KR100307737B1 - A flat type vibration motor - Google Patents

Abstract

The present invention relates to a flat vibration motor for simplifying the assembly process of the device by making the connection by direct contact between the motor-side terminal and the power supply terminal by having the connection means integrally provided to one side of the motor, achieving the above object To this end, the present invention provides a flat vibration motor having a diameter larger than a thickness, the extension end portion 21 of which a part of the bracket 1 is extended outward so that the lead end of the lower substrate 2 is joined to the upper portion; A holder 22 provided at both sides of the extension end 21; The lower end part is joined to the terminal formed in the lead-out end of the lower substrate 2, and the upper end part is provided with a connecting means formed as a terminal 23 which is bent to face each other. The curved upper end of the terminal 23 is characterized in that the assembly process of the device can be simplified by making the elastic direct direct contact with the power supply terminal 30 correspondingly located vertically.

Description

A flat type vibration motor

The present invention relates to a flat vibration motor to simplify the assembly process of the device by making the connection is made by direct contact between the motor-side terminal and the power supply terminal by having the connection means integrally provided to one side of the motor.

Generally, a flat vibration motor, which is built in a mobile phone or a pager, mainly performs an incoming call function, is called a pan cake type or a coil type having a larger diameter than a thickness as shown in FIG. 1. Most of them are flat vibration motors (also called coin types).

The flat drive motor is largely made of a stator which is a fixing member and a rotor which is a rotating member, and the electrical connection between the stator and the rotor is made by the brush 10.

In other words, a lower substrate 2 having a circuit printed on the plate surface is attached to the upper surface of the bracket 1, which is a circular flat plate, by bonding or the like, and the donut-shaped magnet 3 is attached to the outside of the lower substrate 2 in the same manner. Attach in a way.

And the upper part of the bracket (1) is covered by the case 4 of the cap shape which is open downward, the bracket (1) and the case (4) is to be firmly connected to the center by the shaft (5).

Meanwhile, the lower substrate 2 attached to the bracket 1 mainly used a hard board, but recently, a flexible board is mostly used.

With this configuration, the stator is provided with a rotor rotatably on the shaft 5 while the stator is provided.

The rotor is usually provided with an upper substrate 6 for cutting the circular flat plate at a predetermined angle so as to be eccentrically supported by the shaft 5 and a bottom periphery of a rotating center supported by the shaft 5 of the upper substrate 6. The commutator 7, the winding coil 8 attached to the upper surface of the upper substrate 6, and the insulator 9 filled with the upper surface of the upper substrate 6 excluding the attaching surface of the winding coil 8. As is done.

In such a rotor, the commutator 7 is provided in a shape in which a plurality of segments are spaced at minute intervals to form a circular shape as a whole, and the winding coil 8 may be formed as one or more depending on the driving type of the motor. The applied structure is a single-phase or two-phase structure in which two coils each having different phases on both sides of the upper substrate 6 of the eccentric structure are arranged.

On the other hand, the insulator 9 is molded by insert injection using a general resin material.

In this way, the electrical connection between them in the motor consisting of the stator and the rotor is transmitted through the brush 10 as described above.

The lower end of each brush 10 is also fixedly connected to the printed circuit of the lower substrate 2 and the upper end is in sliding contact with the segment of the commutator 7.

On the other hand, the power supplied to the lower substrate 2 is transmitted by the lead wire 11 connected by soldering to the lower substrate 2 protruded to one side of the motor as shown in FIG.

That is, the other end of the lead wire 11 to which the power supply terminal and one end of the device are connected by soldering or a connector connection is connected to each other by a solder or the like in the terminal of the portion extending to protrude outward from the lower substrate 2.

To this end, in the past, a power supply terminal is disposed together with a motor at a predetermined position of the device, and the terminal and the power supply terminal of the motor are connected as a lead wire 11 to enable energization.

On the other hand, when the lower board 2 was used as a hard board, a connector was provided as an end of the lead wire, and the connector was directly connected to the terminal of the lower board.

However, in order to connect the terminals in the power connection structure as described above, the lead wires 11 are required separately, and both ends of these lead wires 11 must be connected to each terminal by soldering or provided with a connector.

Therefore, in order to couple the vibration motor to the device set, it is designed in consideration of the structure that is electrically connected, and must be connected using the lead wire 11, so that the vibration motor and the power supply terminal respectively attached or fastened to different device cases are The inter-substrate connection formed is very difficult.

