KR200168221Y1 - An alternator - Google Patents

Abstract

The present invention relates to an alternator, and more particularly to a coupling structure of the insulating member provided in the output terminal.

In the alternator according to the present invention, the cutout portion of the outer insulation member of the output terminal is coupled to a fixed position. A coupling hole is formed in the plate portion of the end cover, and the engagement protrusion is provided in the outer insulation member. Therefore, the rotation of the outer insulation member due to the vibration or shock generated during the assembly process is prevented, so that defects due to incorrect assembly are reduced. In addition, since the outer insulation member is in close contact with the end cover when the flange nut is assembled, breakage of the insulation member due to the impact of the impact trench is reduced.

Description

Alternator

The present invention relates to an alternator, and more particularly to a coupling structure of the insulating member provided in the output terminal.

In general, an alternator is provided with a rotor provided with a field coil on a rotating shaft connected to a prime mover. As the rotor rotates in the stator, alternating current is generated between the stator windings. The alternating current generated in this way is rectified by direct current by a rectifier, and partly supplied to the field coil of the rotor. And most of the rest is output to the outside through the output terminal protruding outside the end cover.

The structure of this output terminal is explained with reference to FIG.

The terminal bolt 1 provided at the rear of the alternator is press-fitted so that the terminal bolt 2 protrudes outward from the end cover 3. The plate portion 3a of the end cover 3 corresponding thereto has a hole 3b through which the terminal bolt 2 penetrates.

On the other hand, insulating members 4 and 5 are provided inside and outside the plate portion 3a of the end cover so that the output terminals are electrically insulated from the surroundings. That is, the inner insulation member 4 is fixed between the terminal plate 1 and the plate portion 3a of the end cover, and the outer insulation member 5 is the plate portion 3a and the terminal bolt 2 of the end cover. It is fixed between the flange nuts 6 fastened to each other.

Here, the outer insulation member 5 is provided with a brittle material, and attention to shock breakage during handling is required. In addition, as shown in FIG. 2, the outer insulation member 5 has a cutout portion 5a formed so that a part of the outer edge thereof is cut off to facilitate the connection at the time of connecting the external connector.

If this is described according to the assembly order, after assembling the inner insulating member 4 to the terminal bolt 2 fixed to the terminal plate 1, the end cover 3 is assembled. Subsequently, after assembling the outer insulation member 5 to the terminal bolt 2 protruding to the outside of the end cover 3, the assembly of the output terminal is completed by fastening the flange nut 6 using an impact wrench.

However, such a conventional output terminal has a problem that the insulating member is rotated by leaving the correct position by a light shock or vibration in the process of assembling the outer insulating member. As a result, the cutout formed in the outer insulation member is assembled out of the correct position, and there is a problem that it is difficult to connect the connector later. In addition, as the flange nut is fastened in a state in which the outer insulation member is slightly separated from the plate portion of the end cover, there is a problem that the outer insulation member is damaged by the impact of the impact wrench.

The present invention is to solve such a problem, it is an object of the present invention to improve the coupling structure of the insulating member, to prevent the misassembly and breakage of the insulating member, to provide an alternator with improved assembly.

1 is a partial cross-sectional view showing a structure of a conventional output terminal.

2 is a perspective view showing the structure of a conventional outer insulating member.

3 is a cross-sectional view showing the internal configuration of the alternator according to the present invention.

4 is a partial cross-sectional view showing the structure of the output terminal according to the present invention.

5 is a view showing an end cover according to the present invention.

6 is a perspective view showing the structure of the outer insulation member according to the present invention.

Explanation of symbols on the main parts of the drawings

25: end cover 25c: coupling hole 30: output terminal

34: outer insulation member 34b: coupling protrusion

The present invention for achieving the above object, the body of the alternator, the end cover coupled to the outside of the body, the output terminal protruding to the outside of the end cover to supply the output current, the output terminal is provided on the output terminal An alternator including an insulation member electrically insulated from the surroundings, and a cutout formed in the insulation member to facilitate connection of an external connector.

Positioning means is provided between the end cover and the insulating member so that the cutout is assembled toward a predetermined position.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment according to the present invention in detail.

As shown in FIG. 3, the alternator according to the present invention is provided with a cylindrical stator 11 composed of an iron core and a coil, and the stator 11 includes front and rear brackets 12 and 13 supporting the same. Together form the body 10 of the alternator.

