Durable Reinforced Expanded Metal Wire Mesh for Industrial Filtration High Efficiency

Reinforced expansion mesh is a type of non removable formwork mesh widely used in construction and other engineering fields. The following provides a detailed introduction from multiple aspects:
1, Basic Structure and Materials
Production process: It is a completely seamless expanded steel mesh made by cutting, expanding, and drawing steel strips with professional machines. Through special processes, the steel strip is stretched and deformed to form a unique mesh and reinforcement structure.
Material selection: commonly used pre galvanized strip steel, with a galvanized layer providing good corrosion resistance, suitable for damp, acidic and alkaline building environments; 304 stainless steel can also be used, with better corrosion resistance and oxidation resistance, suitable for coastal and other scenarios with extremely high weather resistance requirements, such as marine engineering related buildings.
2, Specification parameters (there may be differences among different manufacturers, the following are common examples)
Hole type: Diverse, such as 4.5 × 15mm, 5 × 10mm, 8 × 20mm, 10 × 16mm, etc. Different hole types are suitable for different construction requirements, such as small mesh holes that can be used in areas with high protection and precision requirements.
Plate thickness: 0.3-0.6mm. Thickness affects the strength and applicable scenarios of the mesh. Thin plates can be used as decorative plastering substrates, while thick plates are used for reinforcing load-bearing structures.
Reinforcement height and spacing: Reinforcement height is commonly 4mm and 8mm; The spacing between bars includes 75mm, 100mm, 150mm, etc. V-shaped reinforcing bars increase tension strength, and the combination of bar spacing and bar height affects the overall mechanical properties of the mesh. The higher the bar height and the denser the bar spacing, the higher the strength.
Size: Width generally 600mm, 610mm; Length 2000mm, 2440mm, etc., special sizes can also be customized according to engineering requirements.
3, Performance characteristics
High strength and stability: The V-shaped reinforcement structure greatly enhances the tensile strength, and the longitudinal reinforcement allows for more uniform application of large areas of deep coatings (such as plaster layers). When used as a building base, it can enhance the tensile and crack resistance of structures such as walls and ceilings, and reduce the occurrence of cracks. For example, for residential light partition walls, it can make the walls more stable and less prone to cracking due to external impacts.
Construction convenience: lightweight, easy to handle and install, can be quickly nailed to the keel light steel structure; Easy to cut, convenient for flexible adjustment according to the size of the construction site, and also conducive to the installation and laying of water and electricity pipes; As a non dismantling template, it does not need to be dismantled after pouring concrete, saving process and labor costs and accelerating construction progress. In the construction of building floor slabs, replacing traditional templates and reducing the need for demolition and cleaning.
Economy: Compared to some traditional template materials, although the initial procurement cost may be slightly higher, it has a high cost-effectiveness in the long run due to its convenient construction and cost savings in later maintenance (reducing crack repair, etc.); And it can reduce the use of template support materials, further reducing costs.
Functional advantages: Mesh design facilitates drainage and exhaust, allowing internal air and excess moisture to be expelled during concrete pouring, thereby improving the compactness of the concrete; It can also prevent mold bursting, keep the construction site clean, and improve the quality of the construction environment; It is well combined with concrete and does not require additional roughening to provide an effective bonding surface, ensuring the overall integrity of the structure.
4, Application Fields
Indoor and outdoor structures of buildings:
Light partition and firewall: used for light partition walls in high and low rise residential buildings, factories, etc., to create firewalls that separate spaces while enhancing wall strength and fire resistance.
Mid floor slabs and partition walls: As reinforcement and formwork materials for floor slabs and partition walls, they enhance the structural load-bearing capacity and stability, making the spatial layout of the building more flexible.
Permanent factory interior and exterior walls and enclosures: Enhance the structural strength of the factory and enclosure walls, resist external loads and environmental erosion, and extend the service life of the building.
Basement moisture-proof composite wall: In the damp environment of the basement, with the advantages of corrosion resistance and structure, a moisture-proof and sturdy composite wall structure is constructed to prevent water seepage and wall damage.
Special building construction:
Structural joint: used at construction joints in building structures to enhance the strength of joint connections and prevent cracking and deformation caused by stress concentration.
Tunnel, sewer, and enclosure engineering: used as structural reinforcement materials in tunnel lining, sewer walls, and enclosure construction to enhance the overall strength and stability of the project, and to cope with complex underground stress, water flow erosion, and other situations.
Raft foundation, dock, and retaining wall: provide reinforcement for these load-bearing and anti lateral pressure structures. The raft foundation strengthens the connection between the foundation and the upper structure, while the dock and retaining wall enhance their load-bearing and anti erosion capabilities.
Flat and arched flooring: used for the construction of flat and arched flooring, as templates and reinforcements, to make the floor structure more stable and adapt to the needs of different building spaces (such as large spaces in factories and curved structures in venues).
Arc shaped structures such as nuclear power plants and storage tanks: adapted to special arc shapes, providing structural support and reinforcement, meeting the strict requirements for building structural safety and stability in special fields such as nuclear energy and chemical engineering.
Special projects such as landscape sculptures: With customizable shapes and strength advantages, they are used to support the internal structure of landscape sculptures, making artistic forms both beautiful and sturdy.
Slope protection, soil embankment and other projects: Strengthen slope protection, soil embankment, prevent soil landslide and collapse, improve slope stability, and protect the safety of water, soil and surrounding facilities.
Pre stressing and reinforcement repair engineering:
Pre embedded prestressed components: In concrete prestressed components, as pre embedded reinforcement, it provides prestress, enhances the bending and tensile bearing capacity of the component, and makes the component less prone to cracking and deformation under load.
Reinforcement and repair of prestressed concrete slabs: For prestressed concrete slabs with cracks or detachment in existing buildings, additional support and restraint are provided by connecting them with reinforced expansion nets to restore and enhance the bearing capacity of the slabs and extend their service life.
Bridges, tunnels, and underground engineering: used for beam and slab reinforcement and pre embedded prestressed components in bridges; In tunnels and underground engineering, it is used to reinforce tunnel segments, connect prestressed components, and enhance the strength, seismic resistance, and durability of large-span and high load structures.
Ocean engineering: used for reinforcing and supporting concrete structures such as seawalls, seaports, and underwater tunnels. With high strength and corrosion resistance, it enhances wind resistance, wave resistance, and corrosion resistance. It can also optimize structural stability and bearing capacity by adjusting prestress.