strength.

Steel wires are used for wire ropes and are typically fashioned from a non-alloy carbon steel material. This metal has a carbon content of 0.5 to 0.95%, which makes it incredibly strong. As a result of its strength and durability, steel wires are able to support large tensile forces and can run over sheaves with small diameters.

Strands are created when wires of different layers cross each other. Parallel lay strands are some of the most commonly manufactured strands. The lay length of the wire strands is generally equal to the wires of any two layers that are parallel. This means that there is linear contact. Inner layer wires support the outer layer wires along the entire length of the strand.

In essence, spiral ropes are round strands that are assembled in layers of wires that are aligned in a spiral design. Spiral ropes are constructed so that they are non-rotating, which means that that there is practically no tension under the rope torque.

Stranded ropes are comprised of several different layers of strand that are laid in multiple spiraling layers around a core. A stranded rope core can come in three different types: fiber cores, wire strand cores, or independent wire rope cores. Fiber cores are the most flexible and elastic of the 3 variations, but are easily crushed. Wire strand cores are typically used for suspension and have a high tensile strength. Independent wire rope is the most durable in all types of environments.

Stainless Steel, galvanised or coated wire rope? Learn about these types of wire rope and select the one most suited for your application. Read on to learn more.

Wire rope is made of metal wire threads braided together to form a helix. Because of its heavy, pliable, and tough characteristics, as well as being weather- and corrosion-resistant, it is commonly used in building and construction, engineering, agriculture, aircraft, and marine industries. Each wire strand bringing equal pressure throughout the bundle contributes to its strength and flexibility, making it an ideal material for pulleys. In Australia, wire rope used to be made of wrought iron; today, the material used is mainly steel.

Different industries use different types of wire rope. This is because suitability of a specific wire rope for an application depends on the design, size, types of braids, and other characteristics. For example, marine grade 316 wire rope is suitable for various marine applications and settings.

Stainless steel is the standard alloy utilized in rope and cable. Its resistance to corrosion is much higher than galvanized and coated ropes, although there is no difference in strength. Therefore, it is the preferred material used in marine and salt-water based industries. It does not react easily to chemicals from food processing, textile, and photographic settings. Its high resistance to corrosion, heat and cold, pulp and paper chemicals make stainless steel wire rope a very essential material for creating precise instruments, automobiles, fishing vessels, petrochemical equipment, and other fields.

Galvanized wire rope is also a steel wire material that has undergone a galvanizing process to enhance its corrosion-resistance. The finished wire product is submerged into a zinc bath to coat its entirety, that is, galvanize it. Zinc is utilized in the process because the cathode preservation increases the life expectancy of the wire. Though the coating will wear off as time goes by, it is still resistant to rust, corrosion, and other harsh chemicals. Galvanized wire can be found in industrial and construction fields as well as agricultural and DIY projects.

Stainless steel and galvanized wire can be coated with PVC (poly-vinyl-chloride) or vinyl. Coated wire rope comes in various colours such as clear, black, white, or any other colour that is required in different industries. PVC coated wire is flexible, weather-resistant, and very cost-effective. Nylon coated wire, though not as flexible as PVC, is abrasion-resistant and is ideal for businesses in extremely cold regions.

Wire rope can be assembled to suit specific applications. If you have a project requiring specific types of wire rope, send us an enquiry and we’ll send you a specialised quote.

Wire rope is a collection of metal strands that have been twisted and wound to form the shape of a helix with the purpose of supporting and lifting heavy loads and performing tasks that are too rigorous for standard wire. On shipping docks, rigging, and load bearing equipment, wire rope is attached to swivels, shackles, or hooks to lift a load in a controlled, even, and efficient manner.

The uses for wire rope include adding support to suspension bridges, lifting elevators, and serving as additional reinforcement for towers. The design of wire rope, with its multiple strands wrapped around a stable core, provides strength, flexibility, and ease of handling for applications that have bending stress.

Individual designs of wire rope involve different materials, wire, and strand configurations as a means for supporting and assisting in the completion of lifting or supportive applications.

The term wire rope encompasses a wide range of mechanical tools that are made to perform heavy and extreme lifting jobs. Wire rope is a complicated and complex tool with multiple moving parts capable of moving in unison. A 6 by 25 wire rope has 150 outer strands that move as one in an intricate pattern supported by a flexible core.

