JP2011114922A - Dc brushless motor and air conditioner employing the same - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem with a conventional DC brushless motor configuration, wherein a conductive member and work for sticking the conductive member are required to thereby increase cost since a load-side bracket is connected to an anti-load-side bracket by the conductive member stuck onto a side of a motor. <P>SOLUTION: The motor includes a rotor 5 freely rotatably held via bearings 7, 9 and a rotating shaft, the load-side and anti-load-side brackets 8, 10 holding the bearings, a stator 1 of which coil 3 is formed from a mold resin 4, and vibration-proof rubbers 11, 12 where a conductive material is mixed with the load-side bracket and the anti-load-side bracket. The motor is fixed by a fixing cover composed of the conductive material, and the load-side bracket is connected to the anti-load-side bracket by the vibration-proof rubbers mixed with the conductive material and the fixing cover 13 composed of the conductive material, thus obtaining an equivalent effect with a low-cost configuration. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an electrolytic corrosion preventing structure for a DC brushless motor.

  As shown in FIG. 2, a conventional DC brushless motor of this type has a finished body in which a stator 101 is integrally molded, and a rotor comprising a magnet 102, a shaft 103, a bearing A104, and a bearing B105. -It has a finished product. The load-side bearing A104 is supported by the load-side bracket A106 and fixed to the finished stator body. The anti-load side bearing B105 is supported by the anti-load side bracket B107, and is fixed to and integrated with the finished stator. The load side bracket A106 and the anti-load side bracket B107 are connected by a conductive member.

JP 2007-20348 A

  However, in the configuration as described above, the load side bracket 106 and the anti-load side bracket 107 are connected by the conductive member attached to the side surface of the motor, and the conductive member and the conductive member attaching work are required, which increases the cost.

  The present invention solves the above-mentioned conventional problems. A vibration-proof rubber mixed with a conductive material is attached to a load side bracket and an anti-load side bracket, and the motor is mounted by a fixed cover made of a conductive material. By fixing, the load-side bracket and the anti-load-side bracket are connected by the anti-vibration rubber mixed with the conductive material and the fixed cover made of the conductive material. Another object of the present invention is to provide a motor and a structure for preventing galvanic corrosion that do not generate galvanic corrosion even when driven by a high-voltage PWM method.

  In order to solve the above-mentioned conventional problems, a DC brushless motor of the present invention includes a rotor that is rotatably held via a bearing and a rotating shaft, a load side and an anti-load side bracket that holds the bearing, A stator whose coil portion is molded from mold resin, vibration-proof rubber mixed with conductive material is attached to the load-side bracket and anti-load-side bracket, and the motor is fixed by a fixed cover made of conductive material By connecting the load side bracket and the anti-load side bracket with the anti-vibration rubber mixed with the conductive material and the fixed cover made of the conductive material, an equivalent effect can be obtained by an inexpensive configuration. It is possible to provide a motor and a galvanic corrosion prevention structure that do not generate galvanic corrosion even when driven by a high voltage PWM method.

In the DC brushless motor of the present invention, the vibration-proof rubber mixed with a conductive material is attached to the load side bracket and the anti-load side bracket, and the motor is fixed by a fixing cover made of a conductive material. By connecting the load side bracket and the anti-load side bracket with the anti-vibration rubber mixed with the conductive material and the fixed cover made of the conductive material, the same effect can be obtained by the low cost configuration. Even the driving method does not cause electric corrosion.

Partial sectional view of the motor according to the first embodiment of the present invention. Sectional view of a conventional DC brushless motor

  According to a first aspect of the present invention, there is provided a rotor that is rotatably held via a bearing and a rotating shaft, a load side and anti-load side bracket that holds the bearing, a stator in which a coil portion is formed of a mold resin, and the load A motor made of anti-vibration rubber mixed with conductive material attached to the side bracket and anti-load side bracket is fixed with a fixed cover made of conductive material, so that anti-vibration mixed with conductive material By connecting the load side bracket and the anti-load side bracket with a fixed cover made of rubber and a conductive material, the same effect can be obtained with an inexpensive configuration.

  According to the second aspect of the present invention, the anti-vibration rubber can be connected with an inexpensive structure by forming the carbon-containing material and the fixed cover with metal.

  The third invention is more effective when the motor is a high-voltage PWM DC brushless motor.

