Explosion Proof Distribution Box

An explosion-proof distribution box is a complete distribution unit designed to house switches, instruments and other equipment in a centralised manner, preventing explosions at the installation site caused by sparks, arcs or high temperatures. Currently, this unit has become an indispensable distribution facility in flammable and explosive environments such as the petrochemical industry.
Based on their explosion-proof design, explosion-proof electrical equipment is primarily classified into flameproof, increased safety, intrinsically safe and positive pressure types. The structure primarily consists of the enclosure and cover, busbar box and cable outlet box, switch knobs, mounting slots, high-breaking-capacity miniature circuit breakers and drive shafts. As explosion-proof distribution boxes are used in harsh environments—particularly those installed outdoors, which are exposed to the elements year-round—the enclosure is typically made of cast aluminium alloy.
The working principle of positive pressure explosion-proof technology in explosion-proof distribution boxes: A distribution box that may possess ignition energy or lacks explosion-proof certification is placed within a positive pressure chamber. A positive pressure ventilation system then fills the chamber with a protective gas, whilst a differential pressure detection system continuously monitors the internal pressure of the distribution box. This ensures that the internal pressure remains higher than the surrounding atmosphere at all times, preventing explosive mixtures from entering the enclosure. Consequently, ignition sources within the distribution box are isolated from flammable gases in the surrounding environment, thereby achieving overall explosion protection for the distribution box.
In the future, explosion-proof distribution boxes will evolve towards greater intelligence, energy efficiency, safety and connectivity. Firstly, the equipment will integrate intelligent control systems, utilising the Internet of Things (IoT), big data and artificial intelligence to enable remote monitoring, fault prediction and automatic handling, thereby enhancing efficiency and safety. Secondly, technology will place greater emphasis on energy efficiency management, utilising energy-saving materials, LED lighting and intelligent dimming to reduce energy consumption and meet green manufacturing requirements.
At the same time, safety performance will continue to improve, with enhanced resistance to electromagnetic interference, fire resistance ratings and environmental adaptability to meet the demands of high-risk industries. Finally, with the development of cloud computing and 5G, explosion-proof distribution boxes will integrate more effectively into the Industrial Internet, enabling efficient coordination between devices and remote operation and maintenance.
Main Categories of Explosion Proof Distribution Boxes
Explosion-proof distribution boxes are categorised as follows: explosion-proof lighting boxes, explosion-proof power distribution boxes, explosion-proof control boxes, explosion-proof control cabinets, explosion-proof distribution cabinets, explosion-proof operating boxes, explosion-proof enclosures, explosion-proof starter boxes, explosion-proof motor starters, explosion-proof soft starters, explosion-proof variable frequency drives, explosion-proof star-delta starter boxes, explosion-proof autotransformer step-down starter boxes, explosion-proof magnetic starters, explosion-proof power socket boxes, portable explosion-proof enclosures, and BMG explosion-proof distribution boxes, amongst others.
Design Standards and Technical Specifications for Explosion Proof Distribution Boxes
Material Selection Standards
As critical electrical equipment for use in special environments, the choice of materials for explosion-proof distribution boxes directly affects the safety and service life of the equipment. For the enclosure and internal components, priority should be given to metal materials with corrosion-resistant and high-temperature-resistant properties; 304 stainless steel or 6061 aluminium alloy are recommended. These two materials not only meet mechanical strength requirements but also exhibit significantly superior oxidation resistance compared to ordinary carbon steel. Specialised explosion-proof cable glands must be fitted at cable entry and exit points. These components should be made of polyurethane composite or fluororubber to ensure elasticity and sealing integrity within a temperature range of -40°C to 120°C.
Structural Design Specifications
The enclosure’s structural design must meet multiple protection requirements: Firstly, double-layer silicone sealing strips should be installed at the enclosure joints, in conjunction with stainless steel anti-loosening bolts, to ensure compliance with IP65 protection rating. Secondly, the wall thickness of the enclosure should be designed according to its volume; typically, enclosures under 20 litres use 2 mm sheet metal, whilst those between 20 and 100 litres use 3 mm sheet metal, with additional internal stiffening ribs. The heat dissipation system design must follow thermodynamic principles; it is recommended to install aluminium heat dissipation fins on non-explosion-proof surfaces, along with explosion-proof axial fans that automatically start and stop based on internal temperature sensors.
