This Article takes an In-depth look at Wire Mesh
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Wire mesh, often known as wire fabric, wire cloth, or hardware mesh, is crafted by interlacing, weaving, or welding wires of variable thicknesses into uniformly spaced rows and intersecting columns. Crafted on industrial looms, this method produces square or rectangular openings between wires. Alternatively, welded wire mesh is crafted by electrically welding intersecting longitudinal wires.
There is an almost endless array of shapes, sizes, and configurations of wire mesh crafted from a variety of robust materials. These mesh configurations primarily function to separate, screen, structure, and shield various applications and processes. Wire types include galvanized steel, stainless steel, aluminum, steel, and copper alloys. Factors such as the intended use, required tensile strength, durability, lifespan, and necessary flexibility help in determining the ideal wire type and style.
The production of wire mesh involves weaving or welding. Weaving is akin to textile weaving on a loom, while welding joins wires at crossing points. Automated, pre-configured machinery facilitates both processes.
The demand for woven wire cloth surged in the late 17th century due to its use in the mining and pulp industries, prompting the development of wire weaving looms. Over time, wire mesh has evolved beyond its original purposes to be used in architecture, plastic extrusion, and filtration processes, as well as aggregate screening. This evolution has sparked the growth of the industrial wire weaving sector.
Weaving Loom — Mesh rolls are woven on looms with widths ranging from 48” to over 98”. Looms have a warp beam, heddle frames, a reed, a rapier for moving weft wire, and a take-up mechanism.
These looms produce standard and custom mesh patterns, which are cut to customer-specified lengths. Horizontally or lengthwise woven wires are called warp wires while vertically or crosswise woven wires are termed weft or shute wires, reflecting textile terminology.
Once the loom is set up and warp beam loaded, weaving becomes an automated cycle. As the loom operates, the warp beam unwinds evenly while the take-up mechanism rolls up the finished fabric in sync. This coordination maintains appropriate tension, crucial for high-quality fabric production.
Wire mesh welding involves a semi-automatic process where wire intersections are fused. Specialized welding machines apply uniform welds at each intersecting point using techniques like resistance welding, TIG welding, plasma welding, and soldering.
Often consisting of thicker wires for enhanced robustness and strength, welded mesh is usually more durable than woven mesh. Its welding process imparts additional rigidity, making it perfect for fencing, cages, and reinforcement applications in concrete.
Wire mesh types are classified by fabrication methods, characteristics, functionalities, and weave designs, tailored for specific strength, weight, and finishing needs. Critical selection factors include metal type, mesh pattern, and finish, with metal choice being particularly essential.
This mesh, formed by welding wires into square grids, is a strong choice for secure fencing, storage shelves, animal enclosures, room partitions, and pest traps.
Attributes of welded wire mesh include:
Stainless steel welded wire mesh inherits the corrosion resistance and sturdiness of its material, ensuring sustained performance.
Crafted from standard or carbon steel wire, galvanized wire mesh features a protective zinc coating applied during galvanization. This layer serves as a shield against rust and corrosion. Mesh made with galvanized wires or zinc-coated plain steel after weaving offers variable pricing, with post-galvanization yielding superior quality.
Galvanized wire mesh meets various needs, such as fencing for agriculture and gardening, greenhouses, architectural purposes, construction, protective barriers, window guards, and infill panels. Its affordability enhances its popularity among wire mesh types.
Applying a vinyl coating to either woven or welded wire mesh forms a resilient protective layer that remains stable over broad temperature ranges, unaffected by sunlight, and resists damage. Vinyl coatings enhance visual appeal while bolstering durability, resisting rust and corrosion, and shielding against moisture and external elements by encasing the wires for lasting performance.
Welded steel bar gratings undergo forge welding at high temperatures, bonding vertical and horizontal bars for enduring strength and stability. Made from carbon or stainless steel, these gratings excel in robustness and rigidity.
Engineered for heavy-duty use, they are found in ramps, bridge decking, ventilation grilles, sidewalks, landings, and industrial floors. Panels vary in widths from two to three feet, lengths of two feet, with bar depths from 1” to 6” and thicknesses between 0.25” to 0.50”.
Known for high-quality attributes, stainless steel mesh leverages its metal properties for outstanding performance. Where traditional steel is prone to rust, added chromium in stainless steel offers protective resistance to oxidation, elevating its suitability for outdoor applications.
