KR100439002B1 - Flat coreless vibrating moter - Google Patents

Abstract

PURPOSE: A flat coreless vibration motor is provided to generate electrical vibrations from a torque imbalance during rotation of a rotor assembly. CONSTITUTION: A flat coreless vibration motor comprises a upper case(40); a lower case(10); a stator assembly(20) arranged in the lower case, wherein the stator assembly includes a plurality of magnets(22), brushes(24a,24b) for receiving power from an external source, and a shaft(25) fixed to the lower case; and a rotor assembly(30) where a coil assembly(32) and a printed circuit board(31) printed with a commutator pattern are integrally molded. The coil assembly includes one or more single line coils, and double line coils. The printed circuit board is printed with a first pattern coil(311) and a second pattern coil(312). The first pattern coil is formed at the position corresponding to the double line coil and electrically connected to the double line coils so as to cooperate with the double line coil and operate as a single armature coil. The second pattern coil is formed at the position corresponding to the single line coil.

Description

FLAT CORELESS VIBRATING MOTER

The present invention relates to a flat core vibration vibration motor, and more particularly, to a flat core vibration vibration motor for supporting a vibration call mode of a mobile communication terminal.

With the recent rapid development of communication technology, each individual can make a call anytime and anywhere while carrying a mobile communication terminal. One of the essential functions in using such communication equipment is an incoming call function. Currently, the incoming call function includes a voice call mode such as a melody or a bell and a vibration call mode for shaking the device. Here, the vibration call mode is mainly used as a consideration to avoid harming others in public places, for example, subway, theater, library, etc. where many people gather.

Currently, a flat coreless vibration motor is commonly used to support a vibration function in a mobile communication terminal. The flat coreless vibration motor according to the prior art generates vibrations by weight and eccentricity of weights in a state where torque is constant in a three or two coil connection manner. However, as the mobile communication terminal becomes smaller and slimmer, the vibration force decreases as the weight of the weight and the size of the rotor assembly decrease.

Accordingly, the inventors of the present invention have changed the structure of the rotor assembly and the wiring method of the coil to maximize the unevenness of the torque during the rotation of the rotor assembly to generate an electric vibration, so the idea of a flat core vibration vibration motor that can increase the vibration force.

The present invention is to solve the above problems, by varying the structure of the rotor assembly and the wiring method of the coil to maximize the unevenness of the torque during rotation of the rotor assembly to generate an electric vibration, thereby increasing the vibration force flat The object is to provide a coreless vibration motor.

1 is a cross-sectional view of a flat core vibration vibration motor according to the present invention.

2 is a printed circuit board having a commutator according to the present invention;

3 is a coil connection diagram according to the present invention.

4 is a current waveform diagram according to the present invention;

5 is a torque waveform diagram according to the present invention.

<Brief Description of Drawings>

10: lower case 20: stator assembly

22: field magnet 23a, 23b: power line

24a, 24b: brush 25: shaft

30: rotor assembly 31: printed circuit board

311: first pattern coil 312: second pattern coil

313: copper foil pattern 314: commutator

32: coil assembly 321: bearing

322,323: coil 324: weight

40: upper case

A flat core vibration vibration motor according to an aspect of the present invention for achieving the above object is provided in the upper case, the lower case, the lower case and a magnet having a plurality of alternating N, S stimulation, and supplies power from the outside A stator assembly including a receiving brush, a shaft fixed to the lower case, a bearing coupled to the shaft, a coil assembly provided with a plurality of coils and weights, and contacting the brush and supplying power from the brush to the coil A flat coreless vibration motor comprising a rotor assembly in which a printed circuit board on which a commutator pattern is printed is integrally molded, wherein the coil assembly is wound by overlapping a coil structure with at least one single wire coil formed in a single wire structure. It includes a double coil and is electrically connected in series with the double coil in the printed circuit board For example, in order to operate together with one armature coil, a first pattern coil formed at a position corresponding to the double-coil coil and a second pattern coil formed at a position corresponding to the disconnection coil are printed to be electrically driven by torque unevenness during rotation of the rotor assembly. It is characterized in that the vibration is generated.

