KR20230093677A - Sound wave vibrator - Google Patents

Abstract

According to an embodiment of the present invention, a sound wave vibrator comprises: a housing; a coil which is installed in the housing to form a magnetic field in the vertical direction of the housing by applied voltage; a movable body which can vibrate in the vertical direction of the housing due to the magnetic field formed by the coil; a plate spring which is installed between the housing and the movable body, and can elastically deform in accordance with the movement of the movable body; and a support block which is installed between the plate spring and the movable body, and keeps the movable body spaced from the plate spring, wherein the height of the support block is set to be equal to or greater than the maximum amplitude of the movable body, thereby preventing the movable body from colliding with the plate spring during a vibration process of the movable body.

Description

Sound wave vibrator {SOUND WAVE VIBRATOR}

The following description relates to a sonic vibrator, and according to an embodiment, it is possible to prevent damage to a leaf spring and eliminate a cause of noise generation.

The vibrator is a device that periodically reciprocates. For example, we can think of an object hanging on a spring that reciprocates by the elastic force of the spring, or a pendulum that hangs on a string and reciprocates by gravity.

Acoustic wave vibrator, one of various types of vibrators, has attractive and repulsive forces according to the relationship between the magnetic field formed by the magnet and the magnetic field formed by the coil when a sinusoidal driving signal (voltage) is applied to the coil. It has a structure in which the magnet vibrates up and down by acting alternately.

Such a sound wave vibrator can be miniaturized in a small size, and recently, various products made using such a sound wave vibrator exist. For example, sonic vibrators are applied to various products such as mattresses, cushions, pillows, and various exercise equipment.

KR 10-2179266 B1

An object of an embodiment is to provide a sonic vibrator capable of preventing damage to a leaf spring and removing a cause of noise generation.

According to one embodiment, the acoustic vibrator may include a housing; a coil installed in the housing to form a magnetic field in a height direction of the housing by an applied voltage; a moving body capable of vibrating in a height direction of the housing by a magnetic field formed by the coil; a plate spring installed between the housing and the moving body and elastically deformable according to the movement of the moving body; and a support block installed between the leaf spring and the moving body to allow the moving body to be spaced apart from the leaf spring, and the height of the support block is equal to or greater than the maximum amplitude of the moving body. , It is possible to prevent the moving body from colliding with the plate spring during the vibration process of the moving body.

The support block may be integrally formed with the plate spring.

The plate spring includes an upper plate spring positioned on an upper side of the moving body and a lower plate spring positioned on a lower side of the moving body, and the support block includes an upper plate supporting block positioned between the upper plate spring and the moving body; and a lower plate support block positioned between the lower plate spring and the moving body, and the central position of the coil may be deviated from a central position between the upper plate support block and the lower plate support block based on the height direction of the housing. .

The housing may include an outer housing forming an appearance of the sound wave vibrator; and an inner housing installed inside the outer housing and sequentially disposed along the height direction of the outer housing to accommodate the upper plate spring, the upper plate support block, the moving body, the lower plate support block, and the lower plate spring. And, on the inner surface of the inner housing, (i) the coil shifted to one side along the height direction of the outer housing, and (ii) disposed in a space in the inner housing where the coil is not located, so that the coil A deviation block for supporting may be installed.

The plate spring, the central portion; an edge portion spaced outward from the central portion; and a connecting portion interconnecting the central portion and the rim portion, wherein the housing includes: an inner housing provided with an upper stepped portion accommodating at least a portion of the rim portion; and an end plate fixed to an upper side of the inner housing to prevent the rim portion accommodated in the upper stepped portion from being separated from the upper stepped portion.

According to an embodiment, by preventing an object vibrating inside the sound wave vibrator from colliding with the plate spring, damage to the plate spring may be prevented, and durability of the entire sound wave vibrator may be improved.

According to an embodiment, the sonic vibrator enables more quiet use by eliminating the cause of noise generation by preventing an object vibrating inside from colliding with a leaf spring.

According to an embodiment, by integrally forming a support block supporting the plate spring of the sound wave vibrator with the plate spring, it is possible to simplify the assembly process and improve product quality.