An essential part of the design of wire rope is the required clearance between the strands to give each stand the freedom to move and adjust when the rope bends. It is this unique feature that differentiates wire rope from solid wire and other forms of cable.

The basic element of wire rope is wire that is used to configure, shape, and form the rope. Typically, steel, stainless steel, and galvanized wires are the first choice with aluminum, nickel alloy, bronze, copper, and titanium being second possibilities. The choice of wire is dependent on the type of work the wire is going to be used to perform with strength, flexibility, and abrasion resistance being the major determining factors.

Stainless steel wire rope has all of the basic qualities of galvanized and general wire rope with the added benefits of corrosion and rust resistance; this makes it the ideal choice for harsh and stressful conditions.

Steel wire rope is classified as general purpose wire rope and comes in a wide variety of sizes, diameters, and strengths. It is the most common type of wire rope and is used for several industrial, manufacturing, and construction applications.

Before going further into the discussion of how wire rope is made, it is important to understand the numbers used to describe each type. All wire ropes have a core around which wires are wound. The various styles of cores vary according to the construction and design of the requirements of the wire rope that is being produced.

Wire rope is classified by the number of strands it has as well as the number of wires in each strand. The most common classification is a seven wire rope that has one strand in the center and six around its circumference. This type of wire rope is lightweight with a very simple construction. The majority of wire ropes are more complex and intricate with multiple intertwining strands and wires.

What must be understood about wire rope is that it has a complicated configuration. It is actually wires wrapped around wires to form bundles that are wrapped around other bundles. In the case of a seven wire wire rope, the core has bundles of wires wound around it; this can be seen in the image below.

The first step in wire rope creation is the production of wire strands where wires are wound around a single core wire. The number of wires included in the strand is dependent on the specified strength, flexibility, and size requirements of the rope. Once the strand is completed, it is straightened before being moved to wire rope construction.

Like wire ropes, strands have different patterns; patterns are the arrangements of the wires and their diameters. Though most strands have a core, there are strand patterns that have three or four wires without a core that are referred to as centerless strands. The design of each strand pattern is meant to enhance the strength of the wire rope and improve its performance.

For a multiple layer strand, the layers of wire are placed over one another in successive order. The placement of the wires on top of each other must be such that they fit smoothly and evenly.

The Warrington pattern is like the multiple layer pattern with one variation. Like the multiple layer pattern, the inner wires and the core are the same and have the same diameter. The difference is in the outer layer, which has wires of alternating sizes of large and small with larger diameter wires laying in the valleys of the inner wires.

All of the wires of a filler pattern are the same size. What makes this pattern unique is the insertion of small wires in the valleys of the inner wires to fill the gap between the inner and outer layer.

The flattened strand pattern is also known as the triangular strand, which can be triangular or oval. Three round wires form the core. The outer flattened surface has a greater sectional metallic area; this makes this pattern stronger and longer lasting.

The core of a wire rope runs through the center of the rope and can be composed of a variety of materials, which include synthetic fibers, natural fibers, a single strand, or another wire rope. The core supports the wound strands, helps maintain their position, is an effective lubricant carrier, and provides support.

Wire ropes with fiber cores are restricted to light loads and are not used in severe, harsh, or stressful conditions. Polypropylene and nylon are types of synthetic fiber cores and can be used in conditions where there is exposure to chemicals.

Cores made of wire are classified as independent wire cores. The core of a wire rope with a wire core is actually a wire rope with another wire rope serving as the core, as can be seen in the diagram below. These types of wire ropes are used where the rope will be exposed to exceptional resistance and crushing.

A strand, or wire strand core, is exactly like the rest of the strands of the wire rope with wires of the same diameter and size as the other strands.

The choice of core and creation of the strands are the simplest yet most essential parts of wire rope construction. Wire rope lays, the method used to wind the strands, is more complex and involves several choices.

Lay is a term used to describe three of the main characteristics of wire rope: direction, relationship, and linear distance. The strands can be wrapped around the core going right or left. Right or left refers to the direction of the strands wrapped around the core and the wires within the strands. The linear distance is how far a strand moves when it is making a revolution around the core.

In a regular lay, the wires and strands spiral in opposite directions. With a right hand regular lay, the wires spiral to the left and the strands to the right. In the left hand regular lay, the wires spiral to the right and the strands to the left. This type of lay is easy to handle but wears out quickly because the crown wires are in contact with the bearing surface.

