Categories | Outdoor Disconnector Switch |
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Brand Name: | HengAnshun |
Model Number: | GW9-10/1000A |
Place of Origin: | China |
MOQ: | 3units(1group) |
Price: | USD195/Unit Based on EXW |
Supply Ability: | 10000 units/month |
Delivery Time: | 10 work days |
Packaging Details: | Export wooden case packing |
Material: | Ceramic+Stainless Steel+Steel |
Max.Voltage: | 36kV |
Rating Current: | 1000A |
Usage: | Breaking/Connecting |
Wind Speed: | 700Pa |
Packa1 set(3 units)ge: | Export wooden case packing |
Outdoor Disconnector Switch Ceramic Insulator Hookstick Operated
Switch 700Pa Used With Vacuum Circuit Breaker
Product Decription:
Outdoor disconnector switch is a type of electrical switch used in high voltage power systems to isolate sections of the network for maintenance or safety purposes. The switch is typically mounted on a pole or other support structure and is used to disconnect an overhead power line from the rest of the system.
Outdoor disconnector switches are designed to handle high voltages and currents and are often installed in outdoor locations. They consist of a set of stationary and movable contacts that are separated by an air gap. When the switch is in the closed position, the contacts are in contact with each other, allowing current to flow through the circuit. When the switch is opened, the contacts are separated, interrupting the flow of current through the circuit and isolating it from the rest of the system.
Outdoor disconnector switches are an important component of power system safety and reliability and are designed to operate in a variety of environmental conditions. They are often subject to rigorous testing and certification requirements to ensure that they meet industry standards for performance and safety.
Outdoor disconnector switches are commonly used in high voltage transmission and distribution systems to isolate sections of the network for maintenance or repair work. They are also used as a safety device to protect workers from electrical hazards, such as accidental contact with live parts of the system.
Structure:
1.Porcelain Insulator Body: The insulator body is the main component of the isolator, and is typically made of high-strength porcelain. It is designed to provide electrical insulation between the conductor and supporting structure, and is molded into the desired shape and size.
2.Metal End Fittings: The metal end fittings are attached to the insulator body and provide a means of connecting the isolator to the conductor and supporting structure. They are typically made of galvanized steel or other corrosion-resistant material, and may be designed with special features such as clevises or ball-and-socket joints for easy installation.
3.Sealing Compound: A sealing compound is used to seal the joint between the insulator body and metal end fittings, preventing moisture and contaminants from entering the interior of the isolator.
4.Hardware: Hardware such as bolts, nuts, and washers are used to secure the metal end fittings to the insulator body and supporting structure.
5.Fitting Caps: Fitting caps are used to protect the metal end fittings from corrosion and damage, and may be made of plastic or other materials.
6.Additional Features: Depending on the specific application, porcelain high voltage electrical isolators may be designed with additional features such as insulating barriers, arc chutes, and earth switches to improve their performance and safety.
Safety Tips:
1.Compliance with safety standards: High voltage disconnect switches should comply with relevant safety standards, such as IEC, ANSI, or NFPA. Compliance ensures that the switches meet specific safety requirements and have undergone rigorous testing, providing assurance of their reliability and safe operation.
2.Proper ventilation and cooling: Adequate ventilation and cooling systems should be in place for high voltage disconnect switches, especially in enclosed or confined spaces. Proper ventilation helps dissipate heat generated during operation, preventing overheating and reducing the risk of equipment failure or electrical hazards.
3.Hazardous area considerations: High voltage disconnect switches located in hazardous areas, such as those with flammable or explosive atmospheres, should be designed with appropriate protection measures, such as explosion-proof enclosures or intrinsically safe components. These measures mitigate the risk of igniting hazardous substances and ensure safe operation in such environments.
4.Regular inspection and maintenance: High voltage disconnect switches should undergo regular inspection and maintenance to identify and address any potential issues. This includes checking for signs of wear, loose connections, or corrosion, and promptly repairing or replacing any damaged components to maintain the switch's integrity and safety.
5.Clear labeling and signage: High voltage disconnect switches should be clearly labeled with appropriate warning signs and safety instructions. This helps personnel identify the switch, understand its potential hazards, and follow proper safety protocols when operating or working near the equipment.
Application:
1.isolation: When the isolator switch is in the open position, it creates a physical gap in the electrical circuit, which electrically isolates the section of the transmission line on either side of the switch. This prevents electrical energy from flowing through the line, which can help protect against damage to equipment downstream of the switch.
2.Surge protection: The isolator switch is often used in conjunction with surge arrestors, which are designed to protect against voltage surges caused by lightning strikes or other electrical disturbances. The combination of the isolator switch and surge arrestors helps protect against damage to equipment by diverting excess electrical energy away from the transmission line.
3.Maintenance safety: By providing a visible break in the transmission line, the isolator switch helps ensure that maintenance personnel can safely work on the line without risk of electrocution. This helps protect both the equipment and the people working on it.
Collocation:
The relation between the outdoor vacuum circuit breaker and the outdoor high-voltage disconnect isolator lies in their complementary roles in the electrical system:
Circuit Interruption: The vacuum circuit breaker is responsible for interrupting the electrical circuit during normal operation or in the event of a fault. It acts as the primary means of breaking the current flow. In contrast, the disconnect isolator is used for isolating the circuit from the power source during maintenance or repair activities. It provides an additional layer of safety by physically opening the circuit.
Coordination: In high-voltage power systems, the vacuum circuit breaker and the disconnect isolator are often coordinated to work together. The circuit breaker is responsible for detecting faults and tripping to interrupt the current flow, while the disconnect isolator is used to physically isolate the circuit and provide a visible indication of the disconnection.
Safety and Maintenance: The disconnect isolator plays a crucial role in ensuring the safety of maintenance personnel. Before any maintenance work can be performed on the electrical equipment, the disconnect isolator is operated to open the circuit and provide a visible air gap. This ensures that the equipment is de-energized and safe to work on. The vacuum circuit breaker, on the other hand, protects the system during normal operation and in the event of faults.
Technical Parameters:
Serial No. | Parameter | Unit | Data | |||||||||
1 | Rated Voltage | kV | 12 | |||||||||
2 | Rated Current | Model No. | (H)GW9-12(W)/630-20 | A | 630 | |||||||
(H)GW9-12(W)/1000-20 | 1000 | |||||||||||
(H)GW9-12(W)/1250-31.5 | 1250 | |||||||||||
3 | 4s Short-time withstanding current | Model No. | (H)GW9-12(W)/630-20 | kA | 50 | |||||||
(H)GW9-12(W)/1000-20 | 50 | |||||||||||
(H)GW9-12(W)/1250-31.5 | 80 | |||||||||||
4 | Rated Insulation Level | Lightning surge withstand voltage(peak) | Polar-to-Earth (Positive & Negative) | kV | 75 | |||||||
Interfracture (Positive & Negative) | 85 | |||||||||||
Industrial frequency withstand voltage (1 min) (Effective value) | Dry Test/Wet Test | Polar-to-Earth | 42(Dry) 34(Wet) | |||||||||
Interfracture | 48(Dry) | |||||||||||
48(Dry) | ||||||||||||
48(Dry) 40(Wet) | ||||||||||||
5 | Main Circuit Resistance | μ Ω | 630 | |||||||||
1000 | ||||||||||||
1250 | ||||||||||||
6 | Mechanical Life Time | times | 50 | |||||||||
50 | ||||||||||||
80 |