According to an exemplary embodiment, a sound wave vibrator having excellent efficiency may be provided as a result of intensifying the intensity of vibration through the offset structure of the coil.

According to one embodiment, since the upper plate spring and the lower plate spring can be easily assembled without a separate bonding process through the structure of the stepped portion formed on the inner housing, the convenience of assembly and maintenance can be greatly improved.

1 is a perspective view of a sound wave vibrator according to an exemplary embodiment.
2 is an exploded perspective view of a sound wave vibrator according to an exemplary embodiment.
3 is a cross-sectional view of a sound wave vibrator according to an exemplary embodiment.
4 is a bottom perspective view of an outer housing according to an embodiment.
5 is a bottom perspective view of an inner housing according to an embodiment.
6 is a view showing a shaft according to an embodiment.
7 is a bottom perspective view of an upper plate spring according to an embodiment.
8 is a top perspective view of an upper plate spring according to an embodiment.

Hereinafter, embodiments will be described in detail through exemplary drawings. In adding reference numerals to components of each drawing, it should be noted that the same components have the same numerals as much as possible even if they are displayed on different drawings. In addition, in describing the embodiment, if it is determined that a detailed description of a related known configuration or function hinders understanding of the embodiment, the detailed description will be omitted.

In addition, in describing the components of the embodiment, terms such as first, second, A, B, (a), and (b) may be used. These terms are only used to distinguish the component from other components, and the nature, order, or order of the corresponding component is not limited by the term. When an element is described as being “connected,” “coupled to,” or “connected” to another element, that element may be directly connected or connected to the other element, but there may be another element between the elements. It should be understood that may be "connected", "coupled" or "connected".

Components included in one embodiment and components having common functions will be described using the same names in other embodiments. Unless stated to the contrary, descriptions described in one embodiment may be applied to other embodiments, and detailed descriptions will be omitted to the extent of overlap.

1 is a perspective view of a sound wave vibrator according to an embodiment, FIG. 2 is an exploded perspective view of a sound wave vibrator according to an embodiment, and FIG. 3 is a cross-sectional view of the sound wave vibrator according to an embodiment.

Referring to FIGS. 1 to 3 , the sound wave vibrator 100 according to an embodiment may provide vibration to a user through a moving body 140 vibrating by a magnetic field formed by a coil 180 .

In this way, the sound wave vibrator 100 operated by a magnetic field can be miniaturized in a small size, and can be applied to various products such as mattresses, cushions, pillows, and various exercise equipment. Meanwhile, this is just an example, and products to which the sonic vibrator 100 is applied are not necessarily limited in this way.

The sound wave vibrator 100 includes housings 110, 120, and 130, movement bodies 140, leaf springs 150 and 160, support blocks 155 and 165, shafts 170, coils 180, and excursion blocks ( 185), an upper bolt 192 and a lower bolt 194.

The housings 110, 120, and 130 may accommodate other parts and provide a space in which the moving body 140 can vibrate. The housings 110 , 120 , and 130 may include an outer housing 110 , an inner housing 120 and an end plate 130 .

The outer housing 110 may form the external appearance of the sound wave vibrator 100 . The outer housing 110 may include a side surface 111 , a flange 112 and a lower surface 113 .

The flange 112 of the outer housing 110 is a portion protruding outward from the upper end of the side surface 111 of the outer housing 110 .

The side surface 111 of the outer housing 110 may be spaced apart from the side surface 121 of the inner housing 120 . According to this structure, it is possible to prevent a problem in which heat generated from the coil 180 installed in the inner housing 120 is directly transmitted to the user's hand. In addition, the function of cooling the coil 180 with air may be performed by using air circulating in a space between the side surface 111 of the outer housing 110 and the side surface 121 of the inner housing 120 .

The lower surface 113 of the outer housing 110 may be spaced apart from the lower end of the side surface 121 of the inner housing 120 . According to this structure, it is possible to prevent a problem in which the downward movement of the moving body 140 is interfered with by the lower surface 113 of the outer housing 110 .

