KR20230129656A - Horizental vibration motor - Google Patents

Abstract

According to one aspect of the embodiment, a housing provided with a receiving space; a stator fixed to the housing and including a coil assembly that generates an electromagnetic field; An oscillator including a plurality of magnets that vibrate by interaction with the electromagnetic field of the coil assembly; and at least one pair of elastic parts in the housing to cushion and support the vibrator, wherein the vibrator has at least one pair of grooves on which the elastic parts are mounted and provided to provide a mounting space between the housing and the housing. Provides a horizontal vibration motor comprising:

Description

HORIZENTAL VIBRATION MOTOR}

The embodiment relates to a horizontal vibration motor, and in particular, to a horizontal vibration motor that can maximize the accommodation space of the housing.

Recently, small electronic products such as portable communication devices, portable game consoles, portable MP3 players, and small home game consoles have been developed. The small electronic products mentioned above include a display device for transmitting information as an image and a sound device for transmitting information as a voice. Recently, vibration motors to transmit information using vibration are being installed in small electronic products.

Vibration motors installed in small electronic products are required not only to be small in size but also to have the ability to generate strong vibrations.

The embodiments aim to solve the above-described problems and other problems.

The purpose of the embodiment is to provide a horizontal vibration motor that can maximize the accommodation space of the housing.

According to one aspect of the embodiment, a housing provided with a receiving space; a stator fixed to the housing and including a coil assembly that generates an electromagnetic field; An oscillator including a plurality of magnets that vibrate by interaction with the electromagnetic field of the coil assembly; and at least one pair of elastic parts in the housing to cushion and support the vibrator, wherein the vibrator has at least one pair of grooves on which the elastic parts are mounted and provided to provide a mounting space between the housing and the housing. Provides a horizontal vibration motor comprising:

According to one aspect of the embodiment, a stopper installed in the mounting space to limit displacement of the vibrator may be further included.

According to one aspect of the embodiment, the vibrator further includes a weight block in which a through hole is formed, a yoke plate accommodated in the through hole and fixing the magnets, and the groove portion may be provided in the weight block.

According to one aspect of the embodiment, the weight block may further include a protrusion formed to protrude toward the housing to limit displacement of the elastic portion.

According to one aspect of the embodiment, the protrusion may be formed closer to the housing than the stopper.

According to one aspect of the embodiment, the grooves may be formed in at least two places on both sides of the upper and lower surfaces of the weight block.

According to one aspect of the embodiment, the elastic unit includes a housing fixed end fixed to the housing and a vibrator fixed end fixed to the vibrator side groove, and the mounting space may be formed between the vibrator fixed end and the housing. .

According to one aspect of the embodiment, the vibrator fixed end may be positioned parallel to the housing fixed end at a different height from the housing fixed end.

According to one aspect of the embodiment, the elastic part may further include a connection part that connects the housing fixed end and the vibrator fixed end and is disposed parallel to one side wall of the housing.

According to an embodiment, by mounting the elastic part and the stopper for cushioning and supporting the vibrator in the groove formed in the weight block, the installation space of the elastic part and the stopper inside the housing is minimized, making it possible to miniaturize the horizontal vibration motor, and the accommodation space of the housing Not only does it maximize the

1 is an exploded perspective view showing a horizontal vibration motor of one embodiment.
Figure 2 is a side cross-sectional view showing a horizontal vibration motor of one embodiment.
Figures 3 and 4 are perspective views of the weight block applied to one embodiment as seen from the top and bottom, respectively.
Figure 5 is a perspective view showing an elastic portion applied to one embodiment.
Figures 6 and 7 are diagrams showing an example of a mounting structure of an elastic part applied to an embodiment.
Figures 8 and 9 are diagrams showing another example of an elastic part mounting structure applied to an embodiment.

Hereinafter, this embodiment will be examined in detail with reference to the accompanying drawings.

FIG. 1 is an exploded perspective view showing a horizontal vibration motor of one embodiment, and FIG. 2 is a side cross-sectional view showing a horizontal vibration motor of one embodiment.