Welded or woven, stainless steel mesh is favored for its reliability, immunity to corrosion, and suitability across diverse applications, especially for external and marine settings due to its resistance to climate challenges.
Common stainless steel grades include 304, 304L, 316, 316L, 321, 347, and 430, with wire diameters from 0.0085 inch (0.216 mm) to 0.307 inch (7.8 mm). Mesh openings, key in design, define usage, with those less than 0.25 inch (6.35 mm) termed wire cloth.
Grade 316 stainless steel, an ideal marine alloy, withstands oxidation, acids, and salt exposure excellently, available in fine to coarse varieties. Grade 304, though less corrosion-resistant than 316, is significantly workable and cost-efficient.
Wire mesh patterns determine its usage suitability across applications. There's a range of standard and customized patterns. A defining characteristic is whether the wire is crimped, involving mechanical shaping of weft or warp wires to enhance functionality and appearance.
With either square or rectangular weaves, crimped wire mesh is made by a crimping mesh machine. The crimping process compresses wire so weft overlaps warp wires, creating an interlocking effect.
Pre-Crimp — Wires undergo pre-crimping for added folds or ridges prior to weaving, boosting wire mesh strength and firmness by keeping weft and warp wires intact in place.
Lock Crimp — Lock crimp utilizes the crimp grooves to secure weaves at intersections, enhancing sturdiness and stability.
Inter-Crimp — This process involves additional crimps between intersections on fine wires with large openings, ensuring precise warp and weft wire locking for enhanced rigidity.
Non-crimped or plain wire mesh is woven using basic over-and-under techniques, producing a smooth, uncomplicated surface. This approach yields high mesh count patterns, often featuring a 3x3 weave or finer, prevalent in screens such as window or door screens.
Double weave wire mesh offers enhanced toughness due to a dual wire weave method. Here, warp wires wrap over two weft wires, making this mesh ideal for rigor-demanding applications like vibrating screens, agriculture, and barbecue screens.
Flat top weaves pair non-crimped warp wires with crimped weft wires, creating a lockable mesh that remains smooth, reducing friction and abrasion potential. Ideal for architectural and structural needs, it's favored in applications like vibrating screens for durability and efficiency.
The twill weave pattern involves alternating warp wire over-under placement across two weft wires, creating a diagonal design with enhanced strength and durability. This weave is adept at supporting heavier loads and is fundamental in filter, colander, shielding, and insect screen fabrication, using corrosion-resistant stainless steel grades 304 and 316.
Dutch weave wire mesh differs with varied wire diameters for warp and weft, ensuring greater tensile strength and superior filtration. Dutch weaves, crafted in plain or twill patterns, offer strength and filter efficacy.
Plain Dutch Weave — Integrates plain weave with Dutch weaving, using wires of varying thickness, favoring mechanical stability, finer openings, and maximal tensile strength.
Twill Dutch Weave — This merges twill and Dutch weaves, producing a much finer result for filtering applications, capable of supporting substantial loads and enhancing filtering precision and tensile strength.
Off count wire mesh features a different number of openings in horizontal and vertical directions, forming a rectangle instead of squares, making it invaluable for sifting and sizing operations even when some deviation is accepted.
Stranded weave mesh uses small bundles of weft and warp wires in a dense square pattern for strength and compactness, essential for microfiltration applications.
An essential concept in wire mesh, mesh count signifies the number of openings in a linear inch. Measured by counting openings from wire center to wire center, it's expressed simply, such as 4x4 or 20x20, indicating openings per inch.
Wire mesh edges are either raw or selvage. Raw edges show exposed weft wires, while selvage edges have a finished border ensuring stability and safer handling. Looping at the perimeter accomplishes selvage edges, enhancing mesh durability.
The primary material for wire mesh is the wire itself, which can be made from a range of ferrous and non-ferrous metals. Wire used in mesh production comes in various gauges, with the gauge number indicating the wire's thickness. Lower gauge numbers correspond to thicker wires, while higher numbers indicate thinner wires.
For plain and crimped wire mesh, the gauge of the shute or weft wires matches the gauge of the warp wires. However, in Dutch woven wire mesh, the weft and warp wires have different gauges. Stranded wire mesh, on the other hand, consists of very fine wires twisted together into bundles.