The inner housing 120 may be installed inside the outer housing 110 . The inner housing 120 provides a space in which the moving body 140 and the coil 180 are disposed.

Inside the inner housing 120, an upper plate spring 150, an upper plate support block 155, a moving body 140, a lower plate support block 165 and a lower plate spring 160 are accommodated, and they are of the outer housing 110. They may be sequentially arranged from the top along the height direction. In addition, a coil 180 and a displacement block 185 may be installed on an inner surface of the inner housing 120 .

The inner housing 120 may include a side surface 121 , a flange 122 , an upper stepped portion 124 and a lower stepped portion 126 .

The flange 122 of the inner housing 120 is a portion protruding outward from the upper end of the side surface 121 of the inner housing 120, and is attached to the flange 112 and/or the end plate 130 of the outer housing 110. can be combined The flange 122 of the inner housing 120 may be located between the flange 112 of the outer housing 110 and the end plate 130, as shown. The two flanges 112 and 122 and the end plate 130 may be assembled to be in close contact with each other through coupling means (not shown) such as screws.

The upper stepped portion 124 is recessed from the flange 122 of the inner housing 120, so that at least a portion of the edge portion 152 of the upper plate spring 150 may be accommodated.

The lower stepped portion 126 is a portion protruding inward from the lower end of the side surface 121 and may support the rim portion of the lower plate spring 160 .

According to the structure of the upper stepped portion 124, the lower stepped portion 126, and the end plate 130 to be described later, the moving body 140 and the plate The springs 150 and 160 may be fixed within the housings 110 , 120 and 130 . Accordingly, in the process of assembling and maintaining, convenience can be remarkably increased.

Since the end plate 130 is fixed to the upper side of the inner housing 120 , it is possible to prevent the rim portion 152 accommodated in the upper stepped portion 124 from being separated from the upper stepped portion 124 . The end plate 130 may have a donut shape with a hollow inside so as not to hinder upward movement of the moving body 140 . The end plate 130 may have a ring shape having a width corresponding to the flange 122 of the inner housing 120 .

The movement body 140 may vibrate in the height direction of the housings 110 , 120 , and 130 by the magnetic field formed by the coil 180 . The moving body 140 may include a magnet 141 , an upper magnet protection plate 142 and a lower magnet protection plate 143 .

The magnet 141 may be disposed to form a magnetic field in a height direction of the housings 110 , 120 , and 130 . Depending on the relationship between the magnetic field formed by the magnet 141 and the magnetic field formed by the coil when a sine wave driving signal (voltage) is applied to the coil 180, the gap between the magnet 141 and the coil 180 At , attraction and repulsion act alternately. Accordingly, the magnet 141 may vibrate up and down along the height direction of the housings 110 , 120 , and 130 .

The upper magnet protection plate 142 may be positioned between the upper side of the magnet 141 and the upper plate support block 155 . The upper magnet protection plate 142 may have, for example, a diameter greater than that of the magnet 141 . According to the upper magnet protection plate 142, it is possible to prevent damage to the magnet 141 due to direct contact with the outside.

The lower magnet protection plate 143 may be positioned between the lower side of the magnet 141 and the lower support block 165 . Unless stated to the contrary, it should be noted that the description of the upper magnet protection plate 142 can also be applied to the lower magnet protection plate 143.

The plate springs 150 and 160 are installed between the housings 110 , 120 and 130 and the moving body 140 and can be elastically deformed according to the movement of the moving body 140 . For example, the plate springs 150 and 160 may be formed of non-magnetic materials such as non-ferrous metals or synthetic resins (eg, acetal, PE or PC).

The plate springs 150 and 160 may include an upper plate spring 150 located on the upper side of the moving body 140 and a lower plate spring 160 located on the lower side of the moving body 140 .