In the Lang, or Albert, lay, the wires and strands spiral in the same direction with right hand lay being the most common. The wires in a Lang lay appear to run parallel to the center line of the rope. The difficulty with Lang lay wire ropes is handling since they tend to kink, twist, and crush.

Wire rope is an exceptionally strong tool that has been configured and designed to withstand the stress placed upon it through rigorous and continual use. In most applications, wire rope has to endure extreme stress and strain. It is for these reasons that coatings have been developed to protect wire rope from abrasions, corrosion, UV rays, and harmful and damaging chemicals.

Three main types of coatings are used to protect wire rope: polyvinyl chloride (PVC), polypropylene, and nylon. Of the three types, PVC is the most popular.

In cases where there are severe and hazardous working conditions, polypropylene is the recommended choice since it is capable of protecting wire rope against corrosion and chemical leaching. Additionally, it is resistant to impact damage and abrasion. Polypropylene is a tough, rigid, and crystalline thermoplastic that is made from a propene monomer and is resilient as well as inexpensive.

Braided wires are electrical conductors made up of small wires that are braided together to form a round tubular braid. The braiding and configuration of braided wire makes them very sturdy such that they do not break when flexed or bent. Braided wires are widely used as conductors, are commonly made from copper due to copper"s exceptional conductivity, and can be bare or coated depending on the application.

Braided wire can be round and tubular or flat. Round tubular braids fit in most spaces where flat braided wire will not. Flat braided wire begins as round braided wire which is flattened on a capstan. They are exceptionally strong and designed for medical and aircraft applications.

Metals used to make wire rope are various grades of stainless steel, bright steel, and galvanized steel. Though the majority of wire rope manufacturers use these three metals, other metals such as copper, aluminum, bronze, and monel are also used on a limited basis.

The most important aspect of wire rope is the wire and the metal from which it is made. The strength and resilience of wire rope is highly dependent on the quality of metal used to make it, and these are essential factors to be considered when purchasing it.

Bright steel wire does not have a coating and is rotation resistant, (designed to not rotate when lifting a load). It is drawn from hot rolled rods that are put through a die to match its specific dimensional tolerances, mechanical properties, and finish. Bright wire is used as a single line in conditions that require a rope that will resist cabling.

Galvanized steel has a zinc coating for corrosion resistance and has the same strength and durability as bright steel. Environmental conditions determine the use of galvanized steel. In mildly severe and slightly harsh conditions, galvanized steel wire is an economical replacement for stainless steel.

In the manufacturing process, galvanized wire goes through the process of galvanization, a method of coating steel wire with a protective and rust resistant metal. Galvanized wire is exceptionally strong, rust resistant, and flexible enough to meet the needs of a variety of applications.

Wire rope made from copper is mostly used for electrical applications due to its exceptional electrical characteristics. The benefits of copper wire rope are its durability, flexibility, and resilience compared to standard copper wire. The strength of copper wire rope is seen in its use in applications where there are vibrations and shaking.

The wire rope lubrication process begins during its fabrication and continues during its use. Lubrication of wire rope is designed to lower the amount of friction it endures and provide corrosion protection. Continued lubrication increases the lifespan of wire rope by preventing it from drying up, rusting, and breaking.

The types of lubricants for wire rope are penetrating or coating with coatings covering and sealing the outside of the rope. Penetrating lubricants go deep into the rope and seep into the core where they evaporate to form a thick coating or film.

The application of the lubricant is dependent on the type of core. Fiber cores absorb the lubricant and serve as a reservoir that retains the lubricant for an extended period of time. With metal cores, the lubricant is applied as the wire is twisted into strands to give complete saturation and coverage of the wires.

There are several types of greases that are used as wire rope lubricating agents and are made up of oil, a thickener, and additives. The essential components are the base oil and additives, which influence the behavior of the grease. The thickener holds the base oil and additives together. The amount of base oil in a grease is between 70% and 95% with an additive of 10%.

The additive in grease enhances the positive properties of the oil and suppresses the negative properties. Common additives are oxidation and rust inhibitors as well as pressure, wear, and friction reducing agents.

Of the many choices for lubricants, vegetable oil is the easiest to use and penetrates the deepest. The design of the additives for vegetable oils gives them the necessary qualities required to penetrate deep into a wire rope. The exceptional penetration provides protection against wear and corrosion. Since vegetable oil is a fluid, it helps in washing the wire rope to remove external abrasive contaminants.

