Expanded Metal: Types, Applications and Advantages

Chapter 1: What is Expanded Metal?

Expanded metal is a type of sheet metal mesh created by stretching a sheet of malleable metal that has been slitted. The slits are oriented perpendicular to the stretching direction, resulting in a mesh with an array of holes formed by the slitted sections.

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Expanded metal is based on the principle that metals expand and contract under different conditions. This behavior is influenced by the metal's atomic structure and chemical properties, which results in the creation of expanded metal.

Expanded metal differs from and competes with these alternatives:

Perforated Sheet

Perforation is the punching of holes, in this case, into a metal sheet. The result of such perforation is a (metal) perforated sheet. In many cases, sheets that can be perforated can also be expanded. Perforation is a subtractive process ' the punching of holes implies the removal of material. This comes as a disadvantage as the removed material is regarded as wastage. Perforation does not subject the perforated metal sheet to stretching, at least not necessarily. One of its advantages is the feasibility of very small openings and drainage casings for various applications. It can also have shapes that are not feasible with other meshing techniques ' this comes in handy if the mesh is intended for decorative purposes.

Perforated metal sheets are commonly used in the enclosures of computer equipment.

Woven Mesh

During this meshing technique, metal wires are intertwined in a manner similar to threads in fabric. The weaving is maintained through friction and the wire's rigidity, with no actual bonding between the separate wires. If not secured, the edges can unravel. Screens used for sand sieving are commonly woven in this way.

Welded Mesh

A grid of parallel wires is laid over another grid, with each set of wires oriented at a right angle to the other. Welded connections are made at each intersection of the wires. This type of mesh is often utilized for covering large areas. Meshes with finer spacing are more challenging to produce due to the high density of welds needed for each unit of area.

Welded mesh is frequently employed for reinforcing concrete structures.

Chapter 2: What are the different material types of expanded metal?

In principle, all metals that are malleable can be stretched or expanded. Nevertheless, not all of these metals are practical for large-scale industrial expansion. The following section will cover some of these materials.

Copper Expanded Metal

Historically, copper isn't typically the primary choice for structural applications, particularly when only structural factors are considered. Additionally, copper is relatively expensive, especially when assessed per unit volume. Volume is crucial as it affects the final size of the expanded metal sheet. The high density of copper is a disadvantage in applications where weight is a critical factor, such as in rigging.

Copper becomes relevant when factors beyond just structural concerns are important. These considerations include:

• Corrosion resistance ' essential when the intended application exposes the expanded metal sheet to moisture or other reactive environments.
• Electrical conductivity ' copper is a better electrical conductor than most metals that are available on an industrial scale.
• Appearance ' where the mesh is intended for decorative purposes, copper can be a good choice.
• Malleability ' the malleability of copper makes it easier to cut and stretch, often into more complex shapes.

Expanded Aluminium

Aluminum has a wide range of structural applications due to its strength and lightweight nature. It is an effective conductor, which is why it's often used in overhead power lines.

Aluminum's malleability makes it easier to work with than steel (when cold), and its resistance to corrosion adds to its advantages. With a high melting point and excellent thermal reflectivity, aluminum is well-suited for high-temperature environments.

Expanded Steel

Steel is the most widely used structural metal, known for its exceptional strength compared to other metals listed here, provided it remains free from corrosion. Steel comes in various types:

Expanded Mild Steel

This provides a robust and economical solution. It is commonly coated with molten zinc through a hot-dipping process for galvanization.

Grating Metal Sheet

This expanded metal sheet is made from higher gauge metal sheets, typically crafted from mild steel.

Stainless Steel Expanded Metal

Stainless steel offers greater resistance to corrosion compared to mild steel and is more effective in high-temperature environments.

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Chapter 3:What is the manufacturing process of expanded metal?

The production of expanded metal encompasses several stages. These stages will be outlined in the following sections.

Sheet Metal Selection

The initial step involves selecting the appropriate sheet metal. This choice is determined by the specific application for which the expanded metal will be used.

When selecting the metal, the following properties are taken into account:

• Rigidity
• Corrosion resistance
• Strength
• Appearance
• Specific weight
• Toughness
• Flexibility
• Elasticity

In addition to the metal's chemical and structural properties, the dimensions are also a crucial consideration.