In addition to gauge, the choice of metal affects the type and application of the wire mesh. Wire is manufactured by drawing raw metal through a die or draw plate. While most wire mesh uses cylindrical wires, other shapes such as square, hexagonal, and rectangular are also utilized.
Carbon plain steel is one of the more popular metal wires used to manufacture wire mesh. It is mainly iron with a small amount of carbon and is a low-cost, versatile metal used for window guards, screens, and separation screens for mining. Carbon steel can be zinc coated to make galvanized steel wire or powder coated with plastic.
Stainless steel wire mesh is renowned for its strength, durability, and attractive shiny finish, making it a popular choice for architectural applications. Various grades of stainless steel are used in its production, with grades 316 and 304 being the most widely utilized.
Aluminum is favored for its lightweight, flexibility, malleability, corrosion resistance, and affordability, making it the most popular non-ferrous metal for wire mesh production. Pure aluminum, such as grade 1000, is rarely used; instead, aluminum is typically alloyed with metals like copper, magnesium, zinc, or silicon to enhance its strength and other properties.
The most commonly used alloys for aluminum wire mesh are 1350, 5056, and 6061, each providing specific benefits for various applications.
| Percentage of Aluminum Wire Mesh Alloys | ||||||||||
|---|---|---|---|---|---|---|---|---|---|---|
| Alloy | Si | Fe | Cu | Mn | Mg | Cr | Zn | Ti | Ga | Aluminum |
| 1350 | 0.1 | 0.4 | 0.05 | 0.01 | ... | 0.01 | 0.05 | ... | 0.03 | 99.5 |
| 5052 | 0.25 | 0.4 | 0.1 | 0.1 | 2.2-2.8 | 0.15-0.35 | 0.1 | ... | ... | Remainder |
| 5056 | 0.3 | 0.4 | 0.1 | 0.1 | 2.2-2.8 | 0.15-0.35 | 0.1 | ... | ... | Remainder |
| 6061 | 0.40-0.8 | 0.7 | 0.15-0.40 | 0.15 | 0.8-1.2 | 0.04-0.35 | 0.25 | 0.15 | ... | Remainder |
Copper wire mesh is valued for its ductility, malleability, and excellent thermal and electrical conductivity. It is commonly employed in applications such as radio frequency interference shields in Faraday cages and various electrical uses. Unlike aluminum, copper is rarely used in its pure form and is typically alloyed to enhance its natural properties.
Copper undergoes color changes when exposed to salt, moisture, and sunlight, shifting from salmon-red to various shades of brown, gray, and eventually to blue-green or gray-green. To maintain its appearance and control the oxidation process, copper wire mesh is often treated with coatings and chemicals.
Brass, an alloy of copper and zinc, is used in wire mesh manufacturing and is known in the industry as 270 yellow brass or 260 high brass. 270 yellow brass comprises 65% copper and 35% zinc, while 260 high brass contains 70% copper and 30% zinc. The higher zinc content in brass wire mesh enhances its tensile strength, abrasion resistance, and produces a more hardened mesh.
Industrial-grade brass wire mesh typically has a yellow hue, making it a popular choice for decorative and artistic applications in architectural projects.
Bronze, an alloy of copper with 90% copper and 10% zinc, shares many of the properties of copper, such as malleability, ductility, and durability. However, bronze offers greater resistance to corrosion compared to brass and is harder and less malleable than pure copper. It is commonly used in industrial applications like filtering and also in various architectural applications.
The metals and alloys mentioned are among the most commonly used for manufacturing wire mesh. However, custom wire mesh can also be made from other metals such as titanium, Hastelloy, Monel 400, nichrome, Inconel, and tungsten. In essence, any ferrous or non-ferrous metal that can be drawn into wire can be utilized to produce wire mesh.
Wire mesh is highly versatile and can be tailored to meet a wide range of requirements, leading to its extensive use in various applications. In industrial settings, wire mesh serves as protective shielding, components of filtration and separation systems, and support for railings. It is a crucial element in filtration systems used in wastewater treatment facilities, petrochemical plants, and juice production processes.
Beyond industrial applications, wire mesh has been commercially utilized for many years. It provides protection against insects and is used in the construction of animal enclosures. Various forms of wire mesh are employed in products like screen doors, window screens, screen partitions, and decorative screens.
Industries that commonly rely on wire mesh include:
Wire mesh is used in both commercial and residential settings for various applications, including:
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