KR101268943B1 - Vibrator with Brush - Google Patents

Abstract

Among the vibration generators used in mobile phones, mobile information terminals, and game machines, the commutator pattern is installed on the substrate, and the coil and the weight are attached to the opposite side so that the center of gravity is eccentric to the center of rotation. Brush type flat vibration that generates the rotor and rotates when the current is supplied to the commutator pattern and coil of the rotor through the brush installed on the stator side where the case and bracket are attached and the shaft and magnet are attached. In the generator, at the site where the weight body is assembled to the upper substrate, the outer radius of the weight body is made larger than the outer radius of the upper substrate at the site where the weight body is assembled, and an arc-shaped protrusion is formed from the outside of the weight body to the upper substrate to form an arc-shaped protrusion. Make the radius equal to the outer radius of the upper board of the site where the weight is assembled Vibration generator of the rotor structure in which the outer radius of the weight body matches the outer radius of the insulating resin

Description

Brush-type vibration generator {Vibrator with Brush}

In general, with the recent development of communication technology, the most widely distributed to the public are mobile phones and personal information terminals. These devices are becoming smaller as they become smaller, making them portable as well as being able to carry voice and data input and output anywhere, anytime. Nowadays, not only vibrating function is required for public etiquette, but also vibrating function is provided when inputting data such as phone number or playing game by touch type. In addition, the general game function is to provide a function that allows the player to play the game more realistically by generating a vibration in the case of shooting a gun or hitting a ball in a sports game. In this case, the vibration generator is generally used. In this case, the vibration function is used, and in addition to the brush-type vibration generator (aka vibration motor) that uses a shunt current rectifying component such as a brush and a commutator, a brushless vibration generator and a linear vibration generator Likewise, the production of vibration generators that meet the demand for long life and high reliability is also expanding.

The present invention is a technique applied to a brush-type vibration generator using a sliding type commutator called a commutator and a brush that is widely used because of low cost.

In the case of the general flat brush type vibration generator shown in FIGS. 1 and 2, the center of gravity of the rotor is eccentric with the center of rotation to generate vibration during rotation. Since no external eccentric weight is required, vibration can be generated with a relatively simple structure, and it is possible to manufacture a thin thickness, which is advantageous for thinning, and thus the use range thereof is gradually widening.

1 is a cross-sectional view of a conventional vibration generator. The conventional flat vibration generator consists of a stator which is a fixed member and a rotor which is a rotating member. That is, the lower substrate 6 is coupled to the upper surface of the bracket 1, which is a circular flat plate, and the upper ends of the lead wires 4a and 4b and the leader wires are connected to an external power source. The conductor wires 5a and 5b and the brushes 7a and 7b are electrically connected to each other, and the washer-shaped magnets 16 having concentric circles are coupled to each other. The shaft 2 is assembled at the upper center of the bracket 1, and the case 3 is assembled on the opposite side of the bracket 1 around the shaft 2 so that the entire outer structure is formed by the bracket 1 and the case 3. Configure The shaft 2 serves to guide the rotation of the rotor described below, in which the commutator 9 consists of a pattern of substrates on the side of the upper substrate 8 and on the opposite side. Resin insulator 11 in which two winding coils 10 wound with copper (copper) wires are coupled, a weight body 12 is coupled between two winding coils 10, and a bearing 13 is disposed at the center thereof. It is usually molded through injection molding to integrate mechanically. The upper washer 14 and the lower washer 15 made of a material having low frictional resistance may be added to reduce the rotational resistance of the contact portion caused by the bracket 1 or the case 3 when the rotor rotates. Referring to the flow of current, an external current is applied to the lead wires 4a and 4b and the current flows to the brushes 7a and 7b along the pattern of the lower substrate 6 and then the upper substrate of the rotor ( After reaching the commutator 9 on one side of 8), it reaches the winding coil 10 along the pattern of the upper substrate 8 and flows inside the winding coil 10 to generate electromagnetic force to function as an electromagnet. The magnet 16 disposed on the upper side and disposed to face the winding coil 10 interacts to generate rotational force.

In this flat brush type vibration generator, how to optimize the shape and assembly method of the upper substrate 8, the weight body 12 and the resin insulator 11 by design to maximize the rotor weight eccentricity in a small space and in the mass production process The key is whether to lower the manufacturing cost with less defects.

