KR100656270B1 - Induction generator advanced heat conduction of stator core - Google Patents

Abstract

The present invention relates to an induction generator having a stator iron core with improved heat conductivity by optimizing the size of the generator and maximizing the cooling efficiency by forming a concave-convex cooling fin on the outer diameter side of the stator iron core to improve thermal conductivity.

Induction generator having a stator iron core with improved thermal conductivity according to the present invention, the slot is inserted into the stator coil in the inner diameter side of the yoke, and instead of the frame for thermally conducting the heat generated from the stator coil to the outer diameter side to the outside A stator iron core having an uneven cooling fin formed therein; A rotor iron core which is rotated together with the shaft in the stator iron core and has a plurality of air holes so that internal air flows around the shaft; A rotor air guide installed to flow internal air generated by the rotation of the rotor bar through the air hole of the rotor iron core; An enclosure installed at an outer diameter of the stator iron core to protect the stator iron core from external impact and foreign matter; An outer fan cover installed at an upper end of the half load side bearing of the shaft and connected to the half load side of the enclosure; The outer fan is installed inside the outer fan cover and is provided with an outer fan installed so that external air flows between cooling fins of the stator iron core by generating air flow by rotation.

Induction Generator, Induction Motor, Stator Iron, Cooling Fin, Air Hole, Rotor Air Guide

Description

Induction generator advanced heat conduction of stator core

1 is a cross-sectional view showing the overall structure of the induction generator according to the present invention.

2 is a cross-sectional view of the induction generator cut by the cutting line A-A of FIG.

3 is a structural diagram showing a sheet structure of the stator iron core of FIG.

4 is a cross-sectional view of the enclosure protecting the stator iron core of FIG.

Figure 5 is a cross-sectional structural view showing the overall structure of a conventional induction generator.

6 is a cross-sectional view of the induction generator cut by the cutting line B-B of FIG.

7 is a structural diagram showing a sheet structure of the stator iron core of FIG.

8 is a cross-sectional view of a frame on which the stator iron core of FIG. 5 is supported.

Explanation of symbols on the main parts of the drawings

11: stator iron core 12: stator coil

13: iron core 14: rotor bar

15: Rotor Air Guide 16: Half Load Side End Shield

17: Load side end shield 18: Half load side bearing

19: load side bearing 20: enclosure

21: outer fan 22: outer fan cover                 

23: shaft 31: cooling fin

32: slot 41: air hole

The present invention relates to an induction generator, and more particularly, to an induction generator having a stator core with improved thermal conductivity to improve thermal conductivity through a stator core to optimize cooling efficiency.

In general, the induction generator has a structure including a stator (Stator) is fixed to the inside of the frame and a rotor (Rotor) to induce the alternating current while rotating in the center of the stator.

FIG. 5 is a cross-sectional view illustrating the entire structure of a conventional induction generator, and FIG. 6 is a cross-sectional view of the induction generator cut by the cutting line B-B of FIG. 5. 7 is a structural diagram showing a sheet structure of the stator iron core of FIG. 5, and FIG. 8 is a sectional view of a frame on which the stator iron core of FIG. 5 is supported.

Referring to these drawings, the conventional induction generator is largely composed of a rotor and a stationary body, the rotor is a rotor core (102), the shaft 108 constituting the axis of rotation and the internal air flows It consists of an outer fan 109 for cooling the fan 110 and the stator iron core 101. On the other hand, the stationary body is composed of a load side bearing 106 and a load side end shield 104, and a half load side bearing 105 and a half bottom end shield 107, which supports the rotating body to rotate, and generates a magnetic force It consists of a stator iron core (101).

The conventional stator core 101 is formed with a slot 101a to insert a stator coil into a circular thin silicon steel sheet as shown in FIG. 7, and the conventional frame 103 is shown in FIG. 8. As described above, the inner diameter of the frame 103 is processed to the outer diameter of the stator iron core 101 so that the stator iron core 101 can be inserted.

