KR19980084437A - Alternator Armature Coil Winding Method - Google Patents

Abstract

The present invention relates to a method of winding an alternator armature coil (4), in particular the relationship between the field magnetic pole size (a) and the field magnetic pole spacing (b), the winding angle (a, b, c, d) of the armature coil (4) By establishing correctly and matching the winding angles (a, b, c, d) with the field stimulus spacing (b) of the electric coil (4), the emphasis was placed on reducing the phase difference and producing a good sine wave alternating current.

The armature coil of a general generator is inserted into a groove in a counterpart that is different by 90 degrees even in three phases and 60 degrees in three phases. As shown in FIG. 6 (b), the coil windings of one phase are separated by 60 degrees. Since the coil length becomes longer, the efficiency decreases due to the internal resistance of the coil. The magnetic pole size (a ') and the magnetic pole spacing (b') of FIG. 6 (a) are the electric magnetic coil (b ') where the actual magnetic flux linkage occurs in the electric coil (4) of FIG. 6 (b). (4) Due to the difference in winding angle, phase difference occurs due to the time difference reaching the coil. It is also wrong to distinguish this phase difference into voltage and current.

In the present invention, the grooves of the magnetic poles and the magnetic core 5 must be even and the coil winding angles (a, b, c, d) include the even magnetic grooves (5) evenly within the magnetic pole spacing (b). A magnetic pole end portion forming the magnetic pole spacing (b) passes through the left and right 齒 幅 1/2 of the magnetic core (5).

The armature coil (4) of the present invention is left and right in the magnetic pole interval (b) and even grooves in the magnetic pole interval (b) as shown in Figure 5 (a), (b), (c), (d) The coil winding angles (a, b, c, d) including 1/2 are wound around the coils at the same angle as the magnetic pole spacing (b) and spaced by the magnetic pole size (a), and the coils are placed within the next magnetic pole spacing (b). Winding up.

Referring to the operation and effect of the present invention.

The armature coil 4 is wound around the armature core 5 fixed to the body 1 and the field magnetic pole 2 assembled to the body 1 rotates clockwise by the power transmitted to the shaft 6. As shown in FIG. 7, induction electromotive force is generated in the armature coil 4 where the magnetic lines cross. The induced electromotive force is applied to (a) and (c) part coils (4) where the magnetic field lines (2) of the field magnetic pole (2) and the (pole) rotational direction of FIG. 3 intersect according to Fleming's right-hand rule. As shown in (a), the positive (+) waveform (NS) is generated, and the (b) and (d) part coils where the magnetic poles of the S-pole and the N-pole (based on the rotational direction) in FIG. As shown in A), a negative waveform (SN) occurs. As such, the (NS) waveform and the (SN) waveform are connected in series with the armature coil 4 as shown in FIG. A positive (+) composite waveform of + NS + SN is output and a negative composite waveform of SN + NS + SN + NS is output when rotated 180 degrees. When rotating 270 degrees, the positive composite waveform of NS + SN + NS + SN is output. When rotating 360 degrees, the negative composite waveform of SN + NS + SN + NS is output. When the stimulus is rotated by the generator, AC cycle of 2 cycles is output.

In the present invention, the armature coil 4 of one phase is wound around the coil at the same angle (a) as the magnetic pole spacing (b) of the field magnetic pole (2) and floated by the magnetic pole size (a) again the same angle as the magnetic pole spacing (b) ( Since the coil is wound repeatedly by (c) and (d), the armature coil (4) length is reduced by the arc length of the magnetic pole size (a), thereby significantly reducing the internal resistance of the armature coil (4) and reducing the manufacturing cost. have.

In addition, since the magnetic pole spacing (b) and the winding angle of the armature coil (4) are the same, the phase difference can be significantly reduced, so that an alternating current of a good sine wave can be obtained, and the manufacturing cost can be reduced because the winding method of the armature coil (4) is simple.

In this way, the relationship between magnetic pole and armature coil is correctly established, and the most suitable design of magnetic pole size (a), magnetic pole interval (b) and armature coil (4) maximizes energy saving and power generation efficiency and reduces manufacturing cost. This is a very informative thing to do.

Description

Alternator armature coil winding method

1 is a cross-sectional view of the generator of the present invention

2 is a perspective view of field stimulation of the present invention

3 is a cross-sectional view of the armature coil and field magnetic pole of the present invention

4 is a current waveform diagram of the present invention.