3 shows the design of the patent 10-0321870. In the proposed design, the outer diameter portion of the winding coil 10 and the weight body 12 therein filled with the resin insulator 11 is formed on the upper substrate 8. A structure substantially aligned with the outer diameter is proposed. In this proposal, the winding coil 10 and the weight body 12 therebetween are assembled so as not to deviate from the upper substrate 8, and the method of filling the resin insulator 11 by guiding the outer diameter of the upper substrate 8 is shown. The outer diameter filled with the resin insulator 11 coincides with the outer diameter of the upper substrate 8 so that the portion filled with the resin insulator 11 substantially surrounds the outer portion of the weight body 12 as shown in FIG. The advantage is that the weight 12 can be stably fixed. On the other hand, it has two disadvantages that cannot be overlooked. First, the weight 12 has a larger eccentric effect as it moves away from the center of rotation, but the outer circumference of the rotor is filled with a resin having a lower specific gravity, thereby reducing the eccentric effect. Secondly, if the weight body 12 replaces the space occupied by the upper substrate 8, the eccentric effect is large for the same reason, and the outer diameter portion filled with the resin insulator 11 in consideration of the convenience of the manufacturing process is the upper substrate 8 By presenting a structure substantially aligned with the outer diameter of the upper substrate (8), which also has a low specific gravity is occupied to the outside, the eccentric effect is reduced.

An alternative to this is to align the outer diameter of the weight body 12 with the outer diameter of the insulating resin 11 as shown in Patent Registration 10-0828645 or Patent Registration 10-0616629 shown in FIG. 4, but cut a portion of the upper substrate 8 in a straight line. And the shape is made to fill the protrusions in the weight body 12 to the cut out portion. These designs have the effect of increasing the eccentric effect than the invention of the patent 10-0321870, but the problem illustrated in FIG. In other words, the upper substrate 8 is cut in a straight line to form concave grooves or protrusions on the right and left sides in some areas, and the protrusions of the weight body 12 are formed to guide the concave grooves or the left and right protrusions. There is a gap between the width of the protrusion and the width of the protrusion, and when the upper substrate 8 and the weight body 12 guide portion are twisted left or right, the center position of the outer radius of the resin insulator 11 and the outer radius of the weight body 12 When the upper substrate 8 or the weight body 12 is filled with the resin insulator 11, a part of the resin insulator 11 covers the outer portion of the weight body 12. In the example of FIG. 5, the supplementary description of FIG. 5 illustrates a case in which the weight body 12 is in a shape in which the upper body 8 is inclined to the left side of the upper substrate 8. It can be seen that the larger the protruding and the right side of the insulating resin 11 to cover the outside of the weight body 12 thinly. The part where the insulating resin 11 covers the outside of the weight body 12 thinly has a weak bonding force and becomes a "burr" shape, and the consumer has a gap during use, so as to bump into the stator during rotation or separate from the foreign material. The same action will interfere with the rotation. In order to prevent this, after filling with the resin insulator 11, the rotor should be inspected and the "burr" should be removed, thereby increasing the manufacturing cost.

In the present invention, as shown in FIG. 6, the outer radius of the weight body 12 is larger than the outer radius of the upper substrate 8, and an arc-shaped protrusion is formed from the outer portion of the weight body 12 to the upper substrate 8. The inner radius of the protrusion is the same as the outer radius of the upper substrate 8 and is filled with the radius of the weight body 12 when filling with the insulating resin (11). Unlike the registered patent 10-0828645 or the registered patent 10-0616629, even if an assembly error occurs in which the weight body 12 rotates from the center of the rotor to the left and right sides, an arc-shaped shape extending from the outer side of the weight body 12 to the upper substrate 8 is formed. The inner radius portion of the protrusion is closely attached to the outer radius portion of the upper substrate 8 so that both the center of the outer radius of the weight body 12 and the outer radius center of the insulating resin 11 do not deviate from the rotor center. You can do it.
According to one aspect of the invention, the upper substrate is installed on one side and the commutator pattern is installed on the opposite side of the upper substrate and the center of gravity of the coil and the weight body is attached to the center of rotation and the rotor molded in the injection resin, and to form an outer And a stator formed by attaching a case, a bracket, a shaft, and a magnet, and a vibration is generated while a current is supplied to the commutator pattern and the coil of the rotor through a brush installed on the stator side, and the weight is the upper substrate. The outer radius of the weight is larger than the outer radius of the upper board at the site assembled on the upper body, and an arc-shaped protrusion is formed from the outer side of the weight to the upper board to make the inner radius of the protrusion of the arc equal to the outer radius of the upper board. The outer radius of the upper substrate by making the outer radius of the weight match the outer radius of the insulating resin The brush-type vibration generator may be provided, which increases the outer radius of the insulating resin while matching the outer radius of the weight body with the outer radius of the insulating resin.