The induction generator transfers the heat generated from the stator iron core 101 to the frame 103, and the heat generated to the frame 103 conducts heat to the atmosphere through the outer shell and the cooling fins of the frame 103. Have In addition, the conventional induction motor has the same structure as the conventional induction generator described above.

However, the conventional induction generator and induction motor structure as described above has a problem in that the thermal conductivity is lowered by forming an air layer between the stator core and the frame.

Accordingly, an object of the present invention is to provide an induction generator having a stator iron core with improved thermal conductivity to improve the thermal conductivity by configuring the stator iron core and the frame as a heat source so that there is no air layer between the stator core and the frame. It is.

It is another object of the present invention to provide an induction generator having a stator iron core with improved thermal conductivity such that an air hole is installed in the rotor iron core and an internal air guide is installed so that smooth flow of internal air can be achieved.                         

In order to achieve the above object, an induction generator having a stator iron core having improved thermal conductivity according to the present invention has a slot into which a stator coil is inserted into an inner diameter side of a yoke, and an outer diameter side of the stator coil. A stator iron core having a concave-convex cooling fin formed in place of a frame for thermally conducting heat generated to the outside; A rotor iron core which is rotated together with the shaft in the stator iron core and has a plurality of air holes so that internal air flows around the shaft; A rotor air guide installed to flow internal air generated by the rotation of the rotor bar through the air hole of the rotor iron core; An enclosure installed at an outer diameter of the stator iron core to protect the stator iron core from external impact and foreign matter; An outer fan cover installed at an upper end of the half load side bearing of the shaft and connected to the half load side of the enclosure; The outer fan is installed inside the outer fan cover and is provided with an outer fan installed so that external air flows between cooling fins of the stator iron core by generating air flow by rotation.

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

1 is a cross-sectional structural view showing the overall structure of the induction generator according to the present invention, Figure 2 is a cross-sectional view of the induction generator cut by the cutting line A-A of FIG. 3 is a structural diagram showing a sheet structure of the stator iron core of FIG. 1, and FIG. 4 is a cross-sectional view of an enclosure protecting the stator iron core of FIG. 1.

Referring to these drawings, the induction generator (M) according to the present invention is largely composed of a rotor and a stationary body, the rotor is a rotor core 13 and the shaft 23 constituting the axis of rotation thereof ) And an external fan 21 for cooling the stator iron core 11. On the other hand, the stationary body is composed of a load side bearing 19 and the load side end shield 17, and the half load side bearing 18 and the half load side end shield 16 to support the rotating body to generate the rotational force, It consists of a stator iron core (11).

The load side bearing 19 and the half load side bearing 18 are installed to smoothly rotate the shaft 23 constituting the axis of the rotating body, and the load side end shield 17 and the half load side end shield 16 are internal. It is installed to isolate and seal the stator coil 12 and the inside of the outside.

As shown in FIG. 3, the stator iron core 11 is formed with a slot 32 into which the stator coil 12 is inserted at an inner diameter side based on the yoke, and generated at the stator coil 12 at an outer diameter side. A concave-convex cooling fin 31 is formed in place of a frame of a conventional induction generator that effectively conducts heat generated to the outside. At this time, the stator iron core 11 is formed by laminating a thin silicon steel sheet having a shape in which a slot 32 is formed on the inner diameter side and a plurality of uneven cooling fins 31 are formed on the outer diameter side.

The stator iron core 11 has the slot 32 installed on the inner diameter side and the cooling fins 31 installed on the outer diameter side at the same angle and the same quantity, and at this time, cooling on the outer diameter side for installing the enclosure 20. The pin 31 is removed. In the embodiment of the present invention, as shown in Figures 2 and 3, but partially removed all four cooling fins 31, but the number and location is not limited.                     

The outer diameter of the stator iron core 11 in which the cooling fin 31 is formed on the outer diameter side is provided with an enclosure 20 as shown in FIG. 4 to protect the stator iron core 11 from external impact and foreign matter.