Hereinafter, exemplary embodiments of the present invention will be described in detail with reference to the accompanying drawings so that those skilled in the art can easily understand and reproduce the present invention.

1 is an exploded perspective view of a flat core vibration vibration motor according to an embodiment of the present invention, Figure 2 shows a printed circuit board (PCB) printed with a commutator according to the present invention.

As shown in FIG. 1, the vibration motor according to the present invention includes a stator assembly 20, a rotor assembly 30, and an upper case 40 surrounding the rotor assembly 30 fixed to the lower case 10. It includes.

The stator assembly 20 includes a field magnet 22, brushes 24a and 24b, and a shaft 25 fixed to the center of the lower case 10.

The field magnet 22 is a flat magnet having a plurality of alternating N and S magnetic poles. In the preferred embodiment, the field magnet 22 is a magnet having four poles of NSNS arranged in a circle.

The brushes 24a and 24b apply power supplied from the outside to the rotor assembly 30.

According to a further aspect of the invention, the stator assembly 20 is disposed in the space between the field magnet 22 and the lower case 10, the power line (23a, 23b) for supplying external power to one end of the Connected substrate 23. At this time, the brushes 24a and 24b are bonded to the other end of the substrate 23. Preferably, the substrate 23 is formed of a flexible printed circuit board (FPCB) having a copper foil pattern for supplying power from the power lines (23a, 23b).

The rotor assembly 30 includes a printed circuit board 31 and a coil assembly 32.

As shown in FIGS. 1 and 2, the printed circuit board 31 is printed with first and second pattern coils 311 and 312 connected with copper foil patterns 313 on the upper surface thereof, and the brush on the lower surface thereof. A commutator pattern (314 in FIG. 2) for supplying power input through 24a and 24b to a plurality of coils (322,323 and 323 in FIG. 1) is printed. The commutator segments A, A, B, B, C, and C are connected to each other by a copper foil pattern 313. Here, reference numeral 315 shown in FIG. 2 is a terminal connected to the commutator segment and the copper foil pattern. Reference numeral 316 denotes a chip resistor.

The coil assembly 32 is attached to the printed circuit board 31 on its lower surface, and is eccentrically supported by the shaft 25 and the bearing 321 so as to freely rotate by placing a gap with the field magnet 22. A plurality of coils 322, 323, 323 and weights 324 are laid.

According to an aspect of the present invention, two coils of the plurality of coils 322, 323, and 323 are arranged to overlap at the same position in a double wire structure. Accordingly, according to the present invention, since only two coils are spatially disposed, sufficient space can be secured so that the weight 324 can be disposed in the free space, and the centrifugal force of the rotor assembly 30 by the weight 324. Can be increased. In this embodiment, the arrangement angles of the double-coiled coils 323 and 323 and the single-coiled coils 322 ( ) To 135 degrees. This is an optimized placement angle so that the rotor assembly has no starting point when interacting with the armature coil and the magnet.

According to an additional aspect of the present invention, the first pattern coil 311 of the printed circuit board 31 is formed at a position corresponding to the disconnection coil 322 of the coil assembly 32, and the second pattern coil of the printed circuit board ( 312 is formed at a position corresponding to the double coils 323 and 323. Accordingly, when a current is applied to the coil and the pattern coil, the rotor assembly may increase the rotational force by applying electric force to the coil and the pattern coil in the same direction.

Figure 3 is a coil connection diagram according to a preferred embodiment of the present invention, Figure 4 is a current waveform diagram according to the present invention, Figure 5 is a torque waveform diagram according to the present invention.

As shown in FIG. 3, the coils B and C arranged in a double wire structure are connected to be connected in series with the first and second pattern coils 311 and 312 printed on the printed circuit board 31 and arranged in a single wire structure. The coil A is implemented such that one end thereof is connected to the commutator segment B, each end of the coils B and C arranged in a double-wire structure is connected to the commutator segment A, and the other ends of the coils A, B and C are connected to the commutator segment C. Accordingly, the armature coil according to the present invention is driven in a conventional three-phase 120 degree constant current drive method.

