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foshan nanhai ruixin glass co., ltd
About Us
Your Professional & Reliable Partner.
Foshan Nanhai Ruixin Glass Co., Ltd was founded in 2013, located in Foshan. More than 10 years experiences in tempered glass , We provide good Quality products & Service. We have these International certifications: CCC ,CE, SGCC and SAI.We have 5 branch factories , all with different products:One of which produces bathroom glass, one produces mirror, one produces mass products, one produces decorative art glass , and one produces oversized building glass.Our factory introduces advanced ...
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Year Established:

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Million+
Employees

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Million+
customers served

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Million+
Annual Sales:
China foshan nanhai ruixin glass co., ltd High quality
Trust Seal, Credit Check, RoSH and Supplier Capability Assessment. company has strictly quality control system and professional test lab.
China foshan nanhai ruixin glass co., ltd DEVELOPMENT
Internal professional design team and advanced machinery workshop. We can cooperate to develop the products you need.
China foshan nanhai ruixin glass co., ltd MANUFACTURING
Advanced automatic machines, strictly process control system. We can manufacture all the Electrical terminals beyond your demand.
China foshan nanhai ruixin glass co., ltd 100% SERVICE
Bulk and customized small packaging, FOB, CIF, DDU and DDP. Let us help you find the best solution for all your concerns.

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Comparison Between Double-Glazed and Triple-Glazed Glass: Balancing Performance and Cost
1. Thermal Insulation Performance   Double-Glazed Glass: Features a hollow space between two glass panes, reducing heat transfer effectively. Suitable for most buildings with moderate energy-saving needs, especially in temperate climates.​   ​​Triple-Glazed Glass: Offers an additional pane and hollow space, significantly enhancing insulation. Ideal for cold regions or buildings with strict energy efficiency requirements.   2. Soundproofing Performance   Double-Glazed Glass: Reduces high-frequency noise effectively, suitable for regular residential and commercial environments.   Triple-Glazed Glass: The extra pane and hollow space provide superior soundproofing, especially effective in reducing both high- and low-frequency noise, making it suitable for noisy areas near airports or highways.       3. Weight and Structural Requirements   Double-Glazed Glass: Lightweight and easier to install, with lower requirements for frame strength and structural design.   Triple-Glazed Glass: Heavier due to the additional pane, requiring frames with higher load-bearing capacity and robust installation processes.   4. Cost and Benefits   Double-Glazed Glass: Lower manufacturing and installation costs, making it an economical choice for projects with limited budgets.   Triple-Glazed Glass: Higher initial cost but delivers long-term savings through reduced energy consumption, ideal for sustainable building projects.     5. Application Scenarios   Double-Glazed Glass: Recommended for temperate climates and standard buildings with moderate energy-saving requirements.   Triple-Glazed Glass: Suited for cold climates, noisy environments, or green buildings, particularly for high-performance architectural projects.