The horizontal vibration motor of one embodiment includes a housing 100 forming an accommodation space, a fixing plate 210 fixed to the housing 100 and provided with a plurality of poles 211a, 211b, and 211c, and a plurality of poles 211a. , 211b, 211c), a coil winding body 220 on which a coil is selectively wound, an F-PCB 230 that supplies current to the coil winding body 220, and poles provided with the coil winding body 220 ( A plurality of magnets 311 and 312 installed opposite to 211a and 211c), a weight block 320 in which the magnets 311 and 312 are accommodated, and a yoke plate 330 that secures the magnets 311 and 312 to the weight block 320. It may include an elastic portion 410 and a stopper (S) that cushion and support the weight block 320 to the housing 100.

The housing 100 has a rectangular parallelepiped shape and consists of an upper case 110 forming a top surface and a plurality of side surfaces, and a lower case 120 forming a bottom surface, and the inside of the upper case 110 and the lower case 120 Accommodation space may be provided. Since the upper case 110 and lower case 120 are made of a ferromagnetic material, leakage of magnetic force to the outside can be prevented.

A plurality of poles (211a, 211b, 211c) are formed in a row on the fixing plate 210 at predetermined intervals, and the coil winding body 220 is provided on some or all of the poles (211a, 211b, 211c). Coil assemblies 210 and 220 can be configured.

The F-PCB 230 is a circuit board electrically connected to the coil winding body 220, and may be installed to extend from one side of the fixing plate 210 to the outside of the housing 100. By supplying current to the coil winding body 220 from the outside through the F-PCB 230, electromagnetic force can be generated in the coil assemblies 210 and 220.

The fixing plate 210 is made of a ferromagnetic material, and the yoke portion 210 is provided to protrude downward integrally with the fixing plate 210, so that the magnetic flux generated in the coil 220 can be effectively drawn out. The yoke portion 212 is located inside the hole 121 provided at the center of the lower case 110, and the fixing plate 210 may be fixed to the upper surface of the lower case 110. A plurality of poles 211a, 211b, and 211c and the yoke portion 212 may be formed integrally with the fixing plate 210.

In this way, the stator 200 may be composed of an assembly of the fixing plate 210, the coil winding body 220, and the F-PCB 230, and as current is supplied to the coil winding body 220, the stator 200 ) can form a magnetic field.

The magnets 311 and 312 are provided on the upper side of the poles 211a and 211c on which the coil winding body 220 is provided, and may be provided to face each other in the vertical direction at a predetermined interval.

The yoke plate 330 is a ferromagnetic material, and the magnets 330 may be fixed to the lower side of the yoke plate 330 while being spaced apart from each other. The yoke plate 330 prevents the magnetic field generated from the magnets 311 and 312 from leaking upward and at the same time directs the magnetic field toward the lower coil windings 220, thereby improving the driving efficiency of the horizontal vibration motor. .

The weight block 320 is provided with a through hole 321 that is stepped in the vertical direction at the center, and the magnets 311 and 312 and the yoke plate 330 can be fixed to the through hole 321. The weight block 320 is combined with the magnets 311 and 312 to increase the amount of vibration.

In this way, the vibrator 300 may be composed of an assembly of magnets 311 and 312, a weight block 320, and a yoke plate 330.

The elastic portion 410 cushions and supports the vibrator 300 to the housing 100 and can be fixed to the lower case 110 and the weight block 320, which will be described in detail below.

The stopper (S) may be provided to limit excessive displacement of the vibrator 300 due to external shock. The stopper (S) may be mounted on the lower side of the weight block 320 and may be provided to maintain a predetermined distance from the lower case 120. Accordingly, the stopper S first collides with the lower case 120 due to an external impact, thereby preventing damage to the components constituting the vibrator 300.