Dimensions of Metal Sheet

The aspects considered to be dimensions of the metal sheet are:

• The total area covered by the metal sheet before expansion
• The thickness of the metal sheet before expansion
• The flatness and squaring
• Size of each cut, hence the size of each hole
• Mesh dimensions
  
• For diamond meshes, the following is usually considered:
  • Long way of diamond ' the larger diagonal. The long way of diamond is the dimension along which rows are defined.
  • Short way of diamond ' the shorter diagonal. The short way of diamond is the dimension along which the die moves when stretching a piece of metal.
  • The long way of diamond and the short way of diamond become equal when a square mesh is being produced.
  • Long way of opening ' the larger diagonal of the opening
  • Short way of opening ' the smaller diagonal of the opening
• Extent of flattening (if any), and leveling
• Total area covered by the sheet after expansion
• Thickness of the sheet after expansion
• Distance between the cuts hence the thickness of the strands. This is controlled by controlling the speed of the feed during the cutting and stretching process during expansion.
• Before expansion, the metal sheet is cut to size. The cutting is often done with an automatic guillotine. The desired pattern determines the size of the expanded metal sheet.

Cutting and Stretching Metal

The cutting process creates the openings in the expanded metal, setting the final dimensions of these openings. This can either be done in two separate steps'cutting and stretching'or in a single combined operation, which is more frequently used.

A die is employed to define half of a row across the full width of the sheet. The metal sheet is aligned with the inner edge of the die, which also aligns with the supporting platform. The sheet is then fed under the die at a rate corresponding to the desired strand thickness. The die descends to cut and stretch the sheet in one motion (creating the first half row), and then it retracts.

If the expanded sheet metal requires uniformly sized and shaped openings, a single die will be used for the entire process. In this case:

• The die moves sideways the distance equal to the maximum dimension of each shape along that axis.
• The sheet is fed again.
• The die comes back down, cutting and stretching the second half of the first row, simultaneously cutting the first half of the second row.
• The next cut and stretch complete the second row, simultaneously cutting the first half of the third row, and so on.

When different sizes or shapes are required, two distinct but complementary dies are used. These dies alternate in operation to form the various shapes.

This method of cutting and feeding results in an expanded metal sheet with a textured, raised surface, often referred to as standard expanded metal.

During the expansion process, coolants and lubricants used by the presses often remain on the surface of the expanded metal. These residues may be left in place, particularly if no further finishing is planned after expansion (and flattening). Interestingly, these substances can sometimes help the metal resist corrosion.

However, if additional finishing or appearance considerations are important, these chemicals can be problematic. In such cases, they can be removed, typically through chemical methods like using detergents.

Shapes of Openings

Diamond shape ' This is the most commonly used pattern for expanded metal sheets.

Hexagonal shape ' Another frequent pattern, achieved by extending the diamond shape's bond along a plane perpendicular to the feed direction. Compared to the diamond shape, creating hexagonal patterns is more challenging due to the bond shearing involved.

Square shape ' This is a variation of the diamond pattern where the diagonals are of equal length.

Louvered ' The metal is pressed to create a louvered appearance. This pattern typically results in minimal expansion, meaning there is a smaller increase in the overall dimensions of the metal sheet.

Decorative ' Custom shapes can be designed to meet specific aesthetic and architectural needs.

Strand Thickness

The thickness of the strands affects the overall percentage of open areas in an expanded metal sheet for any given die shape and opening size. It also influences the ratio of the total area of the expanded sheet to that of the original solid sheet from which it was produced.

Strand thickness is influenced by the feed rate during the stretching process. A higher feed rate results in expanded metal sheets with a lower percentage of open space.

It is possible to have varying strand thicknesses within a single sheet by adjusting the feed rate as needed during production.

Flattening Process

This process results in a flat surface finish on the expanded metal when such a finish is desired. Typically, the cutting and stretching processes leave the metal with a ridged or rippled texture, often referred to as a raised surface. While a raised finish may be preferable in some applications, it is not always desirable. In cases where a smooth finish is needed, flattening is applied.

Expanded metal that has not been flattened is commonly known as standard expanded metal, as it emerges directly from the expanding machine. Flattening is accomplished through cold rolling, which compresses the metal to make it thinner and more even. As the metal is cold rolled, it becomes thinner and elongates in the direction of movement through the rollers.

The lengthening of the expanded metal sheet results in the stretching of the openings in the same direction. Consequently, the openings may appear elongated or wider compared to those in the standard expanded metal sheet.

Metal Leveling

This process should not be confused with flattening. Flattening removes the ridged texture from the surface of the expanded metal, while leveling ensures that the sheet lies flat on a level surface. Flattening addresses the surface texture, whereas leveling concerns the overall flatness of the sheet. Leveling pertains to the sheet's three-dimensional geometry and measures how well different points align within the same plane.