According to a further aspect of the present invention, the size of the armature coils B, C arranged in the double-wire structure and the armature coil A arranged in the single-wire structure are the same. That is, in the present invention, the current waveform when the current flows into the commutator segments A and C (2 in FIG. 4) and the current waveform when the current flows into the commutator segments B and C (3 in FIG. 4) are applied to the pattern coils A and B. To change. Accordingly, the rotor assembly (30 of FIG. 1) of the present invention is driven to have different current waveforms for each phase during rotation as shown in FIG. 4, and as a result, different phases for each phase as shown in FIG. By generating torque waveforms, high vibrations can be obtained due to torque variations.

When the brush (24a, 24b of FIG. 1) to which the power is applied is in contact with the commutator segments A and B, the power current is arranged in the coils B and C arranged in the double-wire structure and the pattern coils PA, PB and the single wire structure. Flowing through the coil A, the current waveform is equal to 1 shown in FIG. 4 and the torque waveform is equal to 1T shown in FIG.

Accordingly, an electromagnetic force is generated as current flows through the coils A, B, and C, and this force acts as a rotational force for interacting with the field magnet (22 in FIG. 1) to move the rotor assembly (30 in FIG. 1). Done. Subsequently, when the rotor assembly (30 in FIG. 1) is rotated so that the brushes (24a and 24b in FIG. 1) contact the commutator segments B and C, the power currents are formed in a single wire structure with coil A and commutator segments. Flowing through C, the current waveform is equal to 2 shown in FIG. 4 and the torque waveform is equal to 2T shown in FIG. Subsequently, when the rotor assembly (30 in FIG. 1) is rotated so that the brushes (24a and 24b in FIG. 1) are connected to the commutator segments C and A, the power current is passed through the coils B, C and the pattern coils PA and PB. At this time, the current waveform is equal to 3 shown in FIG. 4 and the torque waveform is equal to 3T shown in FIG.

The flat coreless vibration motor according to the present invention having the configuration as described above is driven to have different current waveforms when the rotor assembly rotates, as shown in FIG. 4, and as a result, the torque shown in FIG. As shown in the waveform, torque imbalance is brought for each phase, and high vibration force can be obtained even if the magnitude and eccentricity of the weight are reduced.

As described above, the flat core vibration vibration motor according to the present invention is connected to a double coil and a single coil to be driven by a conventional three-phase 120 degree constant current driving method, and the rotor assembly is electrically connected in series with the double coil and the pattern coil. When the three-phase energization is driven to have a different current waveform for each phase to generate a non-uniform torque, there is a useful effect to obtain a high vibration because it generates electrical vibration.

In addition, according to the present invention, by forming the pattern coil at a position corresponding to each of the double-coil and the single-coil, the electric current is applied to the rotor assembly by the coil and the pattern coil to increase the rotational force.

Although the present invention has been described with reference to the accompanying drawings, it will be apparent to those skilled in the art that many various obvious modifications are possible without departing from the scope of the present invention from this description. Therefore, it should be interpreted by the claims described to include many such variations.

Claims (5)

delete An upper case; A lower case; A stator assembly disposed on the lower case and including a magnet having a plurality of alternating N and S poles, a brush supplied with power from the outside, and a shaft fixed to the lower case; Rotor assembly integrally molded with a bearing coupled to the shaft and a coil assembly provided with a plurality of coils and weights, and a printed circuit board in contact with the brush and printed with a commutator pattern for supplying power from the brush to the coil. ; In the flat core vibration vibration motor comprising: The coil assembly is: At least one single coil formed in a single wire structure; Including a double coil wound overlaid in a double wire structure, The printed circuit board is: A first pattern coil formed at a position corresponding to the double coil and a second pattern coil formed at a position corresponding to the single coil in order to be electrically connected in series with the double coil and operated as a single armature coil. A flat core vibration vibration motor. The flat core vibration vibration motor of claim 2, wherein the double-coil and single-coil have the same size. delete delete