The inner center of the body 10 is provided with a rotating shaft 16 which is supported by the front and rear bearings 14 and 15. The rotary shaft 16 is provided with a rotor 17 having a built-in field coil, and interacts with the stator 11 on the outside, and cooling fans for cooling components in the body on both sides of the rotor 17. 18, 19) are installed.

The rotating shaft 16 extending outwardly of the rear bracket 13 is provided with a slip ring 20 for supplying current to the field coil of the rotor 17. A brush 21 is provided on the outside of the rear bracket 13 to be in contact with the slip ring 20, and a brush holder 22 supporting the slip bracket 20 is provided. In addition, a rectifier 23 for rectifying alternating current into a direct current and a voltage regulator 24 for adjusting the output voltage of the generator are provided, and an end cover 25 is provided to surround and protect them. In addition, the output terminal 30 through which the output current is output is provided to protrude to the outside of the end cover 25.

The alternator configured as described above generates an output current in the stator 11 when the rotor 17 receiving the exciting current is rotated through the brush 21 and the slip ring 20. The output current generated in this way is rectified by the rectifier 23 into direct current, and a part of the output current is supplied to the field coil of the rotor 17. And most of the rest is output to the outside through the output terminal (30).

The structure of this output terminal will be described in detail with reference to FIG. 4 as follows.

In the terminal plate 31 provided at the rear of the alternator, a terminal bolt 32 is press-installed to protrude outward from the end cover 25. A hole 25b through which the terminal bolt 32 penetrates is formed in the plate portion 25a of the end cover corresponding thereto.

In addition, insulating members 33 and 34 are provided on inner and outer surfaces of the plate portion 25a of the end cover so that the output terminal 30 is electrically insulated from the surroundings. That is, the inner insulation member 33 is interposed between the terminal plate 31 and the plate portion 25a of the end cover, and the outer insulation member 34 is fixed to the plate portion 25a and the terminal bolt 32 of the end cover. It is interposed between the flange nut 35 is fastened to the () is fixed.

On the other hand, the output terminal 30 according to the present invention is provided with a positioning means between the plate portion 25a of the end cover and the outer insulating member 34. This will be described with reference to FIGS. 5 and 6.

Figure 5 shows an end cover according to the present invention, Figure 6 is a perspective view showing an outer insulating member according to the present invention.

The outer insulation member 34 according to the present invention has a cutout portion 34a formed so that a part of the outer edge is cut off so that the connection can be easily performed at the time of connecting the external connector. The cutout 34a should be fixed toward a predetermined position, for which a positioning means is provided. Coupling holes 25c are formed in the plate portion 25a of the end cover by the positioning means, and coupling protrusions 34b are provided in the outer insulation member 34. The coupling hole 25c and the coupling protrusion 34b are provided to be interfitted with each other, thereby preventing the flow of the outer insulation member 34 so that the cutout portion 34a maintains its position.

Here, the outer insulating member 34 is provided with a brittle material, attention is required to the impact breakage during handling.

When the output terminal 30 is described in the assembling order, the inner cover 33 is assembled to the terminal bolt 32 fixed to the terminal plate 31, and then the end cover 25 is assembled. Subsequently, the outer insulation member 34 is assembled to the terminal bolt 32 protruding outward from the end cover 25, wherein the engaging projection 34b of the outer insulation member is inserted into and fixed to the engaging hole 25c of the end cover. The cutout 34a of the outer insulation member 34 maintains its position. Next, when the flange nut 35 is fastened using the impact wrench, the assembly of the output terminal is completed.

As described in detail above, the AC generator according to the present invention is to allow the cutout portion of the outer insulation member of the output terminal to be coupled to the correct position, the coupling portion is formed in the plate portion of the end cover, the engaging projection is formed on the outer insulation member Prepared. Therefore, the rotation of the outer insulation member due to the vibration or shock generated during the assembly process is prevented, so that defects due to incorrect assembly are reduced. In addition, since the outer insulation member is in close contact with the end cover when the flange nut is assembled, breakage of the insulation member due to the impact of the impact trench is reduced.

Claims (2)

Body of an alternator, an end cover coupled to the outside of the body, an output terminal protruding to the outside of the end cover to supply an output current, an insulation member provided on the output terminal to electrically insulate the output terminal from the surroundings, the insulation In an alternator comprising a cutout formed in the member to facilitate connection of an external connector, AC generator, characterized in that the positioning means is provided between the end cover and the insulating member to be assembled toward the predetermined position. The method of claim 1, The positioning means is an alternator characterized in that it is provided with a coupling projection provided to protrude to the insulating member, and the coupling hole is provided in the end cover and the coupling projection is pressed.