An expanded metal sheet is considered level when it is free from waves and buckles. Since completely eliminating these imperfections is difficult, acceptable tolerances are established to define what is considered acceptable.

Chapter 4: How are surface finishing and shearing applied to expanded metal?

This chapter will cover the topics of surface finishing and shearing for expanded metal.

Surface Finishing of Expanded Metal

In many cases, expanded metal sheets are utilized directly as they come from the roller or stretching machine, with no further modifications.

However, for certain applications, additional surface finishing is necessary. These include:

Finishing Through Painting

Painting is often the most economical method for finishing expanded metal sheets. Paint can be used for aesthetic purposes or to provide corrosion protection. However, for effective corrosion resistance, the paint must be fully intact; any small gaps can allow corrosion to develop underneath the coating. Of the coatings mentioned, painting is the least expensive, offers the least corrosion protection, and requires the most frequent maintenance.

Powder Coating

This method often provides results similar to painting, but uses plastic instead. It tends to be more durable than painting. Typically, a spray gun is used to apply the plastic powder, which is often electrostatically charged. The coated sheet is then heated to bond the plastic with the metal surface.

Galvanizing Process

In the galvanizing process, the expanded metal sheet is immersed in molten zinc, which forms a protective zinc coating. This coating helps safeguard the mesh from corrosion. However, due to the high temperatures involved, this method has limitations on the dimensions of the expanded metal that can be galvanized. Very fine meshes are generally not suitable for galvanizing due to these constraints.

Anodizing Process

Anodizing is an electroplating technique where the expanded metal sheet is coated while being electrically charged. This process provides a more granular coating compared to other methods and ensures a stronger bond with the metal. Despite its effectiveness, anodizing is relatively expensive, both in terms of the plating material and the process itself. Its higher cost is a primary reason for its less frequent use.

Anodizing is usually common with iron-based metals (which are prone to corrosion). This process circumvents some of the dimension limits that arise from the galvanizing process since it can be carried out at much lower temperatures.

Shearing of Expanded Metal

Shearing is the process used to cut expanded metal sheets to size. It involves trimming a larger sheet into smaller sections or altering its shape. Shearing is performed with shears, which are metal blades or mechanisms that operate similarly to scissors. Shears can be either manual or mechanized. When the blades come together on the expanded metal, they apply sufficient shear force to cut through the material.

Various types of shearing methods exist, which will be discussed in the following sections:

Side Shearing

This involves shearing along the longer axis of the diamond pattern.

Bond Shearing

Bond shearing cuts the sheet precisely along the edge, resulting in closed shapes only on either side of the cut. This method aligns with the shapes of the pattern.

For raised expanded metal, bond shearing should be performed along the bonds between the rows.

Random Shearing

Random shearing does not follow the shape edges, resulting in open shapes and irregular patterns at the edges. This method can leave sharp, spiked strands. To improve handling, expanded metal that has been randomly sheared should be U-edged or framed as an alternative.

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U-edging involves applying a U-shaped metal strip to cover the edges of an expanded metal sheet.

Centerline Shearing

This involves shearing with a line of symmetry on the expanded metal sheet.

Balance Shearing

This technique creates a matching section, ensuring the mesh pattern appears continuous.

End Shearing

This method shears along the shorter axis of the diamond shape.

Random Shearing

This involves cutting across strands at locations other than the bonds.

Expanded Metal Meshes

Among expanded metal shapes, the diamond (hexagonal) pattern is the most common. Typically, the same shape and size of openings are used consistently throughout a sheet. The diamond shape features four-sided openings with strands meeting at the corners.

As the difference between the diagonals of the diamond shape decreases, it begins to approximate a square (geometrically, a square is a special type of diamond where the diagonals are equal). In such instances, the mesh is referred to as a square mesh.

The hexagon does not need to be regular, but the side length determines the dimensions and strength of the bonds.

Chapter 5: What factors determine the quality of expanded metal?

Tolerances for expanded metals need to be adhered to for:

• Sheet thickness
• Strand width
• Dimensions of openings
• Coating thickness

Typically, expanded metal should be free from:

• Burrs
• Broken strands
• Laminations
• Welded strands
• Slivers

Tolerances in Expanded Metal

Expanded metal can be produced with different tolerances, which will be described below.

Camper Curve

This refers to the bow or curve in the sheet. It may not matter if the expanded metal sheets are to be rolled for packaging, but it can be problematic for applications needing a flatter material. This is particularly true for materials requiring higher rigidity, which could result in residual stresses in the structure.

