Курсовая работа: Planning of mobile complete set for a rural wind generator

· Other magnets in close proximity to the magnet

If a magnet is stored away from high temperatures, and from the factors mentioned above, it will retain its magnetism essentially forever. Modern magnet materials lose a fraction of their magnetism over time if affected by the above factors ^[8] .

3.5 Generator losses

The losses in a synchronous generator consist of rotational loss (mechanical loss and magnetic loss) and copper loss in the armature winding. The rotational loss and the field winding loss are subtracted from the power to obtain the power developed by the armature. By subtracting the copper losses in the armature from the developed power, we obtain the output power of a synchronous generator.

In this section, the core loss will be discussed since they are due to the magnetic flux variations.

3.5.1 Eddy current loss

This power loss occurs in a magnetic core when the flux density changes rapidly in the core. Because core material has resistance, a power loss i² R will be caused by the eddy current and will appear as heat in the core ^[13] .

The average eddy current loss is:

(Eq. 3.3)

where P_e is the eddy current loss in watts (W), k_e is the constant that depends on the conductivity of the magnetic material, f is the frequency in hertz (Hz), δ is the lamination thickness in meters, B_m is the maximum flux density in tesla (T) and V is the volume of the magnetic material in cubic meters (m³ ) ^[14] .

The eddy current losses can be reduced by ^[13] :

· Using a high-resistivity core material

· Using a laminated core, in transformers and electric machines the parts that are made of magnetic core and carry time-varying flux are normally laminated.

3.5.2 Hysteresis loss

During a cycle variation of current i, there is a net energy flowing from the source to the coil-core assembly. This energy loss goes to heat the core. The loss of power loss in the core owing to hysteresis effects is called hysterisis loss.

By testing various ferromagnetic materials, Charles Steinmetz proposed that hysteresis loss can be expressed as ^[14] :

(Eq. 3.4)

where P_h is the hysteresis loss in watts, k_h is a constant that depends upon the magnetic material and n is the Steinmetz exponent.

3.5.3 Core loss

The hysterisis loss and eddy current loss are lumped together as the core loss of the coil-core assembly, and given by:

(Eq. 3.5)

3.6 Design Variables

In the following section, all the parameters that are necessary to design and construct a generator will be discussed and variables such as generator diameter, length, etc. will also be calculated.

3.6.1 Speed of the generator

The annual mean wind speed at Ga-Rampuru is approximately 4m/s ^[11] . The rotor will rotate at the same speed as the wind turbine; therefore this means that the rotor will rotate at:

= 250 rad/s = 2387.3 rpm

The rotor speed and the average frequency of the induced voltage are related by:

(Eq. 3.7)

Since a two-pole machine will be designed, the frequency is calculated using equation 3.9 to be 39.79 Hz.

3.6.2 Rotor and Stator Core

A cylindrically shaped rotor will be appropriate for this design as it allows maximum flux distribution over the armature surface as the field coils are spread over the periphery of the rotor. This type of design also accommodates the use of small cylindrical magnets ^[11] .