As shown in FIG. 3 , the diameter of the upper plate spring 150 is larger than that of the lower plate spring 160, so that it can be accommodated and assembled to the above-described upper stepped portion 124. It is revealed that the upper plate spring 150 and the lower plate spring 160 may be formed in a mutually symmetrical shape, and the description of the upper plate spring 150 can be applied to the lower plate spring 160 as long as there is no description to the contrary. put

The support blocks 155 and 165 are installed between the leaf springs 150 and 160 and the moving body 140 to allow the moving body 140 to be spaced apart from the leaf springs 150 and 160 . The support blocks 155 and 165 include the upper plate support block 155 located between the upper plate spring 150 and the moving body 140 and the lower plate support block 165 located between the lower plate spring 160 and the moving body 140. ) may be included. The upper plate support block 155 and the lower plate support block 165 may be formed in mutually symmetrical shapes as shown.

For example, the support blocks 155 and 165 may be integrally formed with the plate springs 150 and 160 . In this way, when the support blocks 155 and 165 are integrally formed with the plate springs 150 and 160, as the number of assembly parts decreases, the convenience of assembly can be increased and errors in the manufacturing process can be reduced. In addition, it has the advantage of being able to fundamentally block problems such as noise and tolerance due to the gap that may exist between two adjacent parts.

Meanwhile, instead of integrally forming the support blocks 155 and 165 with the plate springs 150 and 160, it should be noted that a method of integrally forming a part of the shaft 170 shown in FIG. 3 is also possible. However, in this case, in the hollow formed in the moving body 140, the upper part (upper support block 155 and the upper part of the shaft 170) and the lower part (lower support block 165 and the lower part of the shaft 170) part) must provide a mutually interlocking structure, there is a difficulty in that the difficulty of manufacturing each part is significantly increased compared to the illustrated embodiment. In addition, as the difficulty of manufacturing increases, there is a problem in that manufacturing tolerances increase more than expected. Therefore, as shown, it is better to provide the upper support block 155 and the lower support block 165 fitted in the same form on both sides around one shaft 170 of a simple shape, in terms of manufacturing cost and effort. may have an advantage in

Meanwhile, it should be noted that the support blocks 155 and 165 and the plate springs 150 and 160 may be formed as separate parts and assembled.

On the other hand, the vertical vibration of the moving body 140 is transmitted to the leaf springs 150 and 160 through the support blocks 155 and 165, and the moving body 140, the leaf springs 150 and 160 and the support blocks 155, 165) to vibrate in the vertical direction. At this time, the vertical vibration distance (amplitude) is determined by various factors (eg, the length of the connecting portion 153 (see FIG. 8), the material of the plate springs 150 and 160, the strength of the voltage applied to the coil 180, and the magnet 141 ) of the magnetic force strength, etc.).

If the intended amplitude is greater than the vertical width of the support blocks 155 and 165, the edge of the upper magnet protection plate 142 is the most opposite surface of the upper plate spring 150 during the upward vibration of the moving body 140. As the edge of the lower magnet protection plate 143 collides with the edge of the facing surface of the lower plate spring 160 during the downward vibration of the moving body 140, noise and damage to the magnet 141 etc. will occur.

To solve this problem, the heights of the support blocks 155 and 165 may be set equal to or greater than the maximum amplitude of the moving body 140 . According to this structure, it is possible to prevent the moving body 140 from colliding with the plate springs 150 and 160 during the vibration process of the moving body 140 .

The shaft 170 passes through the plate springs 150 and 160, the support blocks 155 and 165, and the moving body 140, and allows them to be aligned in correct positions. At both ends of the shaft 170, an upper bolt 192 and a lower bolt 194 having a head having a larger diameter than the diameter of the hole formed in the upper plate spring 150 and the diameter of the hole formed in the lower plate spring 160, respectively, are fastened. It can be.

The coil 180 is installed in the housings 110 , 120 , and 130 and may form a magnetic field in a height direction of the housings 110 , 120 , and 130 by an applied voltage. For example, the coil 180 may be provided in a form in which a protective wrap is covered in a form in which a wire is wound. The coil 180 may be attached to the inner surface of the inner housing 120 by a bonding method or the like.

