The present document is based on Japanese Priority Document JP2002-220889, filed in the Japanese Patent Office on Jul. 30, 2002, the entire contents of which being incorporated herein by reference.
1. Field of the Invention
The present invention relates to a small vibration motor for generating vibrations, which is built in an electronic apparatus, such as a mobile telephone, a PDA and the like, and to a method of manufacturing the same.
2. Description of Related Art
Conventionally, an electronic apparatus such as the mobile telephone, the PDA and the like includes a mechanism of a so-called silent mode to notify an incoming call through vibrations, and an alarm to notify a predetermined time through vibrations, and the like. As a mechanism for generating a vibration, a vibration actuator is built into such an electronic apparatus.
The illustrated vibration motor 104 is a motor with a brush. As shown in
Conventionally, when a motor with a brush is used as the vibration motor, the rotational defect caused by a so-called slit-short can not be made zero. Thus, this is a problem with the reliability of a vibration generation operation.
Also, in view of the internal volume of a portable apparatus and the like, it is naturally desired to have a smaller vibration motor. A motor body can be reduced to, for example, a diameter of about 3.5 mm. However, a problem may occur if the diameter of the motor body is made smaller. That is, the diameter of the weight for generating the rotational unbalanced energy becomes too small to generate enough vibrations, and thus the vibration component decreases. In particular, recently, portable apparatuses, such as the mobile telephone, the PDA and the like tend to be thinned. Accordingly, this causes a problem that fitting a cylindrical vibration motor to such a thinned portable apparatus is difficult.
Further, from the viewpoint of the battery life of a portable apparatus such as the mobile telephone and the like, obviously it is desirable to lower the electric power consumption. However, this has a problem that miniaturization of the motor body brings about increases in the rotational number and the electric power consumption.
Moreover, the assembly of the conventional vibration motor into the electronic apparatus must rely on manpower. Thus, automation thereof is difficult.
Accordingly, there has been a need to provide a smaller vibration motor that may be miniaturized, thinned and automatically assembled into an electronic apparatus and a method of manufacturing the same.
In order to attain the above-mentioned subjects, a small vibration motor according to the present invention is characterized by including: a rotor yoke in which an unbalance weight and a magnet are placed and which is fixed to a shaft; a driving torque-generating coil that is placed on a substrate so as to face the magnet; driving electronic parts placed on the substrate, which includes an integrated circuit composed of non-molded bare chips, supply an alternating current to the driving torque generating coil to rotate the rotor yoke around the shaft; a bottom plate which supports the substrate and to which a radial bearing to which the shaft is engaged is fixed; and a cover for covering the rotor yoke, the driving torque-generating coil and the driving electronic parts, which is adhered to the bottom plate.
Also, as the preferable embodiment, in the small vibration motor, the substrate may be constituted by a flexible substrate, and the driving torque generating coil may be electrically connected to the flexible substrate through three terminals.
Also, as the preferable embodiment, the small vibration motor may include a terminal that is formed on a substrate protruded from the package and engaged with a connector mounted on a motherboard and thereby electrically connected.
Also, as the preferable embodiment, the small vibration motor may include a terminal that is placed in the cover or the bottom and engaged with a socket mounted on a motherboard and thereby electrically connected.
Also, as the preferable embodiment, the small vibration motor may include a land that is formed on a surface of the cover or the bottom in contact with a motherboard and electrically connected to another land formed on the motherboard.
In order to attain the above-mentioned subjects, a method of manufacturing a small vibration motor according to the present invention is characterized by including the steps of: mounting driving electronic parts and a driving torque-generating coil on a board; placing a magnet on a rotor yoke so as to face the driving torque-generating coil, in a rotor composed of the rotor yoke and a shaft; placing an unbalance weight at a part of the rotor yoke; fixing a radial bearing to a bottom plate; installing a bottom plate on which the radial bearing is placed to the substrate; installing the rotor to the radial bearing that is engaged with the shaft; and packaging by covering the substrate, the driving electronic parts and the rotor with a cover, and adhering the cover to the bottom plate.
Also, as the preferable embodiment, the method of manufacturing the small vibration motor may be characterized in that as the driving electronic parts, at least an integrated circuit composed of non-molded bare chips is mounted on the substrate.
Also, as the preferable embodiment, the method of manufacturing the small vibration motor may be designed such that the board is constituted by a flexible substrate and the driving torque generating coil is electrically connected to the flexible substrate through three terminals.
Also, as the preferable embodiment, the method of manufacturing the small vibration motor may include a step of forming a terminal on a substrate protruded from the package, which is engaged with a connector mounted on a motherboard and thereby electrically connected.
Also, as the preferable embodiment, the method of manufacturing the small vibration motor may include a step of placing a terminal, which is engaged with a socket mounted on a motherboard and thereby electrically connected, on the package.
Also, as the preferable embodiment, the method of manufacturing the small vibration motor may include a step of forming a land on a surface in contact with the motherboard of the package, which is electrically connected to another land formed on a motherboard.