(A) is the 1-phase current waveform diagram for each magnetic flux linkage part

(B) 1-phase synthesized current waveform output by the wire

(C) is the current waveform and the field rotation angle

5 is an exploded view of field stimulation and electric coil of the present invention.

(A) is a field stimulation development of the present invention

(B) is the development of the armature core and armature coil of the present invention

(C) is angle relation between field stimulus interval and electric coil electric angle

(D) is a detailed view of the coil winding of the present invention

6 is a general generator stimulation and electric coil development

(A) Figure of conventional field stimulation development

(B) is a development of conventional armature core and armature coil winding

(C) is a conventional current waveform diagram

7 is a magnetic line passage diagram of the present invention

8 is a block diagram of the present invention.

* Explanation of symbols for main parts of drawings *

1 generator main body 2 magnetic field stimulation

3: field coil 4: electric magnetic coil

5: armature iron core a: stimulation size of the present invention

b: stimulation interval of the present invention a ': conventional stimulation size

b ': Conventional magnetic pole spacing (a, b, c, d): electric coil winding angle

The present invention relates to a method for winding an armature coil of an alternator and to correctly establish a correlation between an armature coil and a field stimulus, and in particular, to determine the winding angles (a, b, c, d) and the field stimulation interval (b) of the armature coil (4). At the same angle, the main focus was on reducing the phase difference and developing a good sine wave.

The armature coil of a general generator is inserted into a groove in a counterpart that is different from each other by 90 degrees in three phases and 60 degrees in three phases, and as shown in FIG. 6 (b), the winding of the one-phase armature coil 4 is 60 degrees apart. Therefore, the length of the coil is longer than necessary, so the internal resistance of the coil decreases the efficiency and the weight of the generator is high. The magnetic pole size (a ') and the magnetic pole spacing (b') of FIG. 6 (a) are the magnetic flux chains in the armature coil (4) of FIG. 6 (b). Due to the difference in the winding angle of the armature coil 4, a phase difference occurs due to the time difference reaching the coil. It is also wrong to distinguish this phase difference into voltage and current.

In the present invention, the right hand law of Fleming is applied to the correlation between the electric magnetic coil (4) and the field stimulation (2) correctly to improve the power generation efficiency and to produce a good current.

This will be described with reference to the accompanying drawings.

This study will be described by using a four-pole three-phase generator as an example.

The armature coil 4 fixed to the main body 1 of FIG. 1 is wound around the armature coil 4 in the same manner as in FIG. 5 (b), and the field magnetic pole 2 is assembled to the body 1 as shown in FIG. To rotate the field magnetic pole (2) by the external power transmitted to the shaft (6).

In the above, the magnetic pole is configured as the second magnetic pole size (a0 is 60 degrees and the magnetic pole interval (b) 30 degrees to configure the magnetic field stimulation (2), the magnetic pole size (a) and the magnetic pole interval (b) in the three-phase generator) The magnitude (a) and the stimulation interval (b) are 2: 1, and in the two-phase generator, the stimulus size (a) and the stimulation interval (b) are 1: 1.

Field stimulation uses waste light permanent magnets and electromagnets and facilitates heat dissipation during power generation.

The number of grooves in the magnetic magnet core 5 is an even number, and the number of grooves in the coil winding angles (a, b, c, d) in the coil winding angles (a, b, c, d) must be the same in the magnetic magnet core 5 and the magnetic pole spacing (b). Make it even. In addition, both ends of the magnetic pole forming the coil winding angle (a, b, c, d) to pass through 1/2 of the left, right 齒 幅 of the magnetic core (5).

In the above, the armature coil 4 is wound in the clockwise direction as shown in the detail of Fig. 5 (D), and the winding angle of the armature coil 4 of Fig. 5 (A) and the armature coil 4 of Fig. 5 (B) Is equal to the magnetic pole core (5) embraced by the magnetic pole spacing (b), including 齒 幅 1/2 of the left and right. In other words, the winding angle of the armature coil (4) in the 4-pole three-phase generator is the coil winding angle (a, b, c) of FIG. 3 including the left and right 齒 幅 1/2 of the magnetic core (5) embraced by the magnetic pole spacing (b). Wind the coil at 30 degrees (stimulation interval) like 30, (d) and repeat the coil at 30 degrees (stimulation interval) with a space of 60 degrees (stimulation interval). In this manner, the coil is wound in two-phase and three-phase order. 3 is a cross-sectional view of the field magnetic pole (2) and the armature coil (4) showing the winding angles (a, b, c, d), the magnetic pole size (a), the magnetic pole spacing (b) of the electric coil (4).

