JPH0510525Y2 - - Google Patents

Description

[Detailed Description of the Invention] (Industrial Application Field) The present invention relates to a small watch motor used in a quartz crystal watch mechanism.

(Prior Art) A conventional rotor used in a small watch motor has a configuration shown in FIG. This first
In the conventional example, a rotor shaft 1 with an irregular cross section is inserted into an irregular hole 10a formed in the center of a permanent magnet 10 of the rotor.
At the same time, insert the entire permanent magnet into the cylindrical part 11a with the lower end opening formed integrally with the rotor shaft, and insert the permanent magnet inward toward the lower end opening edge of the cylindrical part. The formed locking pawl 11b prevents the permanent magnet 10 from coming off the cylindrical portion 11a (for example, see Japanese Utility Model Application Publication No. 57-27771).

In addition, as a second conventional example, a pinion and a disk portion are integrally formed on the rotor shaft, a fitting stepped portion is formed on the disk portion, and a permanent magnet is mounted on the upper surface of this fitting step. There is also one in which the lower end surfaces are fitted and fixed by a method such as adhesive, and the stator is opposed to the exposed outer peripheral surface of the permanent magnet (for example, Japanese Utility Model Publication No. 138318/1983).

Furthermore, as a third conventional example, there was one in which a protrusion was integrally formed on a permanent magnet, and the permanent magnet and rotor shaft were molded by two-color molding (for example, Publication No. 67022).

(Problems to be Solved by the Invention) However, according to the rotor of the first conventional example, since the outer periphery of the permanent magnet 10 is covered with the cylindrical part 11a, there is a gap between the permanent magnet 10 and the stator 12. The cylindrical portion 11a is interposed in the gap Va of the motor, so that the gap Va has to become larger than necessary, which reduces the motor efficiency.

Further, in the second conventional example, an adhesive or the like is required to fix the permanent magnet to the fitting stepped portion, and the work is complicated.

Furthermore, in the third conventional example, the mold is complicated due to the two-color molding, which has the disadvantage of increasing manufacturing costs.

Therefore, the main purpose of the present invention is to provide a small motor for a watch that can minimize the gap between the stator and the permanent magnet, thereby providing excellent drive efficiency.

(Means for Solving Problems) The present invention is characterized by a rotor consisting of a rotor shaft supported between bearings on two base plates and a donut-shaped permanent magnet through which the rotor shaft passes. , a stator magnetically coupled to the permanent magnet, and a tipping prevention protrusion for preventing the rotor from tipping over when the rotor is assembled, and the rotor shaft includes a pinion, a short cylindrical portion, and a tip. , a plurality of locking portions protruding inward from the tip of the cylindrical portion are integrally formed, and the permanent magnet is fitted with the cylindrical portion protruding outward from the edge on the pinion side. A matching ring-shaped protrusion is integrally formed,
The protruding portion is engaged with the locking portion of the cylindrical portion at a position close to the pinion of the rotor shaft, and the stator is spaced apart from the cylindrical portion by a predetermined distance on the side opposite to the pinion. The tip of the protrusion is provided on the base plate of the rotor shaft on the opposite side of the pinion, and the tip of the protrusion is directly opposed to substantially the center of the outer circumferential surface of the permanent magnet. It is located close to the outer periphery of the cylindrical portion of the rotor.

(Function) Therefore, the locking portion of the cylindrical portion is locked in a snap-fit manner at a position close to the pinion of the rotor shaft, so the outer periphery of the permanent magnet fixed to the rotor shaft is exposed and permanently attached. The magnets directly oppose the magnetic pole faces of the stator, allowing the gap between the two to be set small.

When the rotor is dropped into the bearing on one of the base plates, the fall prevention protrusion prevents the rotor from falling, and when the other base plate is attached, the rotor can be automatically assembled into a predetermined position.

(Example) Hereinafter, an example of the present invention will be described based on FIGS. 1 and 2.

Bearings 1a and 2a are formed on the upper plate 1 and the middle plate 2, respectively, in opposing positions, and the upper and lower ends of the rotor shaft 3 are rotatably supported in both bearings, respectively. The rotor shaft 3 is integrally formed with a pinion 3a, a short cylindrical portion 3b, and a locking portion (claw) 3c that projects inward from the lower surface of the cylindrical portion. Four locking portions 3c protrude from the lower surface of the cylindrical portion 3b at equal intervals.