In the present invention, the driving electronic parts and the driving torque generating coil are mounted on the board. In the rotor composed of the rotor yoke and the shaft, the magnets are placed so as to face the driving torque generating coil in the rotor yoke. The unbalance weight is placed at a part of the rotor yoke. The radial bearing is fixed to the bottom plate. The bottom plate on which the radial bearing is placed is installed to the board. The shaft is engaged with the radial bearing, and the rotor is also installed on the radial bearing. Moreover, the board, the driving electronic parts and the rotor are covered with the cover. Then, the cover is adhered to the bottom plate to be packaged. Thus, the vibration motor can be miniaturized and thinned. Moreover, it is possible to carry out automatically the manufacturing process for the vibration motor and mounting the motor to an electronic apparatus.
The above and other objects, features and advantages of the present invention will become more apparent from the following description of the presently preferred exemplary embodiments of the present invention taken in conjunction with the accompanying drawings, in which:
An embodiment of the present invention will be described below with reference to the attached drawings.
A. Structure of Small Vibration Motor
Notches 10 are formed at the four corners of the FP coil 1, and the flexible substrate 3 is exposed there. The driver IC 4, passive parts (C, R) 11 and the like are mounted on the notches 10. The flexible substrate 3 is made of polyimide as the base material, and that wiring surface is treated with Cu+Ni+Au.
The shaft 5 is supported by a radial bearing 13 installed to a bottom plate 12, a thrust bearing 14 and a thrust bearing holder 15. The radial bearing 13 is made of sintered metal in which, for example, copper-based, iron-steel-based or iron-based oil is impregnated, and it is the cylindrical shaped member. Incidentally, the radial bearing 13 may be made of resin.
Also, a cover 16 is caulked and soldered and thereby fixed to the bottom plate 12. The top surface of the cover 16 is flat such that the small vibration motor can be assembled (absorbed) by a robot arm and the like when it is mounted onto the motherboard. Also, a part of the flexible substrate 3 is protruded so as to be wired to the motherboard. However, having this protrusion is not the essential condition.
The small vibration motor according to this embodiment, as mentioned above, has the approximate dimension of 8.6×8.6 mm, the thickness of 1.9 mm, and the volume is about 140 mm3. The conventional motor with the brush has the dimension of about 300 to 500 mm3. Thus, as compared with the conventional motor, the small vibration motor according to this embodiment can have its volume reduced substantially equal to ½ to ⅓.
B. Process for Manufacturing Small Vibration Motor
The process for manufacturing the above-mentioned small vibration motor will be described below. Here,
B-1. Process for Manufacturing Driver IC
At first, as shown in
B-2. Flexible Substrate Process
On the other hand, a flexible substrate manufactured in a different step (not shown) is prepared (Step S110 in
There are three connection portions between the FP coil 1 and the flexible substrate 3, and there are also only three connection terminals to the motherboard (not shown) through the flexible substrate 3. Thus, although the vibrating section and the driver IC 4 are electrically connected, this is not a strong vibrator, and this has the action of attenuating the vibration generated by the flexible substrate 3 itself. Hence, it is possible to suppress the mechanical stress on the mounted portion. Then, the circuit is inspected (Step S16). If the circuit contains any repairable defect, it is returned to the step S12 in order to repair it by carrying out soldering and the like once again and then re-inspected. On the other hand, if it contains any defect that cannot be repaired, it is discarded (Step S18). Also, if the inspected result is satisfactory, the operational flow proceeds to a next process, which will be described later.
B-3. Process for Installing Radial Bearing
A bottom plate is prepared in order to package the small vibration motor (Step S20 in
B-4. Rotor Yoke Process
The rotor yoke 6 is prepared (Step S40 in
B-5. Assembling Process
Next, as shown in
The small vibration motor 30 according to the above-described embodiment can be miniaturized and thinned. As compared with a conventional motor with a brush, the longitudinal and lateral dimension of the small vibration motor 30 is about 8.6×8.6 mm, and thickness is about 1.9 mm, and its volume is about 140 mm3. Thus, this motor has a volume substantially equal to ½ to ⅓ of the conventional motor. In addition, because the driver IC can be mounted as the bare chip, it is advantageous in that the chip manufacturing processes may be reduced. Further, the rotation of the rotor yoke 6 inside helps to increase the cooling efficiency.
Also, since the vibration motor 30 has the driver IC 4 therein, mounting on the motherboard (not shown) can be treated similarly to mounting the surface mount parts. At this time, the mounted direction of the small vibration motor 30 needs to be recognized. In order to indicate the mounting direction, a simple mark 31 may be printed as shown in
In addition, as the methods of mounting the small vibration motor 30 on the motherboard, there are: a method of using an FPC (Flexible Printed Circuit Board) connector 40 electrically connected to the terminal formed on the protrusion section of the flexible substrate 3, as shown in
Also, as a parts shipment/delivery method for the vibration motor 30, it is possible to pack it in a reel-shaped tape 50 as shown in
Finally, the embodiments and examples described above are only examples of the present invention. It should be noted that the present invention is not restricted only to such embodiments and examples, and various modifications, combinations and sub-combinations in accordance with its design or the like may be made without departing from the scope of the present invention.
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