According to the horizontal vibration motor configured as above, attractive and repulsive forces are generated between the electromagnetic field generated from the coil winding body 220 wound around the plurality of poles 211a, 211b, and 211c and the polarities of the magnets 311 and 312, and this causes As a result, the vibrator 300 may vibrate while moving to the left or right with respect to the stator 200. Since the installation positions of the coil winding body 220 and the magnets 311 and 312 can be configured in various ways, the sections that generate attractive and repulsive forces can be configured in a wide and diverse manner, and the amount of vibration can be further improved.

Figures 3 and 4 are perspective views of the weight block applied to one embodiment as seen from the top and bottom, respectively.

As shown in FIGS. 2 to 4, the weight block 320 is in the form of a square block that can be built into the internal space of the housing 100, and has a stepped shape that penetrates the center of the weight block 320 in the vertical direction. A through hole 321 may be provided. The lower space 321a of the through hole is formed relatively wide so that the coil winding bodies 220 can be built in, and the upper spaces 321b and 321c of the through hole 321 are formed to be stepped so that the magnets 311 and 312 are seated. The yoke plate 330 can be fixed.

Grooves 322 may be provided on both sides of the lower surface of the weight block 320. The groove portion 322 has a square shape and may be formed to be open to one side of the weight block 320, and may provide a mounting space (A) for the elastic portion (410) and the supporter (S).

A protrusion 323 may be provided between the through hole 321 and the grooves 322 on the lower surface of the weight block 320. The protrusion 323 is thin and widely protruding, and can limit the displacement of the elastic part 410 and effectively secure the mounting space A for the supporter S between the groove 322 and the protrusion 323. You can.

By configuring the vibrator in a form in which the magnets 311 and 312 and the yoke plate 320 are fixed to the weight block 320 configured as above, vibration can be strongly implemented by increasing the weight of the vibrator 300, and the elastic part The mounting space (A) for (410) and the supporter (S) can be secured inside the weight block 320, making it possible to miniaturize the horizontal vibration motor.

Figure 5 is a perspective view showing an elastic portion applied to one embodiment.

As shown in Figures 2 and 5, the elastic part 410 is a type of leaf spring, and includes a housing fixing part 411 forming one end, a vibrator fixing part 412 forming the other end, and a housing fixing part ( It may be composed of a connection part 413 connected between 411) and the vibrator fixing part 412.

The housing fixing part 411 is positioned parallel to each other at a lower position than the vibrator fixing part 412, and the connection part 413 transmits vibration to a plane perpendicular to the housing fixing part 411 and the vibrator fixing part 412. It can be positioned to form a long path.

According to the elastic part 410 configured as described above, the housing fixing part 411 is welded and fixed to the bottom surface of the lower case 120, and the vibrator fixing part 412 is welded and fixed to the groove 322 of the weight block, By installing the connection portion 413 opposite to one side of the upper case 110, the installation space for the elastic portion 410 inside the housing 100 can be minimized.

Figures 6 and 7 are diagrams showing an example of a mounting structure of an elastic part and a supporter applied to an embodiment.

According to an example of the mounting structure, grooves 322 are provided on both sides of the lower surface of the weight block 320, and a mounting space A is formed between the grooves 322 of the weight block and the lower case 120. You can.

Mounting spaces A may be provided on both sides of the lower part of the weight block 320. The elastic portion 410 and the stopper (S) may be installed on both sides of the lower part of the weight block 320, that is, in the mounting spaces (A).

In order to make the mounting space A wider, the groove portion 322 may be configured to be open on two sides of the weight block 320, and may be formed in various ways within the weight block 320.

One end of the elastic part 410, that is, the housing fixed end 411, is fixed to the lower case 120, and the other end of the elastic part 420, that is, the vibrator fixed end 412, is fixed to the groove 322 of the weight block. And the connection portion 413 of the elastic portion may face one side of the upper case 110.

A predetermined mounting space A may be formed between the groove 322 of the weight block, that is, the vibrator fixing end 412 and the lower case 120, and between the housing fixing end 411 and the vibrator fixing end 412. It can be secured by the height of .

