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ЕЛЕКТРИФИКАЦИЯ

Schneider Electric, Siemens, Legrand и ABB са водещи глобални компании в областта на преноса и разпределението на енергия, по-специално в разработването и доставката на разпределителни устройства. Тези компании предоставят надеждни, ефективни и издръжливи решения за разпределителна апаратура за промишлени, търговски и инфраструктурни проекти, като гарантират безопасен и устойчив пренос на електрическа енергия.

Разпределителната апаратура играе критична роля в електрическите системи, осигурявайки основни функции като:

  1. Превключване: Позволява безопасно отваряне и затваряне на вериги с високо напрежение.

  2. Защита: Предпазва електрическите системи от повреди като свръхток или късо съединение, предотвратявайки повреда на оборудването.

  3. Мониторинг и контрол: Позволява наблюдение в реално време на състоянието на електрическата мрежа, минимизирайки загубите на енергия и подобрявайки ефективността на системата.

  4. Регулиране на напрежението: Управлява и регулира напрежението, за да предотврати колебания, които могат да повредят чувствително оборудване.

Schneider Electric, Siemens и ABB предлагат усъвършенствани комутационни системи, които помагат да се гарантира безопасността, надеждността и ефективността на енергийните системи по целия свят. Тези компании са в челните редици на предоставянето на най-новите технологии и решения, за да отговорят на изискванията на съвременните енергийни мрежи.

MCCB

Как да изберем разпределителна уредба?

 

Switchgear selection is a crucial step in electrical installations. Choosing the right switchgear devices (such as switches, fuses, contactors, relays, etc.) is critical for safety, efficiency, and proper system operation. When selecting switchgear, the following factors should be considered:

1. Load Current (Operating Current)
  • Nominal Current: Switchgear is designed to withstand a specific current value. The selection should be made based on the current drawn by the load.

  • Overcurrent Protection: For overcurrent protection, the device should be selected with a value slightly above the operating current; otherwise, the device may fail to provide protection.

2. Short-Circuit Current
  • For short-circuit protection, the switchgear should be selected to handle the maximum possible short-circuit current in the system.

  • The maximum short-circuit current should be calculated, and the device’s breaking capacity (the ability to interrupt a short-circuit) should be verified accordingly.

3. Voltage Rating
  • Switchgear devices must be selected based on the system's voltage level. The device's voltage rating should not be lower than the system's operating voltage.

4. Protection Type
  • Overload Protection: Devices should provide overload protection, especially for loads like motors. This protects the system against excessive current.

  • Short-Circuit Protection: Switchgear must be capable of disconnecting the circuit during short-circuit conditions.

  • Earth Leakage Protection: If there is a risk of earth leakage, devices with earth leakage current detection can be used.

5. Operating Conditions
  • The selection of switchgear should take into account environmental factors, such as temperature, humidity, and vibration, as they can affect the durability of the device.

  • For industrial environments, the IP (Ingress Protection) rating of the device should be considered to ensure it is resistant to dust and water.

6. Mounting Type
  • The type of installation of the switchgear should match the system’s requirements (e.g., panel-mounted, rail-mounted, etc.).

  • The size and connection type should also align with the electrical panel's capacity.

7. Switching Capacity
  • The device should have the appropriate capacity to open and close the circuit under normal operating conditions. For motors, the contactors' switching characteristics should be carefully chosen.

8. Cost and Quality
  • While selecting switchgear, the budget should be considered. However, safety and long-term durability should be prioritized over price when choosing quality devices.

9. Monitoring and Control Features
  • If remote control, automatic switching, or monitoring is required, smart switchgear or devices with advanced features may be preferred.

10. Standards and Certifications
  • The selected switchgear should comply with international or local safety and quality standards. For example, CE certification or TÜV (German technical inspection) can indicate that the device is safe and high-quality.

Example of Switchgear Selection Steps:
  1. Determine the type of load: Identify if the load is a motor, lighting, heater, etc.

  2. Calculate current and voltage values: Based on the load, calculate the current and voltage values to select the proper device.

  3. Choose the protection type: Consider overcurrent protection, short-circuit protection, and earth leakage protection as needed.

  4. Select the type of switchgear: Choose the appropriate switchgear device, such as a switch, fuse, or contactor.

  5. Choose the device brand and model: Select from devices available on the market, considering quality and cost balance.

Considering these factors during switchgear selection is essential for ensuring the safety of the electrical system and achieving efficient and reliable operation.

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