KR20010057868A - Flat type vibration motor of 2-phase - Google Patents

Abstract

PURPOSE: A two-phase flat vibration motor is provided to enable a sordering process to be performed on only three portions of an upper board and simplify a circuit configuration on the upper board by forming six commutators. CONSTITUTION: A pair of winding coils are provided on an upper board. Each winding coil is made of a single winding. An A coil(11) and a B coil(12) are distanced as far as a predetermined electrical angle and connected to each other on a c point. At the same time when the A coil(11) and the B coil(12) are connected, they are also connected to a circuit printed on the upper board, thereby requiring a soldering process with the upper board. Each other ends, namely, a terminal and b terminal, of the A coil(11) and the B coil(12) is soldered to be connected with the circuit printed on the upper board. The winding coil(10) is fixedly fastened to the printed circuit on the upper board by virtue of the soldering process on three places. There is no necessity to align end parts of the winding coils and the amount required for the soldering process is reduced, so as to simplify the work and facilitate circuit configuration on the upper board.

Description

Flat type vibration motor of 2-phase

The present invention relates to a two-phase flat vibration motor that simplifies the connection structure of the winding coil by forming the winding coil bonded to the upper substrate as a single winding structure.

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 vibration motor consists largely of a stator assembly as a stationary member and a rotor assembly as a rotating member.

That is, the lower substrate 120 having the circuit printed on the plate is bonded to the upper surface of the bracket 110, which is a circular flat plate, and the donut-shaped magnet 130 is attached to the outer side of the lower substrate 120 in the same manner. do.

In addition, the upper portion of the bracket 110 is covered by a cap-shaped case 140 which is open downward, and the bracket 110 and the case 140 are connected by a central shaft 150.

2, the rotor assembly is rotatably provided as shown in FIG. 2, and the rotor assembly again includes the bearing 170, the upper substrate 180, the commutator 190, and the winding coil 200. It is made up of a weight 210 and an insulator 220.

The bearing 170 is a means for rotatably supporting the rotor assembly from the shaft 150, usually using a metal bearing.

The upper substrate 180 is a printed circuit board of a flat plate, and in the past, a shape in which a circle is cut at a predetermined angle is mainly used, but recently, a structure formed in a circle for increasing an eccentricity is mainly used.

The commutator 190 is a connection terminal for electrically connecting the stator assembly and the rotor assembly while the upper end of the brush connected to the lower substrate of the stator assembly is in sliding contact. Dog segments are provided in a circular shape at regular intervals.

The upper substrate 180 is provided with a winding coil 200 and a weight 210 as an upper surface, respectively, in which the winding coil 200 is spaced at a predetermined angle at a position eccentrically to one side from the upper substrate 180. It is formed as two winding coils 200.

In addition, a weight 210 made of a heavy material is bonded to the upper substrate 180 corresponding to the winding coil 200.

In addition, the upper surface of the upper substrate 180 except for the winding coil 200 and the weight 210 is filled with an insulator 220, by which the winding coil 200, the weight 210 and the bearing are connected. While being structured to be integrally coupled with the upper substrate 180, the winding coil 200 is insulated from each other.

Meanwhile, the lower substrate 120 and the commutator 190 between the stator assembly and the rotor assembly are connected by sliding contact by a pair of brushes 160.

In such a configuration, in particular, the winding coil 200 of the motor having a two-phase driving structure is typically a double winding structure for winding two strands of wire simultaneously, and the coil having such a double winding structure is eccentrically to one side on the upper substrate 180. It is generally provided in pairs.

In addition, the pair of winding coils are separated from each other by a constant electric angle, and therefore, the upper substrate 180 requires soldering at six places as shown in FIG. 3.

In other words, soldering is required in two places to connect the coils double-wound in each of the double-wound winding coils 200, and each of the input and output terminals of the double-wound coils is printed on the upper substrate 180. Since four terminal connections are required for connection, soldering in total six locations is required.

However, in order to assemble the winding coil on the upper substrate 180, as described above, since a plurality of end lines are generated, a process for aligning the end lines must be added, and the ends and the printed circuit of the upper substrate 180 are connected. In order to achieve this, there is a problem that a very sophisticated circuit design on the upper substrate 180 is required along with soldering at six locations.

The present invention is to compensate for the above-described problems, the present invention is to make the two winding coils provided on the upper substrate in a single line, each of these two winding coils are connected to each other end of the printed circuit of the upper substrate Its main purpose is to allow soldering to only three locations on the upper substrate.

In addition, the present invention has another object to simplify the circuit design on the upper substrate by forming the number of the commutator to deliver the power induced through the brush to the two winding coils as six.