Wire rope is widely used in machines, structures, and varied lifting applications. Its type, size, and requirements are determined by how it will be used. Regardless of its use, wire rope guarantees exceptional strength and provides high quality and excellent performance.

The lifting of heavy loads for centuries involved the use of hemp rope or chains, neither of which was a guaranteed or substantial method. Early in the 18th Century, between 1824 and 1838, Wilhelm Albert, a German mining engineer, combined the twisting of hemp and strength of chains to create today‘s wire rope.

The most common use of wire rope is as a part of a crane hoist wherein it is attached to the hook of the hoist and wrapped around a grooved drum. The tensile strength and durability of wire rope makes an ideal tool for lifting and keeping loads secure. Though it is used in several industries, it is very popular for production environments wherein materials need to be lifted quickly and efficiently.

In addition to its many lifting applications, the strength and stability of wire rope is useful in other applications, especially in the aerospace industry. Pedals, levers, and connectors in the cockpit of an aircraft are connected with wire rope. The wires provide for the passage of power between systems and mechanisms; this allows control of the aircraft. Wire rope is used to control propeller pitch, cowl flaps, and the throttle. It also assists in lowering and minimizing vibrations.

Tires are reinforced with wire rope to increase their durability and strength. All automotive production environments make use of wire ropes for supplying materials, moving heaving loads, and positioning equipment. Wire rope can be found in the production of steering wheels, cables, exhausts, springs, sunroofs, doors, and seating components.

As surprising as it may seem, the place that wire rope has the greatest use is in the home, where its strength, long life, endurance, and resilience provide guaranteed protection and performance. The main reason wire ropes are so popular for home use is cost.

Inexpensive, easy to obtain, easy to install, and easy to maintain, wire ropes provide an additional method for performing home repairs and structural support. Their excellent flexibility and sturdiness combined with their invisibility has made wire rope an ideal solution to several home maintenance issues. It is used to support staircases, fences, decks, and hang plants.

The search and production of crude oil has relied on wire ropes for centuries to lift drill bits, insert shafts, and support oil rigs on land and the water. When equipment, machinery, and tools have to be lowered into the depths of the earth and sea, wire ropes are the tool that the oil industry relies on to do the job.

Many of the tasks of oil production require tools that are capable of enduring severe and harsh conditions. Wire ropes have to withstand enormous pressure, extraordinary stress, and a wide range of temperatures. The use of wire rope includes maintaining oil rig stability and moorings for offshore rigs.

Wire rope has long been a standard component for the transportation industry, from the cable cars of San Francisco to the lift chairs for ski resorts. For many years, cable cars have relied on heavy duty cables (wire ropes) to be pulled by a central motor from multiple locations. It is a method of transportation that has existed for centuries.

In Europe, funiculars use cables that hang from a support to move cars up and down a mountain with cables moving in opposite directions. The word funicular is from the French word funiculaire, meaning railway by cable. The terms wire rope and cable are used interchangeably when discussed by professionals. The first part of funicular, or funiculaire, is from the Latin word "funis," meaning rope.

The major use for wire ropes in the food and beverage industries is as a means for lifting and moving heavy loads. Wine barrels and containers full of ingredients are lifted and placed through use of cranes and wire ropes. They are also part of conveyor systems that move products from one station to another.

From the beginnings of amusement rides up to the present, wire ropes have been an essential part of attraction construction and safety. They pull cars on roller coasters, hold cabins that swing, and move carriages through haunted houses. The main concern of amusement parks is safety. The strength, stability, and guaranteed performance of wire ropes ensures that people who attend amusement parks will have a good time and stay safe.

The rigging used to complete the stunts in modern movies depends on wire rope for safety. Much like in amusement rides, wire ropes protect performers from injury and harm as they hang above a scene or carry out an impossible move.

The live theater industry uses wire ropes to raise and lower curtains, support overhead rigging, and hold backdrops and scenery pieces. During a production, rapid and efficient movement is a necessity that is facilitated by the use of wire ropes.

Wire rope is a tool that we tend to envision as indestructible, unable to succumb to any form of damage. Though it is exceptionally sturdy and strong as well as capable of enduring constant use, it is just as susceptible to breakdown as any other tool.

To avoid serious harm and damage, wire ropes should be scheduled for regular inspections. There are situations that can damage or break a wire rope; these should be understood prior to the problem arising.