This technical difficulty not only leads to a prolonged assembly time due to a delay in the process, but also a serious problem such as an easy short circuit of a contact connected by soldering, especially when a severe impact is applied to the device during use. .

The present invention partially extends the bracket of the area where the lower substrate is drawn out so that the holder is integrally formed on the upper portion of the lower substrate in order to correct the above problems, and the holder is inserted into the terminal bonded to the terminal of the lower substrate. The main purpose of the present invention is to simplify the connection structure by allowing the power supply terminal to be energized while being directly elastically connected to the upper end of the terminal when the device is assembled.

In addition, the present invention is to provide a separate lead wire or to omit a soldering operation or a connector for connecting the lead wire is another object to reduce the time and assembly time of the parts.

In addition, the present invention has another object to facilitate the miniaturization of the device by efficiently using the layout space in the design of the device because the power supply terminal and the motor is directly connected.

1 is a vertical cross-sectional view of a general flat vibration motor,

2 is a connection structure diagram of a conventional flat vibration motor;

3 is a vertical sectional view of the flat vibration motor according to the present invention;

4 is a perspective view illustrating main parts of the connecting means of the flat vibration motor according to the present invention;

5 is a connection structure diagram of a flat vibration motor according to the present invention.

<Description of Signs of Major Parts of Drawings>

1 Bracket 2 Lower Substrate

21: extension end 22: holder

23: terminal 30: power supply terminal

In order to achieve the above object, the present invention includes a lower substrate attached to the upper portion of the bracket which is a circular flat plate;

A magnet provided outside the lower substrate at an upper portion of the bracket;

An upper case supported by the bracket and the shaft;

An upper substrate rotatably eccentrically supported on the shaft, the upper surface of which a winding coil is disposed;

A commutator formed at a periphery of the rotational center of the bottom side of the upper substrate;

In the flat vibration motor having a diameter larger than the thickness provided by a brush connecting the lower substrate and the commutator,

An extension end for extending a portion of the bracket to the outside so that the lead end of the lower substrate is joined to the upper portion, a holder provided on both sides from the top of the extension end, and fitted into the respective holders so as to be detached and prevented from the lower end of the lower substrate. It is most prominent to be connected to the terminal formed in the upper end portion is bent facing each other is provided with a connecting means which is in direct contact with the power supply terminal in which the bent upper end of the terminal is vertically corresponding.

Hereinafter, described in detail with reference to the accompanying drawings a preferred embodiment of the present invention.

The flat vibration motor according to the present invention is almost similar to the configuration shown in FIG.

That is, as shown in FIG. 3, the vibration motor of the present invention includes a bracket 1 of a flat plate, and a lower substrate 2, which is a printed circuit board, is bonded to an upper surface of the bracket 1, and the lower part of the vibration motor of the present invention is bonded to the lower surface of the bracket 1. The magnet 3 is attached to the outside of the substrate 2 in the shape of a donut, and the upper portion of the bracket 1 is covered by a cap-shaped case 4 which opens downward.

The bottom bracket 1 and the upper case 4 are connected by the shaft 5, and the rotor 5 is eccentrically supported by the shaft 5 so as to be rotatable.

The rotor is again made up of a printed circuit board, an upper substrate 6 and a commutator 7, a winding coil 8 and an insulator 9, the double commutator 7 being supported on the shaft 5 of the upper substrate 6. The winding coil 8 is provided on the upper surface of the upper substrate 6 and the insulator 9 is provided on the upper surface of the upper substrate 6 except the winding coil 8.

At this time, the upper substrate 6 is to cut the printed circuit board, which is a generally circular flat plate at a predetermined angle so as to be eccentrically supported on the shaft 5, the winding coil 8 is eccentrically to one side to the upper substrate 6 In order to increase the amount of eccentricity of the rotor during molding of the insulator 9, the upper substrate 6 may be provided with weights together with the winding coil 8.

On the other hand, the commutator 7 provided at the bottom of the upper substrate 6 has a shape in which a plurality of segments have a circular shape with a small interval, and these segments are each formed by the upper substrate 6 through a circuit printed on the upper substrate 6. It is connected to the winding coil 8 which is joined to the upper portion of.

In particular, the winding coil 8 and the weight provided on the upper surface of the upper substrate 6 are fixed to each other by bonding, and in the other space, the upper substrate 6 while the insulator 9 is molded by insert injection. In the winding coil 8 and the weight is to be firmly fixed.