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

2 is a perspective view showing a rotor assembly of a conventional flat vibration motor;

3 is a winding structure diagram of a conventional winding coil,

4 is a coil winding structure diagram according to the present invention,

5 is a structural diagram of a commutator according to the present invention.

<Description of the symbols for the main parts of the drawings>

10: winding coil 20: upper substrate

21: commutator

In order to achieve the above object, the present invention provides a flat vibration motor having a diameter that is relatively larger than the thickness,

A pair of winding coils provided eccentrically to one side on the upper substrate supported by the eccentric rotation is allowed to be wound as a single wire, and each end of the winding coil is soldered to a circuit printed on the upper substrate, respectively. Connected to each other by soldering to a circuit printed on the upper substrate in a state where the other ends are connected to each other, and the commutator formed on the bottom surface of the upper substrate has six segments.

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

The configuration of the two-phase flat vibration motor to which the present invention is applied is almost similar to the prior art.

However, the present invention improves the structure of the winding coil bonded to the upper substrate in the two-phase flat vibration motor, the connection structure between the winding coil and the printed circuit on the upper substrate, and the structure of the commutator.

Figure 4 schematically shows the winding structure of the winding coil according to the present invention, Figure 5 shows the configuration of the commutator according to the present invention.

As shown, the present invention is characterized by forming a pair of winding coils provided on the upper substrate as before, but each of these winding coils 10 is made of a single winding.

Accordingly, as shown in FIG. 4, the A coil 11 and the B coil 12 are arranged to be spaced apart from each other at a predetermined electric angle while they are connected to each other at the point c.

In this case, the point c is connected to the circuit printed on the upper substrate while the A coil 11 and the B coil 12 are connected, and therefore soldering with the upper substrate is necessary.

In addition, the a and b terminals, which are the other ends of the A coil 11 and the B coil 12, are also fixed by soldering so as to be connected to the circuit printed on the upper substrate.

As described above, the winding coil 10 of the present invention is firmly fixed by bonding in a state where it is connected to the upper substrate side printed circuit by soldering at three places.

Meanwhile, as shown in FIG. 5, the commutator 21 having six segments is provided on the bottom of the upper substrate 20.

These commutators 21 each segment is sequentially connected to terminal a, terminal b and point c, respectively.

In other words, the segment a is connected to the terminal a through the printed circuit of the upper substrate 20, the segment b is connected to the terminal b, and the segment c is connected to the point c.

Looking at the action according to the present invention having the structure as described above are as follows.

As before, the power input from the outside is transmitted by sliding contact with the commutator through a pair of brushes, and the pair of brushes are usually at an angle of exactly 90 ° with the mechanical angle.

At this time, one brush among the pair of brushes becomes the input terminal, and the other brush becomes the output terminal. If the brush on the one side, which is the input terminal, is in contact with the segment, the brush on the other side is exactly 90 ° at the machine angle. It comes into contact with the b or c segment that is present.

Therefore, the power input to the a segment is input through the a terminal of the winding coil is output through the c point or the b terminal, while the A coil 11 and the B coil 12 is energized to generate an electromotive force, The driving force is generated by the interaction between the electromotive force and the magnetic force of the magnet.

In this way, when the brush on one side is connected to the a, b, and c segments in turn by the rotation of the upper substrate 20, the brush on the other side is also in the b, c, a segment at 90 ° to the machine angle, respectively. According to the connection state of the commutator 21, a current is input or output through the a terminal, the b terminal, and the c point of the winding coil, whereby the winding coil is continuously energized to maintain the rotor assembly of the motor. Rotated.

As the rotor assembly eccentrically supported on the shaft rotates as described above, vibration is generated by the eccentric drive by the rotor assembly.

Therefore, the arrangement according to the present invention not only no longer requires end alignment of the winding coil 10, but also reduces the amount of soldering work, which simplifies the work and at the same time makes the circuit design on the upper substrate easier. It has a useful effect.

Claims (1)

In a flat vibration motor having a contour whose diameter is relatively larger than the thickness, The pair of winding coils 10 eccentrically provided on one side of the upper substrate 20 supported by the shaft for eccentric rotation may be wound as single wires, and each end of the winding coil 10 may be respectively It is connected to the circuit printed on the upper substrate 20 by soldering, and each other end is connected to the circuit printed on the upper substrate 20 by soldering in a state of being connected to each other, the lower surface of the upper substrate 20 The commutator 21 formed is a rotor assembly of a two-phase flat vibration motor consisting of six segments.