Guide rollers have the potential to damage and cause abrasions on wire rope if they become rough and uneven. Of the various elements of a crane and lift, guide rollers have the greatest contact with the mechanism‘s wire rope. Regular inspection of guide rollers will ensure they are not damaging the rope or causing abrasions.

Bending is normally a regular part of wire rope usage; this occurs repetitively as the rope passes through a sheave. As a wire rope traverses the sheave, it is continually bent and develops cracks or breaks. The cracking and breaking are exacerbated by movement on and off the groove of the drum. Normally, the breakage happens on the surface and is visible. Once it appears, it accelerates to the core of the rope.

A bird cage is caused by a sudden release of tension and a rebound of the rope. This type of break requires that the rope be replaced since the place of the break will not return to its normal condition.

Wire ropes are multi-layered; this makes them flexible and torque balanced. The layering inside and outside creates flexibility and wear resistance. Relative motion between the wires causes wear over time, which leads to internal breakage. The detection of these breaks can be indicated by an electromagnetic inspection that calculates the diameter of the rope.

Kinked wire rope is caused by pulling a loop on a slack line during installation or operation; this causes a distortion in the strands and wires. This is a serious condition that necessitates rope replacement.

Corrosion damage is the most difficult cause of wire rope damage to identify, which makes it the most dangerous. The main reason for corrosion is poor lubrication that can be seen in the pitted surface of the rope.

The types of damage and problems listed here are only a small portion of the problems that can be caused if a wire rope is not regularly lubricated and inspected. Various regulatory agencies require that wire ropes be inspected weekly or monthly and provide a list of factors to examine.

As with any type of heavy duty equipment, wire rope is required to adhere to a set of regulations or standards that monitor and control its use for safety and quality reasons. The two organizations that provide guidelines for wire rope use are the American Society of Mechanical Engineers (ASME) and the Occupational Safety and Health Administration (OSHA).

All wire rope manufacturers and users closely follow the standards and guidelines established by OSHA and ASME. In the majority of cases, they will identify the specific standards they are following in regard to their products.

OSHA‘s regulations regarding wire rope fall under sections 1910, 1915, and 1926, with the majority of the stipulations listed in 1926 under material handling, storage, use, and disposal.

"Running rope in service shall be visually inspected daily, unless a qualified person determines it should be performed more frequently. The visual inspection shall consist of observation of all rope that can reasonably be expected to be in use during the day‘s operations. The inspector should focus on discovering gross damage that may be an immediate hazard."

"The inspection frequency shall be based on such factors as rope life on the particular installation or similar installations, severity of environment, percentage of capacity lifts, frequency rates of operation, and exposure to shock loads. Inspections need not be at equal calendar intervals and should be more frequent as the rope approaches the end of its useful life. Close visual inspection of the entire rope length shall be made to evaluate inspection and removal criteria."

ASTM A1023 covers the requirements for steel wire ropes with specifications for various grades and constructions from ¼ in. (6 mm) to 31/2 in. (89 mm) manufactured from uncoated or metallic coated wire. Included are cord products from 1/32 in. (0.8 mm) to 3/8 in. (10 mm) made from metallic coated wire.

United States Federal Spec RR W 410 covers wire ropes and wire seizing strands but does not include all types, classes, constructions, and sizes of wire rope and strands that are available. The purpose of Spec RR W 410 is to cover more common types, classes, constructions, and sizes suitable for federal government use.

Wire rope and wire seizing strand covered by United States Federal Spec RR W 410 are intended for use in general hauling, hoisting, lifting, transporting, well drilling, in passenger and freight elevators, and for marine mooring, towing, trawling, and similar work, none of which are for use with aircraft.

API 9A lists the minimum standards required for use of wire rope for the petroleum and natural gas industries. The types of applications include tubing lines, rod hanger lines, sand lines, cable-tool drilling and clean out lines, cable tool casing lines, rotary drilling lines, winch lines, horse head pumping unit lines, torpedo lines, mast-raising lines, guideline tensioner lines, riser tensioner lines, and mooring and anchor lines. Well serving wire ropes such as lifting slings and well measuring are also included in API 9A.

Wire rope is a collection of metal strands that have been twisted and wound to form the shape of a helix with the purpose of supporting and lifting heavy loads and performing tasks that are too rigorous for standard wire.