A non-circular center hole 4a is bored in the center of the permanent magnet 4, and a ring-shaped protrusion 4b that protrudes outward is formed at the upper edge.

The rotor shaft 3 passes through the center hole 4a of the permanent magnet 4 and is non-rotatably mounted thereon. It surrounds only the protrusion 4b. The locking portion 3c of the cylindrical portion 3 locks onto the lower surface of the protrusion 4b of the permanent magnet 4 in a snap-fit manner.
This prevents the permanent magnet 4 from detaching. stator 5
is the permanent magnet 4 at the lower position of the cylindrical part 3b.
are directly opposed to each other with a gap V on their outer peripheral surfaces.

Further, on the middle plate 2 located on the opposite side of the pinion 3a of the rotor shaft 3, four projections 2b for preventing the rotor from falling are integrally formed at equal intervals, and the tips of the projections have a large diameter. It is located near the outer periphery of the cylindrical portion 3b of the rotor shaft 3.

Therefore, when assembling the rotor, the lower end of the rotor shaft 3 is inserted into the bearing 2a of the middle plate 2, and even when the upper plate 1 is not yet installed, the cylindrical part 3b of the rotor shaft has a protrusion to prevent it from falling. 2b and can stand up without falling over a predetermined amount, so when the upper plate 1 is pressed from above and installed, the upper end of the rotor shaft 3 is guided by the tapered surface of the bearing 1a of this upper plate and automatically Since it is inserted automatically, assembly work can be automated and streamlined. In addition, 6 is a lower board.

Further, in the above embodiment, the locking portion 3c that locks the protrusion 4b of the permanent magnet 4 is provided protrudingly on the lower surface of the cylindrical portion 3b to prevent the permanent magnet 4 from detaching. , this cylindrical portion 3b is not limited to a literal cylindrical shape; for example, a plurality of arms along the outer peripheral surface of the permanent magnet 4 are integrally formed with the rotor shaft 3, and the arms are formed integrally with the rotor shaft 3. A locking portion is provided protrudingly at the tip, and this locking portion is connected to the protrusion 4 of the permanent magnet 4.
It also includes one configured to lock b.

(Effects of the invention) This invention has the advantage that even if a structure is adopted in which the permanent magnets are attached to the rotor shaft using a snap-fit method, the outer peripheral surface of the permanent magnets is exposed and the stator and permanent magnets can be directly opposed. , the gap between the permanent magnet and the stator can be narrowed, and a highly efficient motor can be provided.

Furthermore, since the protrusions for preventing the rotor from collapsing are closely opposed to the large-diameter cylindrical portion, it is easy to incorporate the rotor shaft into the base plate, which is effective in preventing the rotor from collapsing.

[Brief explanation of the drawing]

FIG. 1 is a sectional view, FIG. 2 is a sectional view taken along the line of FIG. 1, and FIG. 3 is a sectional view of a conventional example. 1, 2...Main plate, 1a, 2a...Bearing, 2b...
... Protrusion for preventing rotor from falling, 3 ... Rotor shaft, 3
a... Kana, 3b... Cylindrical part, 3c... Locking part,
4...Permanent magnet, 4b...Protrusion, 5...Stator, V...Gap.

Claims (1)

[Claims for Utility Model Registration] A rotor consisting of a rotor shaft supported between two base plate bearings and a donut-shaped permanent magnet through which the rotor shaft passes, and a stator magnetically coupled to the permanent magnet. and a fall prevention protrusion for preventing the rotor from falling when the rotor is assembled, and the rotor shaft has a pinion, a short cylindrical part, and a tip protruding inward from the tip of the cylindrical part. A plurality of locking portions are integrally formed on the permanent magnet, and a ring-shaped protrusion that protrudes outward from the corner edge side edge and fits into the cylindrical portion is integrally formed on the permanent magnet. The locking portion of the cylindrical portion is engaged with the protrusion at a position close to the pinion of the rotor shaft, and the stator is moved from the cylindrical portion to the side opposite to the pinion. The protrusions for preventing falling are provided on the base plate of the rotor shaft on the opposite side of the pinion; A small motor for a watch, wherein a tip of the protrusion is located close to an outer periphery of the cylindrical portion of the rotor.