For example, the coil 180 may be shifted to one side along the height direction of the outer housing 110 as shown in FIG. 3 . In other words, the central position of the coil 180 is the central position between the upper plate support block 155 and the lower plate support block 165 (in other words, the magnet ( 141). For example, the length of the entire coil 180 in the height direction is smaller than the length of the inner housing 120 in the height direction, and the coil 180 may not be disposed below the inner housing 120 .

In this way, when the center of the coil 180 is arranged to deviate from the center of the magnet 141, the direction of the force applied to the magnet 141 by the magnetic force formed by the coil 180 is that of the magnet 141. It is formed in a direction close to the direction of vibration (vertical direction) so that a greater force can be applied to the magnet 141 in the direction of vibration. In addition, compared to the case where the coil is formed to cover the entire inner surface of the inner housing 120, the same or greater force can be applied to the magnet 141 while reducing the amount of coil material.

Meanwhile, it should be noted that the moving body 140 instead of the coil 180 may be displaced in the height direction with respect to the inner housing 120 . However, in the limited inner space of the inner housing 120, the center of the moving body 140 is arranged to coincide with the center of the inner housing 120 so that the moving body 140 can secure the maximum amplitude. It is advantageous in terms of miniaturization and improvement of vibration performance.

The deviation block 185 may be disposed in a space where the coil 180 is not located within the inner housing 120 to support the coil 180 . For example, the offset block 185 may be formed of a non-magnetic material such as synthetic resin (eg, acetal).

The upper bolt 192 may fix the upper plate spring 150 so that the upper plate spring 150 is not separated from the shaft 170 .

The lower bolt 194 may fix the lower plate spring 160 so that the lower plate spring 160 is not separated from the shaft 170 .

Meanwhile, since the upper plate support block 155, the movement body 140, and the lower plate support block 165 are disposed between the upper plate spring 150 and the lower plate spring 160, as a result, the upper bolt 192 and the lower bolt 194 According to ), it is possible to prevent the upper plate spring 150, the upper plate support block 155, the movement body 140, the lower plate support block 165, and the lower plate spring 160 from being separated from the shaft 170. In this state, the edge portion of the upper plate spring 150 is inserted into the upper stepped portion 124 and can be prevented from escaping to the outside by the end plate 130 . According to the structure described above, since it is possible to assemble the acoustic vibrator 100 without resorting to a coupling method such as bonding, the operator's assembly convenience can be remarkably improved.

4 is a bottom perspective view of an outer housing according to an embodiment, and FIG. 5 is a bottom perspective view of an inner housing according to an embodiment.

Referring first to FIG. 4 , an outer housing 110 according to an embodiment may include a side surface 111 , a flange 112 and a lower surface 113 .

A plurality of radially spaced holes may be formed in the side surface 111 and the lower surface 113 of the outer housing 110 . Such a hole helps dissipate heat generated in the coil 180 .

Referring next to FIG. 5 , the inner housing 120 according to an embodiment may include a side surface 121 , a flange 122 and a lower stepped portion 126 .

Similarly, a plurality of radially spaced holes may be formed on the side surface 121 of the inner housing 120, and such holes help to dissipate heat generated from the coil 180.

Meanwhile, in the case of the inner housing 120, the rest of the lower side other than the lower stepped portion 126 has an open shape. According to this shape, it is possible to have a more excellent heat dissipation effect while maximally preventing the movement of the lower plate spring 160 from being interfered with.

Meanwhile, in a state in which the outer housing 110 and the inner housing 120 are coupled, holes formed on the side surfaces of the respective housings 110 and 120 may be staggered when viewed from the side. According to this shape, it is possible to have a relatively uniform heat dissipation performance in a radial direction while avoiding a problem in which durability of the entire acoustic wave vibrator 100 is reduced due to unnecessarily many holes being formed.

6 is a view showing a shaft according to an embodiment.

Referring to FIG. 6 , the shaft 170 according to an embodiment may have a cylindrical outer surface. An upper female screw part 171 to which the upper bolt 192 is coupled and a lower female screw part 172 to which the lower bolt 194 is coupled may be formed on an inner surface of the shaft 170 .