Individual designs of wire rope involve different materials, wire, and strand configurations as a means for supporting and assisting in the completion of a lifting or supportive task.

Wire rope is constructed of multiple strands of wire that are twisted and braided together to form a spiral design or helix. Once the separate wires are shaped into a solid form, they become a single wire with greater strength because the individual wires equalize pressure and have greater flexibility than the individual strands.

To further enhance the strength of wire ropes, they are grouped and wound together to produce cables, which adds to their usefulness as a means of support, ability to lift, and give structural stability.

A key factor in wire rope is the lay of the strands, which can be regular or lang. With regular lay, or right and ordinary lay, the strands are wound from left to right with the wires laid in the opposite direction of the lay of the strands. With lang lay, the wires are wound in the same direction.

The structure and design of wire rope produces a final product that has superior strength, excellent strength flexibility, and the ability to handle constant bending stress as well as being weather resistant.

Wire rope is one of those products that has found a place in a wide variety of industries since it can be adapted and shaped to fit several applications. It can be found as a tow cable for boats and airplanes or in the movie industry as a harness for stunt artists. The varied uses of wire rope have made it an essential part of operations that require a rope with strength, endurance, and flexibility.

In the aerospace industry, wire ropes, or Bowden cables, connect pedals and levers in the airplane cockpit to send power to aircraft systems to control the airplane. The things that are controlled by wire ropes are propeller pitch, cowl flaps, and throttle. Wire ropes on aircraft are insulated to avoid vibrations.

Wire rope is extensively used in the auto industry for a wide variety of applications due to its versatility and strength. It is used for raising windows and opening and closing sunroofs. Other uses include steering wheels, cables, exhausts, springs, sunroofs, doors, and seat components. In the manufacturing process, wire rope is used to hoist vehicles, move large body parts, and on hoists and cranes.

The construction industry has a greatest reliance on wire rope because of the need to lift and lower heavy loads. Wire rope used in construction must have extremely high strength and exceptional performance for safety reasons and efficiency. Larger versions of wire rope are used for suspension bridges and supporting concrete columns.

The main use of wire rope in food processing is for lifting, moving loads, and other heavy tasks. Finished products or raw materials require being moved in storage units and processing centers. The strength and endurance of wire rope makes it possible to move these materials. Wire rope for food processing must be able to withstand regular chemical cleaning.

As with other industries, the oil and gas industry needs strong and reliable equipment for moving heavy equipment. In ocean drilling, machinery is dropped into the ocean using wire rope to securely hold devices to be dropped to extreme depths. Wire ropes are designed to withstand the extreme pressure and stress required. A further use of wire ropes for drilling operations is to maintain stability in the drilling lines. One of the unique features of oil rig wire rope is its length, which can exceed 10,000 feet.

A very common use for wire rope is mooring and towing of sea and freshwater boats and vessels. In the shipbuilding industry, wire rope is used to secure lifeboats as well as lower them into the water. On sailboats, wire rope is used to lift and lower sails. The benefit of using wire rope is its resistance to corrosion and rust caused by salt water and ocean mist.

The skiing industry, much like heavy equipment industries, uses wire rope to hold cars, lifts, or chairs to transport skiers up the mountain. This type of wire rope comes in several varieties depending on the size of the mountain. The benefits of wire rope for skiing is its dependability, guaranteed safety, and reliability. The main challenge of wire rope for use in sports is the weather conditions it must endure.

Since the beginnings of amusement parks, wire rope has been an essential part of attraction construction. It is used to bring roller coaster cars to the top of the ride, hold swings, and pull various vehicles through attractions. One of the main concerns of public amusement parks is safety since rides are filled with powerful machinery designed to operate continuously.

Making the dangerous and exciting shots in movies requires well planned safety precautions. One of the aspects of that planning is wire rope that is designed to protect performers when they are engaged in dangerous and life threatening shots. Dependable wire ropes are ideal since they have the flexibility, strength, endurance, and versatility to be adapted to any conditions.

In architecture and design, wire rope has been used for guard rails, balustrades, and roof construction. In innovative green buildings where plants grow along the surface of the building, the plants grow along specially designed vertical wire ropes that are capable of withstanding weather conditions.

A common use of wire rope is in railings, which are safe, durable, and provide a pleasing aesthetic appeal. The use of wire rope for railings provides protection without obstructing the view from a building. This aspect of wire rope is one of the reasons that it is used for large architectural projects since it blends into the structure without interiors with the architectural design.

