JP2010110029A - Mold motor - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To solve the problem that, in a mold motor in which a stator and a circuit board are resin-molded, it has been necessary hitherto to form a hole at the circuit board by only an area of a space ϕA for the insertion of a bearing when inserting the bearing into the mold motor from the inside of the motor, a mounting area of an electronic component is narrowed, and thus the freedom of a layout of wiring is reduced. <P>SOLUTION: In the mold motor 1 in which the stator 2 and the circuit board 3 are molded by using resin, the mold motor is constituted in such a manner that a bearing housing 11 is opened toward the outside direction of the motor, the bearing 7 can be attached to the motor from the outside, and the circuit board 3 is arranged up to a part immediately below the bearing housing at the side of a reverse insertion port of a rotor. <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

  The present invention relates to a molded motor that is used in a fan motor for an air conditioner and the like and covers parts such as a stator with resin.

  A mold motor that covers a stator and a circuit board with a resin member is conventionally known. (See Patent Document 1)

Since the molded motor as described above covers the stator and the circuit board with resin, the molded motor is excellent in waterproofness and insulation, and has an advantage that it can be manufactured at a lower cost than using a steel plate frame.
JP 2000-14071 A

  However, if the circuit board is arranged at a position as shown in FIG. 4, a hole for inserting the bearing is formed in the center of the circuit board in order to insert the bracket and the bearing on the side opposite to the rotor insertion port. There is a need.

  However, providing such holes in the circuit board reduces the mounting area on which electronic components can be mounted, limiting the number and size of electronic components to be mounted, and limiting the wiring layout. It was.

  Also, in order to secure the mounting area of the circuit board, there is a method of arranging outside the bearing housing on the anti-rotor insertion port side, but this method increases the axial length of the motor. There is a problem that the crossover line from the substrate to the substrate becomes long, and it is desired to arrange the substrate at the conventional position as much as possible.

  In view of the above-described conventional problems, the present invention provides a configuration for ensuring a large mounting area of a substrate without changing the size of the entire motor.

  The invention according to claim 1 is a stator having a winding wound around an iron core, a rotor disposed on an inner periphery of the stator, to which a rotating shaft is attached, and a bearing that slides and supports both sides of the rotating shaft. And a bearing housing that houses the bearing, and a circuit board that includes various electronic components, the stator and the circuit board are covered with resin, and a motor motor frame is used. The molded motor is characterized in that the bearing is attached from the outside by being opened, and the circuit board is arranged up to the bottom of the bearing housing on the anti-rotor insertion port side and covered with resin. It is to provide.

  According to a second aspect of the present invention, there is provided the molded motor according to the first aspect, wherein a bearing bracket made of a steel plate is inserted into the bearing housing on the anti-rotor insertion port side and the bearing is fitted. is there.

  A third aspect of the present invention provides the molded motor according to the first aspect, wherein a bearing housing of the counter-rotor insertion side opening is formed integrally with the resin frame, and a bearing is fitted therein. It is.

  The configuration of the molded motor of the present invention can ensure a large mounting area for electronic components without changing the size of the entire motor. Thereby, the degree of freedom in the number and size of electronic components and the layout of wiring is increased, and a motor with excellent controllability can be provided.

  An embodiment of the present invention will be described with reference to FIGS. FIG. 1 is a cross-sectional view of the motor of the present invention. FIG. 2 is an enlarged view of the counter-rotor insertion port side. FIG. 3 is a diagram of another embodiment.

(Configuration of this embodiment)
As shown in FIG. 1, a motor 1 according to the present invention includes a stator 2 in which a winding is wound around a cylindrical iron core, and a circuit board 3 disposed in the vicinity of the stator 2 that is molded with resin to form a motor frame 4. Is formed. Although not shown, the stator 2 and the circuit board 4 are connected by a jumper, and the energization of the stator 2 is controlled by a control signal from an electronic component on the circuit board 4, so that the motor 1 Is driven.