The present invention differs from the prior art in two aspects.

Even if the assembly error to the left and right during assembly with the upper substrate 8 while increasing the rotor center of gravity eccentricity effect more than the conventional design illustrated in Figure 3 is formed extending from the outer side of the weight body 12 to the upper substrate 8 side Resin insulator 11 unlike the conventional design of FIG. 4 because the center of the outer radius of the weight body 12 does not deviate from the center of the rotor by making the inner radius portion of the protruding portion of one arc shape closely adhere to the outer radius portion of the upper substrate 8. The outer radius and the weight of the body (12) is well matched to the center of the rotor to prevent the occurrence of "burr" (Burr) generated by the resin insulator (11) to ride up the outer body of the weight (12) separately to "burr" The process of removing "(Burr) becomes unnecessary, and the manufacturing process is simplified.

1 is a cross-sectional view of a conventional brush type vibration motor.
2 is a three-dimensional view of a conventional brush type vibration motor.
3 is a conventional rotor three-dimensional view.
4 is another rotor stereoscopic view of the related art.
5 is a factor diagram of "Burr" generation in the conventional design.
6 is a plan view of an example of the present invention.
7 is a plan view of a modified example of the present invention.

In the present invention, at least a portion of the weight body 12 is assembled to the upper substrate 8 as shown in FIG. 6, while the outer radius of the weight body 12 is larger than the outer radius of the upper substrate 8, The outer radius of the weight body 12 by forming an arc-shaped protrusion toward the upper substrate 8 to make the inner radius of the arc-shaped protrusion equal to the outer radius of the upper substrate 8 at the site where the weight body 12 is assembled. The upper substrate 8 and the weight body 12 are bonded by filling the insulating resin 11 so as to match the outer radius of the insulating resin 11. The inner radius of the protrusion extending from the outer portion of the weight body 12 to the upper substrate 8 is in close contact with the outer radius of the upper substrate 8 so that the center of the outer radius of the weight body 12 does not deviate from the rotor center. It is possible to present a structure that becomes

7 introduces another modified example of the present invention. Even if an assembly error occurs from left to right at the center of the rotor, a difference between the outer radius of the weight body 12 and the outer radius of the insulating resin 11 does not occur. Therefore, the so-called "burr" is prevented from occurring, but the upper part is the same. It is an example in which a protrusion for guiding the left and right sides of the arc-shaped protrusion of the weight body 12 is added to the substrate 8 to increase work convenience when assembling the weight body 12 on the upper substrate 8.

1: bracket, 2: shaft, 3: case
4a, 4b: lead wire,
5a, 5b: end conductor wire of leader wire,
6: lower substrate
7a, 7b: brush, 8 upper substrate, 9: upper substrate commutator,
10: winding coil, 11: resin insulator
12: weight, 13: bearing,
14: upper washer, 15: lower washer
16: magnet

Claims (2)

A rotor in which a commutator pattern is installed on one surface and a coil and a weight body, the center of gravity of which is attached eccentrically to the center of rotation on an opposite surface of the upper substrate and molded with an injection resin; And
And a stator formed by attaching a case, a bracket, and a shaft and a magnet to form an outer portion.
Current is supplied to the commutator pattern and coil of the rotor through a brush installed on the stator side to generate vibration while rotating,
At the site where the weight is assembled on the upper substrate, the outer radius of the weight is larger than the outer radius of the upper substrate,
By forming an arc-shaped protrusion descending from the outer side of the weight body to the upper substrate side, the inner radius of the protrusion on the arc is equal to the outer radius of the upper substrate,
By making the outer radius of the weight body coincide with the outer radius of the insulated resin material, the outer radius of the insulated resin material is larger than the outer radius of the upper substrate, while the outer radius of the weight body and the outer radius of the insulating resin are brush-shaped vibrations. generator.
The method of claim 1,
Brush-type vibration generator further comprising a projection for guiding the left and right of the arc-shaped protrusion of the weight on the upper substrate.

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