Producing expanded sheet metal with no camper is quite rare. Therefore, tolerances are established for specific applications. If the camper falls outside the required tolerance, corrective measures are necessary; otherwise, the material can be used effectively.

The curve typically forms along the edge in the direction of the feed during the cutting and stretching phase of the expanding process. Flattening, which often involves rolling, also addresses campers by removing or reducing them, along with waves and buckles, resulting in a more even product.

Squareness Property

This refers to the property of having a rectangular or square shape, characterized by 90° angles and straight edges. In such geometry, the diagonals are equal.

Squareness is a planar characteristic, applicable to a single plane'the view from above when the sheet is laid flat. An expanded sheet can be square without meeting all other spatial and geometric requirements, such as being level. Conversely, issues like camper and buckles can affect the squareness of an expanded metal sheet.

Deviations from squareness often stem from the initial metal sheet, which is rarely perfectly square despite tight production tolerances, or from defects in the die used.

If the application permits, re-squaring can be achieved by random shearing the expanded metal sheet along specific lines. Border shearing generally does not correct squareness, and stretching the shorter diagonal often results in non-straight edges.

Parallel Sides

This feature is often crucial, especially when the expanded metal sheet has parallel opposite sides. Sheets that are perfectly square will always have parallel sides, but sheets with parallel sides are not always square (e.g., a parallelogram). Additionally, sheets without parallel sides can never be square. Deviations from parallelism may be caused by factors such as camper.

In certain applications, expanded metal may be intentionally made with non-parallel sides. For example, a die with varying "tooth" sizes across the sheet's width can create this effect from a square solid sheet. However, such applications are quite rare.

Taper Sides

This refers to the deviation from having parallel sides, which becomes particularly noticeable when it is undesirable. A sheet with tapered sides cannot be considered square.

Expanded Metal Customization

Often, expanded metal sheets require additional processing after they come out of the expanding machine. This may include cutting, bending, welding, bracing, and other modifications. Customization work is not usually part of the standard production process due to the unique requirements of each project. Additionally, some applications may need different gauges of expanded metal to work together effectively.

Customization involves modifications performed on the expanded metal sheet, typically based on specific customer requirements. These tasks may include:

• Shearing to fit specific dimensions
• Shearing to fit specific frame shapes
• Shearing to produce a tear or cut without removing any material or isolating any pieces of the original expanded sheet metal
• Bending the sheets
• Joining sheets together
• Rolling to specific curvatures, including affecting various curvatures on the same sheet

Chapter 6: What are the applications and advantages of expanded metal?

This chapter will explore the uses and benefits of expanded metal.

Applications of Expanded Metal

Expanded metal is versatile and used in various applications, including:

Metal Platforms

Platforms designed for use at significant heights often incorporate expanded metal mesh to take advantage of its lightweight nature. Common applications include rigging in industries such as transportation, oil, telecommunications, and more.

Machine Guards

Expanded metal can cover rotating shafts and machinery parts. It is lighter than solid guards but equally effective in safeguarding machine operators.

Drainage and Ventilation

Expanded metal is used in structures to facilitate drainage and ventilation. It is commonly placed over drainage trenches along roadsides, walkways, factory floors, and similar areas.

Protective Screens

Expanded metal mesh serves as protective screens for building and vehicle windows, including cash-in-transit vehicles.

Walkway Applications

Some bridges and suspended walkways use expanded metal for pedestrian areas to reduce the weight of the deck while maintaining structural integrity.

Use in Barriers

Expanded metal mesh is ideal for creating barriers where light, air, and sometimes water need to pass through. Such barriers are used in aquariums, buildings, tunnels, and other structures.

Fence Applications

Expanded metal is used for protective fences, yard demarcation, animal cages, and other enclosures.

Gabion Walls

Expanded metal is suitable for making gabion walls, especially when finer aggregates are used, offering an alternative to welded mesh.

Equipment Ventilation

Expanded metal mesh can be utilized as a covering for equipment, offering a suitable solution when neither a solid sheet nor an uncovered area is appropriate.

Examples of equipment that might use expanded metal in their coverings include generators, tractor engines, earth-moving machinery engines, and both air and water pumps.

Uses for Decoration

In architectural applications, expanded metal mesh is used in gardens, building openings, walls, roofs, guard rails, and demarcation walls. Fine meshes are also used in jewelry making.

Metal Mesh Trays

Expanded metal mesh can be fashioned into trays used in agriculture, such as for harvesting and transporting green tea from fields.

Recreational Uses

Some recreational parks use expanded mesh on steep cliffs to provide thrill and entertainment.

