Product Details
Place of Origin: China
Brand Name: ENNENG
Certification: CE
Model Number: PMG
Payment & Shipping Terms
Minimum Order Quantity: 1
Price: USD 1000-5000/set
Packaging Details: seaworthy packing
Delivery Time: 15-120 days
Payment Terms: L/C, T/T
Supply Ability: 20000 sets/year
Name: |
Permanent Magnet Wind Turbine Alternator |
Current Type: |
AC |
Power Range: |
5-2000kw |
Protection Grade: |
IP54 IP55 |
Bearing Brand: |
SKF |
Cooling Method: |
Natural Cooled |
Phases: |
3 Phase |
Application: |
Wind Turbine, Hydro Turbine, Etc. |
Voltage: |
220v,380v, 400v,690v, Etc. |
Material: |
Rare Earth NdFeB |
Name: |
Permanent Magnet Wind Turbine Alternator |
Current Type: |
AC |
Power Range: |
5-2000kw |
Protection Grade: |
IP54 IP55 |
Bearing Brand: |
SKF |
Cooling Method: |
Natural Cooled |
Phases: |
3 Phase |
Application: |
Wind Turbine, Hydro Turbine, Etc. |
Voltage: |
220v,380v, 400v,690v, Etc. |
Material: |
Rare Earth NdFeB |
5-2000kw 3-Phase Permanent Magnet Wind And Hydro Turbine Alternator
Detailed Pictures
The permanent magnet generator is a device that converts mechanical energy to electrical energy. In this device, the rotor windings have been replaced with permanent magnets. Permanent magnet generators are used mostly in industrial applications like turbines and engines to produce commercial electrical energy, the permanent magnet alternator is an alternate source of energy and has multiple benefits which make it a great device for a variety of residential, commercial, and industrial applications.
The structure
The permanent magnet generator is mainly composed of a rotor, end cover, and stator. The structure of the stator is very similar to that of an ordinary alternator. The biggest difference between the structure of the rotor and the alternator is that there are high-quality According to the position of the permanent magnet on the rotor, the permanent magnet generator is usually divided into a surface rotor structure and a built-in rotor structure.
Working Principle
The main components of permanent magnet generators are stators and rotors.
The rotor is made from permanent magnets, and it could generate magnetic fields. Magnetic parts are set around the stators as well, so fluxes could compass them.
The stator is composed of rotating coils. Once receiving the magnetic power, the stator generates electricity consequently.
In this way, the movement of the rotors is transformed into electric energy. The more stator coils we have, the more electric currents we get.
The permanent magnet alternator’s rotor is directly equipped with a wind turbine so that it can generate fixed electrical power. The efficiency of permanent magnet synchronous alternators is way higher than that of asynchronous generators. It offers a variety of merits over asynchronous generators and they are as follows:
· Direct drive (No speed multiplier, no gearbox needed)
· Virtually no maintenance
· Highest power-to-weight ratio in direct drive
· High efficiency
· Simplification of mechanical design · Easy mechanical interface
· Cost optimization
· They are environmentally friendly and do not rely on the external weather to produce electricity
· They are smaller in size and hence require very less space compared to other types of generators.
· These permanent magnet generators run for years and beyond without any wear and tear. Additionally, they are soundless and noise-free thus making zero sound pollution.
The classification of permanent magnet generator:
Permanent magnet generators (PMGs) can be classified based on various factors, such as the type of magnet, the application, the number of phases, and the power rating. Here are some common classifications of permanent magnet generators:
Based on magnet type: a. Ferrite Magnet PMG: These generators use ferrite magnets, which are less expensive and have lower magnetic strength than rare-earth magnets. b. Rare-Earth Magnet PMG: These generators use neodymium or samarium-cobalt magnets, which are more expensive but have a higher magnetic strength than ferrite magnets.
Based on application: a. Wind Turbine PMG: These generators are designed for use in wind turbines and are typically used in small-scale or off-grid applications. b. Hydroelectric PMG: These generators are designed for use in hydroelectric power plants and are typically used in large-scale applications.