The types of wire rope are determined by the number of wires in each strand and how many are in the rope, which is defined by a two number system with the first number being the number of wires and the second being the number of wires in each strand. For example, a 6x19 wire rope has 6 wires in 19 strands.

There are a wide variety of products that are produced using wire rope. The demand for wire rope products is due to its strength, durability, and reliability. Since the basic purpose of wire rope is to lift and move heavy materials and items, the most common type of wire rope product is the wire rope sling.

Though the construction of wire rope slings is very similar for all types, there are certain variations applied to slings to adjust them to fit different applications. Slings are configured in various ways to fit different types of loads. These changes are referred to as hitches.

Bridle Hitch: The multiple leg or bridle hitch style has more than one wire rope sling attached to equalize the load and control balance. They reduce load damage by using fixed points on the load and offer easier rigging when hooked into fixed lifting points. .

Single Part Wire Rope Sling: The eye for a single part wire rope sling is formed by looping the wire rope back on to the rope. The end of the rope is attached by a clamp or being woven by hand or mechanically into the rope body. Single part wire rope slings use a single wire rope to produce the sling.

Braided Wire Rope Sling: A braided wire rope sling is made by braiding wire ropes to form a sling. The increased number of strands enhances the strength of the sling and its load capacity. Braiding can be done with three to nine wire ropes.

Cable Laid Wire Rope Sling: Cable laid wire rope slings are made from combining several smaller wire ropes to form a flexible, easy to handle, and kink resistant sling.

Woven Eye Wire Rope Sling: For the woven eye version of a wire rope sling, the eye is formed by weaving the wire rope into itself after forming the loop. It is designed to reduce the chance of the sling catching or being hung up when lifting.

Thimble Wire Rope Sling: To add to the strength of wire rope slings and lessen the stress on a small area of the eye, a thimble, a U shaped piece into which the wire rope fits, is placed in the eye, which helps the sling to retain its natural shape. The thimble is positioned to prevent the hook or load from coming in contact with the wire rope.

Endless Wire Rope Sling:Endless wire rope slings are adaptable slings without a set wear point. They can be manufactured in a wide range of sizes and are used in applications where headroom may be a problem. Endless wire rope slings are made by splicing the ends of a piece of wire rope together or by tucking strand ends into the body to form a core with a tucked position the opposite of the core position. They are also referred to as grommet wire rope slings.

Coiled wire rope is made from bundles of small metal wires that are twisted into a coil. It comes in many varieties and is easy to store since it does not require a spool. Coiled wire rope is produced in coils. When it is not in use, it springs back into a coil, which makes it easy to handle.

Cable wire rope is a type of high strength rope, made of several individual filaments. These filaments are twisted into strands and helically wrapped around a core. One of the most common types of wire rope cable is steel cable.

Push pull wire rope assemblies are used to send force and are used in the aircraft, exercise, medical, automotive, and office equipment industries. Unlike using a single heavy wire, push pull assemblies made with wire rope are stiffer and have a larger bend radii for smoother motion of the wire.

Wire rope assemblies include wire rope and various parts and components that have been added to the wire rope to enhance its function. The connectors for a wire rope assembly are designed to connect the assembly to hooks, equipment, or machines as well as other wire rope assemblies. The central part of a wire rope assembly is the wire rope, which determines the type and kind of work the assembly can perform.

Wire rope lanyards are a standard wire rope product that have a multitude of uses. They are produced using the same process that is used to produce wire rope with the same numbering categorizing system. Lanyards are used to hold fasteners, hardware, or components to prevent loss of an item or prevent injury.

In many ways, wire rope is a form of machine with multiple moving parts. Normally, when we think of a machine, we imagine a device with a motor, drives, and gears. Wire rope does not have any of those components but does fit the definition of being a complex mechanism. It has moving parts that work together to move heavy materials and loads.

The main function of wire rope is to do heavy lifting, which is very dependent on wire rope slings. The type of sling is determined by the quality of the wire rope used to form them and whether several ropes have been braided or wound together.

Wire is the smallest part of wire rope but makes up the various strands. The composition of the wire can be steel, iron, stainless steel, copper, or other types of metal wires and are produced in different grades. The individual wires can be coated or bright, meaning uncoated.

Strands are sets of wires that are twi