Advantages of Expanded Metal

While expanded metal has some drawbacks, such as increased surface area that can lead to corrosion and chemical damage, its benefits often outweigh these issues. Some advantages of expanded metal include:

• Relatively lighter, compared to a solid sheet of the same outer dimensions and the same material
• Decorative
• Allows light and ventilation
• Amount of light can be varied by varying strand thickness
• It yields up to three times the original solid sheet metal size
• It has no material wastage
• Does not require joining any material ' it is built from a single sheet of metal
• Easy to cut (shear) as compared to the solid metal sheets
• It can be recycled
• Allows drainage and fluid flow

Conclusion

It can be reasonably inferred that the need for expanded metal products will persist into the distant future. The combination of (relatively) light weight, high strength, and moderate cost will continue to place a distinct attractiveness on expanded metal products. The general trends of structural and industrial development also seem to agree ' amongst other things, the requirement for civil structures to become increasingly taller will persist, with it the need for platforms, barriers and ornamentation.

Copper mesh is also known as copper screen or copper wire mesh. The copper mesh is a square weave mesh that it woven by a copper wires which has great electrical and thermal conductivity. The copper is a malleable and soft material. A copper mesh is widely used as electromagnets interference. It can also be used as a shield for radio frequency interferences.  It is also used as a window screen or in different industries as filtration and separation.

Copper mesh are known to have long service lives and as a sign of wealth and prestige. It is for these features that they are usually used as decorative house facades in construction. They are also used as reliable and durable plastering reinforcement material for ceilings and walls.

Expanded Copper Mesh

Classification

Copper meshes can be further classified into medium, fine and coarse wire mesh. This is of course depending on the wire specification. The medium copper mesh includes the meshes that are in the range of 12 x 12 meshes up to 40 x 40 meshes. The fine meshes include the 50 x 50 mesh, 60 x 60, 80 x 80 and 100 x 100 mesh. The coarse mesh on the other hand include 2 x 2 mesh, 4 x 4, 6 x 6, 8 x8 and 10 x 10 mesh.

Copper mesh can also be subdivided into three types depending on the materials that it is made up namely the purpose copper mesh, brass wire mesh and the phosphor copper mesh.

Purple copper mesh.

The material used is purple copper wire which is 99.8 percent pure copper. This mesh is non-magnetic and is able to bear the pressure in grinding. It is widely used during filtration of electron beam as well as in electron display screen.

Brass wire cloth or brass wire mesh.

Material used is brass. There are different proportions and one of these is the 65 brass. For this material, it has 65 percent while the zinc is 35 percent. Another brass is the 80 brass material which contains 80 percent of brass proportion with the zinc only 20 percent. The brass wire cloth is non-magnetic, has good ductility and is wear resistant. It can be used as porcelain glass and clay, filtering gas and liquid, powder, and is also used to screen different granules.

Phosphor mesh.

This is also the alias used for tin bronze mesh. The material that makes up the phosphor mesh is phosphor copper wire. The proportion is 85 to 90 percent copper and the tin is about 5 to 15 percent. The phosphor mesh is non-magnetic; it is able to bear the grind alkali and ache and is also ductile.

Mesh sizes and shape

There are different mesh sizes. The usual wire diameter is in the range between .3mm to 1.2mm. The preferred diameter for the wire mesh by most consumers is .6mm. The opening size of the mesh on the other hand is usually in between 4mm to 6mm. The mesh is shaped into square and the copper bare mesh has the spacing of 300 x 300mm.

Advantages of copper mesh

Tensile endurance

Considering that copper is strong in addition to being versatile, it increases the reliability of the overall system even under unfavorable conditions.

Non-reaction with water

Copper does not react with water, but can react with oxygen in the atmosphere and also forms a dark brown layer of copper oxide. In contrast to the oxidation of iron by moist air, this formed layer of copper oxide prevents further deterioration.

Adaptability

Copper wire mesh is flexible and easy to install and handle. It can be quickly attached by welding, brazing or soft soldering. Its versatility means it can be used to adapt to different style configurations.

Durable and maintenance-free

Copper cable mesh is durable and requires very low maintenance, making it the preferred choice for many mechanical and industrial systems. It does not require any type of finish to prevent corrosion.

Biostatic

Bacteria will never expand on the copper grid.

Sustainability

Copper is recyclable and does not lose its high quality, whether you use it in its original state or in manufactured products. By comparison, copper is one of the most recyclable metals after lightweight aluminum and iron.

Safety and security.

It does not melt or burn continuously. Copper cable mesh does not carry fire, especially through walls, ceilings and floors. It also does not decay directly into toxic gases.

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