At the same time, the insulator 9 allows the bearing to be eccentrically coupled to each other, and the shaft 5 is rotatably fitted to the bearing.

In this configuration, the rotor is supported on the shaft 5 in a state capable of vertical flow, and the brush 10 is provided for electrical connection between the lower substrate and the upper substrate while supporting the rotor at the bottom.

On the other hand, the present invention is to improve the electrical connection structure of the flat vibration motor as described above.

In other words, a power source for driving the rotor in the flat vibration motor is transmitted through the lower substrate 2, and the lower substrate 2 receives power from an external power supply terminal.

The present invention is characterized by simplifying the connection structure between the external power supply terminal and the terminal of the lower substrate 2 by making direct contact.

In more detail, as shown in FIG. 4, the bracket 1 and the upper substrate 2 extend outward in a state in which some of them are bonded to each other.

The holder 22 is provided at both ends of the extension end 21 of the bracket 1, and the terminals 23 are inserted into the holders 22 at both sides thereof to prevent their separation.

At this time, the lower end of each terminal 23 is firmly joined to the lead end side terminal of the upper substrate 2 by soldering or the like.

The terminal 23 also has an elasticity in the vertical direction, with its upper end extending at least higher than the upper end of the holder 22 and causing its ends to bend in a direction facing each other.

As such, the most prominent feature of the present invention is that the extension end 21 of the bracket 1 includes the holder 22 and the terminal 23 so as to be integrally provided on one side of the motor.

Meanwhile, the vibration motor according to the present invention allows the bottom surface of the bracket 1 to be attached to one case of the device, and the other case is provided with a power supply terminal at a position corresponding to the connecting means of the present invention.

When the connecting means is integrally provided with the vibration motor as described above, first, as described above, when the vibration motor is attached to the case on one side of the device and the case on the other side is coupled, the power supply terminal provided on the case on the other side is directly Since the terminal 23 of the connecting means of the present invention is elastically contacted, it is in a state of being automatically connected.

That is, in the past, the power supply terminal and the lower substrate partially drawn out from the vibration motor were connected by using a separate lead wire. However, the present invention does not use such a separate lead wire, and the process of joining the lead wire to each terminal may be omitted. There is a number.

In other words, the components and the device case in the device are usually manufactured in a separate process, and the parts and the case manufactured in this way are assembled in one place.

The gathered parts are first joined by joining or fastening to the already set position of the case. At this time, a vibration motor is attached to one device case, and a board or board on which the power supply terminal is formed is connected to the other device case. do.

Therefore, the connection member is necessarily required for the connection between the vibration motor side terminal and the power supply terminal, but the present invention does not include such a connection member, but simply provides a connection means when the vibration motor is manufactured. When assembling, as shown in FIG. 5, the terminal 23 of the connecting means and the power supply terminal 30 are in direct contact with each other so as to be electrically connected.

Therefore, the separate parts and processes for connecting them between the vibrating motor and the power supply terminal can be omitted, and the assembling process can be proceeded faster, thereby increasing the productivity of the product.

Therefore, the present invention simplifies the structure of connection with the power supply terminal by a simple structure improvement including a connecting means integrally on one side, thereby shortening the process of assembling the device and improving safety connection and product productivity. It will work.

Claims (2)

A lower substrate 2 attached to the upper portion of the bracket 1 which is a circular flat plate; A magnet (3) provided outside the lower substrate at an upper portion of the bracket (1); An upper case (4) supported by the bracket (1) and the shaft (5); An upper substrate 6 rotatably eccentrically supported by the shaft 5 and having a winding coil 8 disposed on an upper surface thereof; A commutator 7 formed at a periphery of a rotational center of the bottom side of the upper substrate 6; In the flat vibration motor having a diameter larger than the thickness provided by the brush 10 connecting the lower substrate 2 and the commutator 7, An extension end (21) which extends a part of the bracket (1) to the outside so that the lead end of the lower substrate (2) is joined upward; A holder 22 provided at both sides of the extension end 21; A terminal 23 inserted into the respective holders 22 so as to be prevented from detaching, and having a lower end joined to a terminal formed at an end portion of the lower substrate 2 and an upper end bent to face each other; A flat vibration motor which is provided such that the connecting means is formed so that the curved upper end portion of the terminal 23 is elastically directly in contact with the power supply terminal 30 corresponding to the vertical position. The method of claim 1, wherein the terminal 23 is A flat vibration motor that is forcibly fitted along a hole formed to correspond to the holder 22.