Explosion-proof System Configuration
The selection of electrical components must comply with GB3836.1-2010 General Requirements for Equipment for Use in Explosive Atmospheres. It is recommended to use an Exd IIB T4 explosion-proof circuit breaker for the main switch, and Exe II T3 explosion-proof fuses for branch protection. The cable connection system should be equipped with triple protection: an outer layer of stainless steel braided conduit, a middle layer filled with explosion-proof sealing compound, and an inner layer comprising copper explosion-proof cable glands. In particular, at the transition between the enclosure and the cable duct, a labyrinth-type explosion-proof structure must be installed to ensure that explosion pressure can be safely released through pre-set pressure relief channels.
Intelligent Monitoring System
Modern explosion-proof distribution boxes should incorporate intelligent monitoring modules, including but not limited to: a remote monitoring unit based on the MODBUS protocol, capable of collecting parameters such as internal temperature, humidity and insulation resistance in real time; a GSM text message alarm module, which automatically triggers an alarm when a leakage current exceeding 30 mA or a box temperature exceeding 70°C is detected; it is recommended to install an arc flash protection device utilising ultraviolet detection technology, capable of disconnecting the faulty circuit within 5 ms. All monitoring data should be uploaded to the central control system via an intrinsically safe RS485 interface.
Comprehensive Protection Measures
The safety protection system must establish a multi-level protection mechanism: the first level involves controlling the surface resistance of the enclosure’s electrostatic conductive coating to below 10⁶ Ω; The second level involves the installation of Class I, Category C surge protectors with a current-carrying capacity of no less than 40 kA; the third level involves the installation of a thermal aerosol automatic fire extinguishing system, with the activation temperature threshold set at 150°C.
The earthing system shall be made of tin-plated copper, with an earth resistance value not exceeding 4 Ω, and all metal components must be reliably connected via equipotential bonding terminals. In areas prone to frequent lightning strikes, early-discharge lightning rods shall also be installed, with a protection radius covering the entire switchgear area.
These technical specifications have been drawn up with reference to the IEC 60079 series of international standards and the GB 12476 national standard; during implementation, differentiated designs must be adopted in accordance with the classification of hazardous areas (Zone 0, Zone 1, Zone 2) at the specific site. For special industries such as chemicals and petroleum, industry-specific safety certification requirements, such as ATEX or UL certification, must also be met. All design changes must undergo a special review by the Safety Assessment Committee for Electrical Equipment in Explosive Atmospheres.
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Explosion Proof Distribution Boxes parameters:
Norma na vykonávanie: IEC60079
Symbol nevýbušnosti: Ex d IIC T6 Gb
Rated voltage: AC: 220V, 110V
Stupeň ochrany: IP66
Stupeň ochrany proti korózii: WF2
Často kladené otázky o Amasly Light
Q1.Can mám vzorovú objednávku pre LED svetlo?
Odpoveď: Áno, vítame objednávku vzorky na testovanie a kontrolu kvality. Zmiešané vzorky sú prijateľné.
Q2.A čo čas realizácie?
Odpoveď: Vzorka potrebuje 3-5 dní, čas hromadnej výroby potrebuje 1-2 týždne.
Q3.Do máte nejaký limit MOQ pre svetelnú objednávku?
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Q4. Ako odosielate tovar a ako dlho trvá jeho doručenie?
Odpoveď: Zvyčajne posielame DHL, UPS, FedEx alebo TNT. Zvyčajne trvá 3-5 dní, kým dorazí. Letecká a námorná doprava je tiež voliteľná.
Q5. Ako postupovať pri objednávke LED svetla?
A:
Najprv nám oznámte svoje požiadavky alebo žiadosť.
Po druhé, ponúkame ceny podľa vašich požiadaviek alebo našich návrhov.
Po tretie, zákazník potvrdí vzorky a zloží zálohu na formálnu objednávku.
Po štvrté, zabezpečujeme výrobu.
Q6.Je v poriadku vytlačiť môj LOGO na produkte led svetla ?
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Otázka 7: Poskytujete záruku na výrobky?
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Otázka 8: Ako sa vysporiadať s chybou?
A:
Po prvé, naše výrobky sú vyrábané dinstrict systém kontroly kvality a chybné miera bude menšia ako 0,2%
Po druhé, počas záručnej doby poskytneme náhradné diely na výmenu zlej časti. V prípade hromadných objednávok poskytneme zraniteľné diely vopred alebo môžeme diskutovať o riešeniach vrátane stiahnutia z trhu na základe aktuálnej situácie.
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Q10: Je možné pridať núdzové batérie Explosion Poof Lights?
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Nevýbušné lampy Amasly je možné prispôsobiť podľa požiadaviek zákazníka tak pre lampy, ako aj pre obalové kartóny.