The rotor iron core 13 is installed inside the stator iron core 11, and the rotor iron core 13 rotates inside the stator iron core 11 together with the shaft 23 constituting the rotating shaft. In addition, a plurality of air holes 41 are formed in the rotor iron core 13 so that internal air generated by the rotation of the rotor bar 14 about the shaft 23 flows.

Rotor air guides 15 are installed at both ends of the air hole 41 of the rotor iron core 13 so that internal air generated by the rotation of the rotor bar 14 flows through the air hole 41. .

The outer fan cover 22 is connected to the half load side of the enclosure 20 so as to protect the outer fan 21 installed therein at the upper end of the half load side bearing 18 of the shaft 23.

The outer fan 21 is installed in the outer fan cover 22 to generate air flow by rotation so that the external air flows between the cooling fins 31 of the stator iron core 11.

Induction generator (M) having the configuration as described above is the air flow is generated by the pressure difference generated by the rotation of the external fan 21, when the air flow occurs the air outside the induction generator (M) covers the outer fan (22) flows into the interior. The external air introduced into the outer fan cover 22 is passed through between the uneven cooling fins 31 formed on the outer diameter side of the stator iron core 11, and the stator iron core generated by the induction generator M is driven ( The heat of 11) is directly cooled.

On the other hand, the internal air generated by the rotation of the rotor bar 14 is provided to the rotor core 13 along the rotor air guide 15 provided at the ends of both air holes 41 of the rotor iron core 13. The heat of the rotor iron core 13 is cooled while flowing through the formed air hole 41.

Therefore, the induction generator (M) according to the present invention is provided with a cooling fin 31 of the concave-convex shape in the stator iron core 11, which is a heating source, in place of the conventional frame of the air layer between the conventional stator iron core 11 and the frame. Formation can solve the problem of low thermal conductivity. In addition, by installing the air hole 41 and the rotor air guide 15 in the rotor iron core 13, the internal air generated by the rotation of the rotor bar 14 can be smoothly flow.

What has been described above is just one embodiment of the induction generator having a stator iron core with improved thermal conductivity according to the present invention, but the above description is limited to the induction generator, but is applicable to an induction motor having the same structure as the induction generator Do. In addition, anyone of ordinary skill in the art to which the present invention belongs will have a technical spirit of the present invention to the extent that various modifications can be made.

As described above, the induction generator having a stator iron core with improved thermal conductivity has the following effects.

First, there is an effect that can improve the thermal conductivity through the stator core by eliminating the heat resistance increase factor by the air layer between the frame and the stator core without using the frame.

Second, by forming an air hole in the rotor iron core so that the internal air flows through the air hole of the rotor iron core, there is an effect that can prevent partial overheating due to stagnation of the internal air.

Third, because the frameless structure is easy to maintain the product, there is an advantage that can optimize the volume of the product.

Claims (2)

A stator iron core having a concave-convex cooling fin formed in place of a frame in which a stator coil is inserted into the inner diameter side of the yoke, and a heat conduction amount of heat generated from the stator coil to the outer diameter side. ; A rotor iron core rotated together with the shaft in the stator iron core and having a plurality of air holes so that internal air flows around the shaft; A rotor air guide installed to flow internal air generated by the rotation of the rotor bar through the air hole of the rotor iron core; An enclosure installed at an outer diameter of the stator iron core to protect the stator iron core from external impact and foreign matter; An outer fan cover installed at an upper half bearing side of the shaft and connected to a half load side of the enclosure; And An induction generator having a stator iron core having improved thermal conductivity, characterized in that an outer fan is installed inside the outer fan cover and generates air flow by rotation to allow external air to flow between cooling fins of the stator iron core. The method according to claim 1, wherein the stator iron core, Induction generator having a stator iron core with improved heat conduction, characterized in that the cooling fins of the outer diameter side is removed for the installation of the enclosure in the state that the slots on the inner diameter side and the cooling fins on the outer diameter side are installed at the same angle and the same quantity.

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