Based on the number of phases: a. Single-phase PMG: These generators have a single output phase and are used in low-power applications. b. Three-phase PMG: These generators have three output phases and are used in high-power applications.
Based on power rating: a. Low-power PMG: These generators have a power rating of up to a few kilowatts and are used in small-scale applications. b. High-power PMG: These generators have a power rating of several megawatts and are used in large-scale applications, such as wind turbines and hydroelectric power plants.
These are some common classifications of permanent magnet generators, but there may be other ways to classify them based on specific parameters.
The differences between the electromagnet and permanent magnet:
Unlike electromagnets, permanent magnets do not require any external power source. The main difference between the use of electromagnets and permanent magnets in wind turbines is that electromagnets require slip rings to power the electromagnets, while permanent magnets do not. Likewise, gearboxes require ongoing maintenance, which adds significantly to costs.
The function of the gearbox is to convert the low speed of the turbine shaft to the higher speed required by the induction generator to generate electricity, but the gearbox causes friction and reduces performance. For example, by using neodymium magnets instead of electromagnets, we can increase the efficiency of turbines, reduce efficiency and reduce maintenance costs.
Today, engineers have developed more sophisticated electromagnetic generators that work in tandem with wind captured by wind turbines to generate electricity for local consumption in homes, schools, hospitals, commercial establishments and more. As of now, depending on the strength of the wind, a single wind turbine can generate up to 113GW of electricity, which can power about 250 to 300 houses.
· Low-speed, direct-drive PMGs operate without any gearbox and fast-rotating parts, resulting in increased reliability and superior drive train efficiency.
· Generator can be designed with a segmented stator construction. This provides redundancy and makes it possible to repair the generator in the nacelle without full disassembly. Optionally, our generator design can use the generator bearing as a turbine main bearing to integrate the turbine brake system into the generator construction. Benefits are simplicity, fewer components, and therefore, higher reliability.
· With the rising cost of electricity, an increasing number of populations are looking for an alternate source of energy and permanent magnet generators fit this gap perfectly. These generators can also reduce the strain on the environment as they do not use any non-renewable sources of energy for producing electricity.
How do magnets provide better mounting solutions for wind turbines?
In addition to helping generate electricity, permanent magnets play a vital role in helping maintain the integrity of the turbine's high walls. If you're lucky enough to see the inside of a wind turbine, you'll see lots of cables and very long ladders attached to the walls, some of which contain elevators that allow workers to access the turbine nacelles. The traditional solution for this is to drill holes in the turbine wall to install the brackets or weld the brackets to the wall to secure the brackets. Unfortunately, this solution can affect the integrity of the wall, reducing its strength and making it prone to corrosion.
1. Free Energy Source
Permanent magnet generators produce electricity using their own magnetism. So, you do not need to pay high electric bills, and a large budget is saved. Besides, these devices do not need any other resources, which are quite environmentally friendly.
2. Reliable Power Output
Permanent magnet generators do not need any special operating environments. Hence, they can offer reliable performance compared with wind turbine motors. Additionally, permanent magnet generators do not suffer from energy loss, while induction generators typically lose 20-30% of energy. Additionally, there are no temperature rises in the magnetic machines, so the life of the bearings can be prolonged.
3. Low Maintenance Fee
Due to the features mentioned above, you do not need to spend lots of money and time on the maintenance of permanent magnet generators. And they do not have slip rings and brushes, which are supposed to be checked at regular intervals.
4. Compatibility
Permanent magnet generators can be employed with turbines and diesel generators.
5. Extremely high availability due to simple and robust design
6. Superior efficiency over the entire wind speed range, even at partial loads, resulting in higher efficiency and increased AEP rates.
7. Optimized and tailored to each wind turbine and the environment in which it will operate.
8. Highly serviceable design speeds up maintenance routines. PMG technology eliminates wearing parts, ensuring fewer failures and significantly reducing the need for maintenance.
9. The PMG coupled with a full-power converter provides future-proof grid code compliance, including fault ride-through and 100% reactive power compensation capability.