The supporter (S) may be fixed to the lower side of the vibrator fixing end 412 so as to be located in the mounting space (A). The supporter (S) is installed to be spaced apart from the lower case 120 by a predetermined distance, and may be placed closer to the lower case 120 than the protrusion 323 of the weight block. Even if an external shock is applied, the supporter S comes into contact with the lower case 120 first, thereby limiting the displacement of the vibrator and preventing damage to the components of the vibrator.

Figures 8 and 9 are diagrams showing another example of a mounting structure of an elastic part and a supporter applied to an embodiment.

According to another example of the mounting structure, a first groove 322 is provided on one side of the lower surface of the weight block 320 and a second groove 324 is provided on the other side of the upper surface of the weight block 320, and the first groove of the weight block ( A first mounting space (not shown) is formed between 322) and the lower case 120, and at the same time, a second mounting space (A') is formed between the second groove 324 of the weight block and the upper case 110. You can.

The first mounting space (not shown) may be provided on one lower side of the weight block 320, and the second mounting space (A') may be provided on the other upper side of the weight block 320. The elastic portion 410 and the stopper (S) are located on one lower side of the weight block 320, that is, the first mounting space (not shown), and the other upper side of the weight block 320, that is, the second mounting space (A'), respectively. Can be installed.

The first and second mounting spaces (A', not shown) can be formed in various ways within the weight block 320, and are not limited.

The structure in which the elastic part 410 and the supporter (S) are installed in the first mounting space (not shown) is the same as an example of the mounting structure, and the elastic part 410 and the supporter (S) are installed in the second mounting space (A') ) is installed, only the direction has changed, so detailed explanation will be omitted.

The above description is merely an illustrative explanation of the technical idea of the present invention, and various modifications and variations will be possible to those skilled in the art without departing from the essential characteristics of the present invention.

Accordingly, the embodiments disclosed in the present invention are not intended to limit the technical idea of the present invention, but rather to explain it, and the scope of the technical idea of the present invention is not limited by these embodiments.

The scope of protection of the present invention should be interpreted in accordance with the claims below, and all technical ideas within the equivalent scope should be construed as being included in the scope of rights of the present invention.

110: upper case 120: lower case
200: stator 210: fixed plate
211a, 211b, 211c: pole 212: yoke part
220: Coil winding body 230: F-PCB
300: Vibrator 311,312: Magnet
320: Weight block 330: Yoke plate
410: elastic part

Claims (9)

A housing provided with a receiving space;
a stator fixed to the housing and including a coil assembly that generates an electromagnetic field;
An oscillator including a plurality of magnets that vibrate by interaction with the electromagnetic field of the coil assembly; and
It consists of at least one pair of elastic parts in the housing that cushion and support the vibrator,
The vibrator is,
A horizontal vibration motor including at least one pair of grooves on which the elastic parts are mounted and provided to provide a mounting space between the housing and the housing. According to paragraph 1,
A horizontal vibration motor further comprising a stopper installed in the mounting space to limit displacement of the vibrator. According to paragraph 2,
The vibrator is,
A weight block with a through hole formed,
Further comprising a yoke plate accommodated in the through hole and fixing the magnets,
The groove part is,
A horizontal vibration motor provided on the weight block. According to paragraph 3,
The weight block is,
A horizontal vibration motor further comprising a protrusion formed to protrude toward the housing to limit displacement of the elastic portion. According to paragraph 4,
The protrusion is,
A horizontal vibration motor formed closer to the housing than the stopper. According to paragraph 3,
The grooves are,
A horizontal vibration motor formed on at least two sides of the upper and lower surfaces of the weight block. According to paragraph 1,
The elastic part,
A housing fixed end fixed to the housing,
It includes a vibrator fixing end fixed to the vibrator side groove,
A horizontal vibration motor in which the mounting space is formed between the vibrator fixed end and the housing. In clause 7,
The vibrator fixed end is,
A horizontal vibration motor positioned parallel to the housing fixed end and at a different height from the housing fixed end. According to clause 8,
The elastic part,
A horizontal vibration motor further comprising a connection part connected between the housing fixed end and the vibrator fixed end and disposed parallel to one side wall of the housing.

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