KR0131738Y1 - Dielectric coating apparatus of an electric rotor - Google Patents

Abstract

The present invention relates to an insulation coating machine of the motor rotor, and more specifically to the insulation layer of the rotor to increase the insulation effect by the coating layer attached to the surface of the rotor iron core without bubbles by the electrostatic spray method.

That is, the conductive plate 12 having a plurality of coils attached to the intermediate support 11 of the lower tank 10 attached to the intermediate support 11 at a predetermined interval is rolled out to be connected to the power line 15 of the high voltage generator 14 and the conductive plate. (12) a powder supply part (A) and an upper tank (20) configured to supply a powder (17) provided with an air filter (16) on the upper side to inject the powder particles into the air introduced from the lower air inlet (18). A powder recovery part C for forming the guide grooves 31 at both lower ends of the side 30 and the inlet port 33 above the recovery chamber 32 to recover the powder particles with the recovery device 34; It is an insulation coating machine for a motor rotor, characterized in that it is provided with a coating screw (B) for rotating the rotor by installing a transfer screw 20 between A) and the powder recovery portion (C).

Description

Insulation Coating Machine of Motor Rotor

1 is a cross-sectional view of the configuration of the present invention.

2 is a side cross-sectional view of the present invention.

3 is a plan view of the high-voltage conductive plate of the present invention.

4 is a side view of the high-voltage conductive plate of the present invention.

Figure 5 is a side view of the rotor transfer state according to the present invention.

6 is a perspective view showing the coating of the rotor according to the present invention.

* Explanation of symbols for main parts of the drawings

A: Powder supply part B: Coating transfer part

C: powder recovery part D: powder particles

10: lower jaw 11: intermediate support

12: conductive plate 13: coil

14 high voltage generator 15 power line

16 air filter 17 supply chamber

18: air injection port 20: transfer screw

21: rotor 22: rotor shaft

23: supply part 24: detection sensor

30: upper tank 31: guide groove

32: recovery chamber 33: intake vent

34: recovery device

The present invention relates to an insulation coating machine of the electric rotor, and more specifically to the insulation layer of the rotor by the electrostatic spray method to enhance the insulation effect with a coating layer attached to the surface of the rotor core without bubbles.

In general, in the motor, the coil is wound several times on the rotor to obtain rotational power, and a thick paper is sandwiched between the metal rotor and the coil to provide insulation.

This insulation work requires a lot of time because the insulation paper must be fitted, especially in the case of a small rotor, it is difficult to insert, but also had a weak defect in the heat resistance and pressure resistance.

The present invention relates to an insulating coating machine that can form a coating layer by the electrostatic spraying method of the insulating portion of the motor rotor in order to solve this problem will be described in detail by the accompanying drawings as follows.

The coater body is composed of a powder supply part (A), a coating transfer part (B) of the rotor, and a powder recovery part (C), respectively.

The powder supply part A horizontally crosses the conductive plate 12 attached with a plurality of coils 13 separated from the intermediate support 11 of the lower tank 10 at predetermined intervals, thereby supplying power lines to the high voltage generator 14. (15) and the air filter (16) in the proximal position above the conductive plate 12 to settle the powder particles (D) to a predetermined height and then the powder particles by the air introduced from the lower air injection port (18) It is sprayed into the roll upper feed chamber 17 by (+) pressure.

The coating conveying part (B) rotates the rotor shaft (22) placed on the conveying screw (20) by installing the conveying screw (20) between the powder supply part (A) and the powder recovering part (C). In addition, the ground state.

The powder recovery part C forms guide grooves 31 at both ends of the longitudinal direction of the upper tank 30, and forms an inlet 33 at the upper side of the recovery chamber 32 to collect the powder particles by the recovery device 34. Is collected and sent to the supply chamber 17.

And one side of the supply chamber 17 is provided with a detection sensor 24 for detecting the amount of powder particles and a supply port 23 for supplying the appropriate amount of powder particles.

In the drawing, reference numeral 25 denotes the rotor shaft auxiliary cap and 26 an auxiliary storage port.

According to the present invention, the powder particles (D) to be coated are first placed in the air filter 16 of the lower tank 10 at a predetermined height, and then the coating machine is operated. As shown in FIG. The rotor shaft 22 placed in the) is sent to the coating machine exit direction while rotating to the left.

In addition, in the powder supply unit (A), the air flowing in from the air injection port 19 of the lower tank 10 disperses the powder particles (D) placed in the air filter 16 to the top, and also to the high voltage generator 14 Since the powder particles are charged and made into a cloudy state by the high voltage generated from the connected conductive plate 12, they are electrically adsorbed to the iron core surface of the rotor 21 which is rotated along the transfer screw 20 on the upper side.

At this time, since the rotor shaft 22 is grounded, the charged powder particles are adsorbed, and the unsorbed powder particles are recovered by the recovery device from the recovery chamber 22 through the inlet port 33 and then supplied to the supply chamber 17. In addition, the powder particles are supplied as much as the amount of powder particles adsorbed on the surface of the iron core of the rotor 21.

In addition, the conductive plate 12 may be used by attaching a plurality of separated coils 13 at predetermined intervals, thereby generating a more effective high voltage.

In this way, the rotor 21 is rotated by the transfer screw 20 in the coating transfer part B, disperses the powder particles to the top with air ionized by the air filter 6, and charges the battery at a high voltage. The powder particles adsorbed on the surface of the rotor core and not adsorbed are recovered and reused by the recovery device 34, so that the coating operation is easily and quickly performed, and the rotor core surface forms a uniform coating layer, thereby increasing the insulation effect. And productivity is improved.

Claims (1)

The conductive plate 12 having a plurality of coils attached to the intermediate support 11 of the lower tank 10 attached to the intermediate support 11 at a predetermined interval is rolled out to be connected to the power line 15 of the high voltage generator 14 and the conductive plate 12 Powder supply unit (A) and the upper tank (30) to form a supply type (17) having an air filter 16 installed on the upper side to inject the powder particles into the air introduced from the lower air injection port (18) A powder collecting part (C) and a powder supplying part (A), which form guide grooves 31 at both lower ends of the upper part, and form an inlet port 33 above the recovery chamber 32 to recover the powder particles to the recovery device 34. And a coating screw (B) for rotating the rotor by installing a conveying screw (20) between the powder recovery part (C) and the powder collecting part (C).