  In the fourth aspect of the present invention, it is preferable that the motor according to any one of the first to third aspects is used for an air conditioner. In recent years, high-efficiency PWM systems have been the mainstream of air conditioner motors due to higher efficiency, and the effects can be further exhibited by adopting the motors of the inventions 1 to 3 described above.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings. Note that the present invention is not limited to the embodiments.

(Embodiment 1)
FIG. 1 shows a partial cross-sectional view of the motor of the present embodiment.

In the motor of this embodiment, an insulating layer is formed by applying an insulating resin 2 to a stator 1 in which steel plates are laminated, and a coil 3 is wound around the insulating layer. The finished stator and the load side metal bracket 8 are integrally molded by the mold resin 4.
A rotor 5 is accommodated on the inner peripheral side of the formed stator completed body. A metal rotating shaft 6 is passed through the rotor 5 and is rotatably fixed to a load side metal bracket 8 via a load side bearing 7 of the rotor 5. The metal rotating shaft 6 on the side opposite to the load of the rotor 5 is attached to the metal bracket 10 on the side opposite to the load via an anti-load side bearing 9. The anti-load side metal bracket 10 is attached to the finished stator.

Anti-vibration rubber A11 and anti-vibration rubber B12 mixed with carbon-based material are attached to the load-side metal bracket 8 and the anti-load-side metal bracket 10, and carbon-based material is mixed with the metal fixing cover 13 Anti-vibration rubber A11 and anti-vibration rubber B12 are fixed.
In this way, the load-side metal bracket 8 and the anti-load-side metal bracket 10 are connected by the anti-vibration rubber A11, the anti-vibration rubber B12 mixed with the carbon material, and the metal fixing cover 13, thereby making the load-side metal bracket. The bracket 8 and the non-load-side metal bracket 10 are at the same potential, so that the circulating current does not flow and no electrolytic corrosion occurs.

(Embodiment 2)
The motor of the first embodiment can be more effective if it is a high-voltage PWM DC brushless motor. In recent years, when control is performed at a high frequency in order to realize high efficiency by the high-voltage PWM method, a potential difference is generated between the load side and the anti-load side, and a circulating current flows to cause an erosion phenomenon.

  By connecting the bracket on the load side and the stator and the bracket on the anti-load side, the potential becomes the same, and the circulating current does not flow and no galvanic phenomenon occurs.

(Embodiment 3)
The motor according to the first embodiment is preferably used as a fan motor for an air conditioner. In recent years, high performance of air conditioners has been advanced and high output of motors is required, and a high pressure PWM method is used. Therefore, when the motor of the first embodiment is used as a fan motor for an air conditioner and a structure for preventing electric corrosion, the effect of the present invention is more remarkably exhibited.

  As described above, the motor and the electric corrosion prevention structure according to the present invention are provided with the anti-corrosion rubber mixed with the conductive material on the load side bracket and the anti-load side bracket, and the fixed cover made of the conductive material. By fixing the motor, the same potential is obtained by connecting the load-side bracket and the anti-load-side bracket with a vibration-proof rubber mixed with a conductive material and a fixed cover made of the conductive material. With this configuration, since the circulating current does not flow and no galvanic phenomenon occurs, it is suitable for the use of a motor of an air conditioner that requires high efficiency.

DESCRIPTION OF SYMBOLS 1 Stator 2 Insulation resin 3 Coil 4 Mold resin 5 Rotor 6 Metal rotating shaft 7 Load side bearing 8 Load side metal bracket 9 Anti load side bearing 10 Anti load side metal bracket 11 Anti-vibration rubber A
12 Anti-vibration rubber B
13 Metal fixed cover

Claims (4)

A rotor that is rotatably held via a bearing and a rotating shaft, a load side and anti-load side bracket that holds the bearing, a stator in which a coil portion is formed of a mold resin, and the load side bracket and the anti-load side A motor made of vibration-proof rubber mixed with a conductive material attached to a bracket is fixed by a fixed cover made of a conductive material, so that the load-side bracket and the anti-vibration can be separated by the vibration-proof rubber and the fixed cover. A DC brushless motor characterized by connecting a load side bracket. 2. The DC brushless motor according to claim 1, wherein the anti-vibration rubber is made of a carbon-containing material and the fixed cover is made of metal. 2. The DC brushless motor according to claim 1, wherein the motor is a high voltage PWM system. An air conditioner using the DC brushless motor according to any one of claims 1 to 3.

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