2025

12/30

Discern with Wisdom: Easily Identify the Quality of Architectural Glass
In the field of architecture, the quality of glass plays a crucial role in the overall quality, safety, and service life of a building. Faced with a wide variety of glass products in the market, it is essential to learn how to distinguish their quality. The following are some simple and easy methods for identifying the quality of architectural glass.     I. Visual Inspection   Place the architectural glass in a brightly and evenly lit area. The surface of high-quality glass is flat and smooth, without any undulations or irregularities. When touched by hand, no obvious protrusions or depressions can be felt. This is because advanced manufacturing processes during production precisely control the melting and forming of raw materials, ensuring a high level of surface flatness of the glass.     Carefully examine the glass surface for bubbles, scratches, and impurities. Even a tiny bubble may damage the strength of the glass. Under the influence of temperature changes and external forces, stress concentration around the bubble may lead to breakage. Scratches will disrupt the stress balance on the glass surface, reducing its compressive and impact resistance. Impurities will cause local weaknesses in the glass when under force, increasing the risk of breakage.       II. Dimensional Accuracy and Edge Cutting   The dimensions of architectural glass must strictly meet the design requirements, and the errors in length, width, and thickness should be controlled within a very small range. In building construction, especially in large glass curtain wall projects, the dimensional accuracy of the glass affects the installation efficiency and quality.   If the glass is too large, it may not fit into the frame smoothly, and forced installation will cause uneven stress on the glass and lead to breakage; if it is too small, gaps will be left, affecting the airtightness, watertightness, and thermal insulation performance of the building.     Inspecting the edge cutting of the glass is also extremely important. The edges of high-quality glass should be smooth and neat, without burrs or notches. Rough edges can easily cause injuries during handling and installation and may also damage window frames or other adjacent materials, affecting the stability and sealing of the building structure.   III. Identification of Safety Glass   (A) Tempered Glass Tempered glass must have a 3C certification mark, which is an important proof of its quality compliance. When purchasing, pay attention to the corners or edges of the glass and check whether the 3C mark is clear, complete, and not easily erasable. If there is a problem with the mark, the quality of the glass is questionable.   If possible, observe the state of the tempered glass after breakage. It will be found that it is in the form of small obtuse-angled particles. This is due to the change in the internal stress structure of the glass caused by the tempering process. Compared with the sharp fragments of ordinary glass after breakage, the risk of serious scratches to the human body is greatly reduced.     (B) Laminated Glass The key to inspecting laminated glass lies in its internal interlayer. Place the glass in a well-lit area and check whether the interlayer is uniform. The interlayer of high-quality laminated glass should be flat and uniform, without obvious thickness differences or bubbles. Bubbles in the interlayer will reduce the adhesion, and the interlayer is prone to separation when subjected to external impact, affecting the safety of the glass.   At the same time, check whether there is delamination in the interlayer. Gently press the edge of the glass. If there is displacement or separation between the interlayer and the glass, it indicates that the laminated glass may have quality defects.

2024

12/12

How Low-E Glass Reduces Building Energy Consumption
Low-emissivity (Low-E) glass is a high-performance glass with specialized coatings that control solar radiation and heat transfer. It optimizes energy efficiency in buildings by reducing heating and cooling demands. The following explains the logic behind its energy-saving benefits:   1. Selective Transmission and Reflection Principles Core Technology: Low-E glass is coated with one or multiple layers of metal or metal oxide (e.g., silver, tin oxide), which exhibit selective properties for different wavelengths of light.   Mechanism:   Allows most visible light to pass through, ensuring natural illumination.   Reflects infrared radiation (the main carrier of heat) back to its source, minimizing heat transfer.   Blocks ultraviolet (UV) radiation, reducing fading of interior furnishings and materials.     2. Reduced Heating Energy in Winter   Retaining Indoor Heat: In cold climates, Low-E glass reflects far-infrared radiation (heat) generated indoors back inside, preventing it from escaping.   Enhanced Indoor Comfort: By reducing heat loss, Low-E glass stabilizes indoor temperatures, lowering heating system energy consumption.     3. Lower Cooling Energy in Summer   Blocking Solar Heat: During summer, Low-E coatings reflect infrared radiation from the sun, reducing heat gain inside the building and decreasing air conditioning demand.   Mitigating Urban Heat Island Effects: By reducing heat absorption in densely built urban areas, Low-E glass can indirectly improve outdoor environmental conditions.       4. Enhanced Thermal Efficiency of Buildings   Lower U-Value (Thermal Transmittance): Low-E glass minimizes heat transfer, resulting in a lower U-value, which measures energy efficiency in building materials.   Superior Insulation Performance: Compared to regular glass, Low-E glass provides better insulation, contributing to the overall thermal performance of the building envelope.     Quantified Energy-Saving Effects   Winter Energy Savings: Low-E glass can reduce heating energy consumption by 20%-30%.   Summer Energy Savings: Air conditioning energy use can decrease by 15%-25%.   Overall Savings: On average, Low-E glass lowers annual building energy usage by around 20%, depending on the climate.     Summary: The Core Logic of Energy Reduction   Low-E glass minimizes energy consumption by managing heat radiation, optimizing heat transfer pathways, and improving the thermal efficiency of buildings. By easing the burden on HVAC systems, it enhances indoor comfort while lowering operational costs. As an integral component of sustainable building design, Low-E glass supports energy-efficient and environmentally friendly construction practices.

2024

12/09