4 is an output waveform diagram, (A) is a 1-phase current waveform diagram for each magnetic flux linkage area, (B) is a 1-phase synthetic current waveform actually output by the wire, and (C) is a current waveform and field stimulation rotation angle. This is an angle view to check the relationship between.

5 is an exploded view showing the principle of the present invention, (a) is a magnetic pole development diagram, (b) is an electric magnetic core (5) and an electric coil (4), and (c) a magnetic pole and the magnetic core (5) and the electric coil ( Correlation with 4) is expressed in degrees, and (d) is a detailed view of the winding of the armature coil 4. 6 is a conventional development principle of the power generation, (a) is a magnetic pole development degree, (b) is an electric coil (4) development degree (c) is a current waveform. 7 is a magnetic line passage diagram of the present invention and FIG. 8 is a block diagram of the present invention.

As described above, the operation and effects of the present invention will be described.

The armature coil 4 is wound around the armature core 5 fixed to the body 1 and the field magnetic pole 2 assembled to the body 1 is clockwise by an external power transmitted to the shaft 6. When rotated, the induced electromotive force is generated in the armature coil 4 where the magnetic lines of force cross each other as shown in FIG. The induced electromotive force is applied to the armature coil (4) at (a) and (c) where the magnetic field lines (2) of the field magnetic pole (2) and (c) of the magnetic pole of FIG. 3 intersect according to Fleming's right-hand rule. A positive (+) waveform (NS) is generated as shown in (a) of FIG. 4 and the armature coil (4) at (b) and (d) where the magnetic poles of the S-pole and the N-pole (based on the rotational direction) of FIG. 3 intersect. As shown in Fig. 1A, a negative waveform SN is generated. In this way, the (NS) waveform and the (SN) waveform are connected in series with the armature coil 4 as shown in (D) in FIG. 5, so that the current waveform in one phase is different from that in FIG. Likewise, if the stimulus rotates by 90 degrees, as shown in (b) of Figure 4, the positive (+) composite current waveform of NS + SN + NS + SN is output. The synthesized current waveform of is output. When rotating 270 degrees, the positive composite current waveform of NS + SN + NS + SN is output. When rotating 360 degrees, the negative composite current waveform of SN + NS + SN + NS is output. In three-phase generator, two cycles of AC current waveform are output when one pole is rotated. In the present invention, the armature coil 4 of one phase is wound around the coil at the same angle (a) as the magnetic pole spacing (b) of the field magnetic pole (2) and floated by the magnetic pole size (a) again the same angle as the magnetic pole spacing (b) ( Since the coil is wound repeatedly by (c) and (d), the armature coil (4) length is reduced by the arc length of the magnetic pole size (a), thereby significantly reducing the internal resistance of the armature coil (4) and reducing the manufacturing cost. have.

In addition, because the magnetic pole spacing (b) and the coil angle (4) winding angles (a, b, c, d) are the same, the phase difference can be significantly reduced, so that an alternating current of a good sine wave can be obtained, and the winding method of the armature coil (4) is simple. Therefore, manufacturing cost can be reduced. As such, the relationship between the field magnetic pole (2) and the electric magnetic coil (4) is correctly established, and the most suitable design of the magnetic pole size (a), the magnetic pole spacing (b), and the electric magnetic coil (4) saves energy and generates efficiency. It is very useful to raise the maximum and reduce the production cost.

Claims (1)

In the alternator, the magnetic pole size (a) and the magnetic pole spacing (b) are the size of the magnetic pole size (a) and the magnetic pole spacing (b) of 2: 1 in the three-phase generator, and the magnetic pole size (a) and the magnetic pole in the two-phase generator. The spacing (b) forms a field stimulus with a size of 1: 1, and the winding angles (a, b, c, d) of one-phase armature coils (4) are equal to the even number of armature iron cores (5) embraced by the stimulation interval (b). Wind the armature coil 4 at the same angle (a) as the magnetic pole spacing (b), which includes the groove and both sides 하고 1/2, spaced by the magnetic pole size (a) again to the same angle as the magnetic pole spacing (b) ( B) winding the armature coil (4). Repeat in this manner to wind up the coil (c, d). As described above, the alternator armature coil (4) winding method characterized by winding two-phase and three-phase armature coils (4) in turn.