  The rotor 5 is provided with a magnet around a circular rotor yoke, and a rotating shaft 6 is attached to the center. As described above, in addition to the configuration in which the magnet is arranged around the yoke, a configuration in which the rotating shaft 6 is attached by a resin magnet may be used. Further, both sides of the rotating shaft 6 are slidably supported by bearings 7 and 8, and the bearing 7 on the side opposite to the rotor insertion port is on the bearing bracket 9 and the bearing 8 on the rotor insertion port side is on the bearing bracket 10, respectively. The fitting is fixed.

  1 and 2, the circuit board 3 is arranged on the side opposite to the rotor insertion port of the stator 2. The circuit board 3 is formed with a hole 12 through which the rotation shaft 6 is inserted at the center of a substantially circular substrate. The diameter of the hole is slightly larger than the diameter of the rotation shaft 6. The circuit board 3 is integrally covered with the motor frame 4 with resin, and the non-rotor insertion port side is completely partitioned except for the shaft hole.

  A bearing housing 11 is formed on the outer side where the substrate is embedded toward the outside of the motor. A metal bearing bracket 9 is attached to the bearing housing 11 and the bearing 7 is fitted therein.

  With the above configuration, the area of the circuit board is increased by φA while the axial length of the motor is the same as that of the conventional configuration.

(Assembly method of this embodiment)
A stator 2 having a coil wound around an iron core and a circuit board 3 are set in a molding die, and these components are molded with resin by injection molding. The molded motor frame 4 is formed in a concave shape, and a shaft hole 12 is formed in the center. A bearing housing 11 that houses a bearing is formed outside the vicinity of the shaft hole 12 and a bearing bracket 9 is attached. The bearing bracket 9 may be attached after the mold frame 11 is formed, but may be set in a molding die and insert-molded when molding.

  Next, after inserting the rotor 5 from the rotor insertion port of the motor frame 4 and inserting the rotating shaft 6 into the shaft hole 12, the bearing 7 is attached and the rotating shaft 6 is slidably supported. On the opposite side, a metal bearing bracket 10 is inserted through the rotary shaft 6 and is fixed to the motor frame 4 by being fitted or screwed. And by attaching the bearing 8, the rotating shaft 6 is slidably supported.

(Other examples)
In FIG. 1, the bearing bracket 9 is embedded, but the bearing bracket 9 may be omitted as shown in FIG. 3 unless the accuracy with the bearing is strictly required. Since there is no bearing bracket 9, an inexpensive one can be provided.

  Moreover, a bearing can be fixed reliably by attaching the retaining ring after attaching the bearings 7 and 8.

  Further, in the present invention, since the bearing is attached toward the outside, a lid or the like may be provided in an environment where dust or dust easily enters the bearing.

Sectional view of the molded motor of the present invention Enlarged view of the anti-rotor insertion hole Sectional view of another embodiment of the present invention Cross section of conventional mold motor

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Motor 2 Stator 3 Circuit board 4 Mold part 5 Rotor 6 Rotating shaft 7, 8 Bearing 9, 10 Bearing bracket 11 Bearing housing 12 Shaft hole

Claims (3)

A stator with windings on the stator core;
A rotor disposed on the inner periphery of the stator and having a rotation shaft attached thereto;
A bearing for slidingly supporting both sides of the rotating shaft;
A bearing housing that houses the bearing;
A circuit board on which various electronic components are mounted,
In the molded motor that covers the stator and the circuit board with a resin and forms a motor frame,
The bearing housing is opened from the outside of the motor, so that the bearing is attached from the outside.
The molded motor, wherein the circuit board is arranged up to a position directly under the bearing housing on the side opposite to the rotor insertion port and is covered with a resin.   The molded motor according to claim 1, wherein a bearing bracket made of a steel plate is inserted into the bearing housing on the side opposite to the rotor insertion port, and the bearing is fitted.   The molded motor according to claim 1, wherein a bearing housing of the counter-rotor insertion side opening is formed integrally with the resin frame, and a bearing is fitted therein.