According to the shaft 170, components between the upper plate spring 150 and the lower plate spring 160, including the magnet 141, can be coupled to each other without directly forming a female screw portion in the magnet 141, which is difficult to process. can

For example, the shaft 170 may be integrally formed with other adjacent parts, for example, the upper plate support block 155 or the lower plate support block 165 . However, when considering manufacturing convenience and manufacturing precision of each component, it may be more advantageous to divide and assemble into simple shapes as in the present.

7 is a bottom perspective view of an upper plate spring according to an embodiment, and FIG. 8 is a top perspective view of an upper plate spring according to an embodiment.

7 and 8, the top plate spring 150 according to an embodiment includes a central portion 151, an edge portion 152 spaced outward from the central portion 151, a connection portion 153, and a reinforcing portion 154 ) may be included.

The connecting portion 153 may connect the central portion 151 and the edge portion 152 to each other. For example, since the connecting portion 153 is formed in a curved shape rather than a straight line, the total length may be longer than the distance between the central portion 151 and the edge portion 152 . In other words, when there is a right triangle having the distance between the central portion 151 and the edge portion 152 as the "base" and the amplitude of the moving body 140 as the "height", the connecting portion 153, It may have a length equal to or greater than the length corresponding to the distance of the “hypotenuse” of the aforementioned right triangle.

For example, the connecting portion 153 may have a shape bent multiple times. According to this structure, the maximum movable distance of the central portion 151 compared to the edge portion 152 can be further increased. As the maximum operating distance increases in this way, the sound wave vibrator 100 can generate stronger vibration.

For example, the thickness of the connecting portion 153 may be greater than that of the central portion 151 and the edge portion 152 .

The reinforcing part 154 serves to reinforce a weak part in the upper plate spring 150 against fatigue failure. The reinforcing portion 154 may be understood as a portion protruding over any one or more of the central portion 151 , the edge portion 152 , and the connection portion 153 . Based on the movement direction of the moving body 140, the thickness of the part where the reinforcing part 154 is formed among the upper plate springs 150 may be thicker than the part where the reinforcing part 154 is not formed. According to the reinforcing part 154, since the cross-sectional area of the member is increased, the load value for the repeated load can be reduced, and as a result, the durability of the entire upper plate spring 150 can be improved.

The reinforcement part 154 may include a center-side reinforcement part 1541 and an edge-side reinforcement part 1542 .

The central reinforcing part 1541 may be formed at a portion where the central part 151 and the connection part 153 are interconnected. For example, the central reinforcement part 1541 may be formed across the central part 151 and the connection part 153 . According to the center-side reinforcing portion 1541, the problem of the connecting portion 153 being cut from the central portion 151 can be significantly reduced. A cross-sectional area of an end portion of the central reinforcing portion 1541 toward the central portion 151 may decrease toward the central portion 151 .

The rim-side reinforcement part 1542 may be formed at a portion where the rim part 152 and the connection part 153 are interconnected. For example, the edge-side reinforcement part 1542 may be formed across the edge part 152 and the connection part 153 . According to the edge-side reinforcing portion 1542, a problem in which the connection portion 153 is cut from the edge portion 152 can be significantly reduced. A cross-sectional area of an end portion of the edge-side reinforcing portion 1542 toward the edge portion 152 may decrease toward the edge portion 152 .

Meanwhile, as shown in FIG. 8 , the center-side reinforcement part 1541 and the edge-side reinforcement part 1542 are spaced apart from each other, and the reinforcement part 154 may not be formed between them. According to this structure, as the material is additionally injected into an area where reinforcement is relatively unnecessary (eg, the center area of the connecting portion 153), the effect of vibration is weakened and waste of material can be prevented.

For example, the reinforcing parts 1541 and 1542 are deflected closer to the inside than the outside of the bent part (ie, close to the part with a large curvature) based on the width direction of the connecting part 153. can be located (see Fig. 8). According to such a structure, material consumption can be reduced in preparation for a case where material is reinforced across the entire width direction of the connecting portion 153 . In addition, such a structure selectively reinforces the weakest part (that is, the part where the stress is most concentrated) in consideration of the notch effect, and substantially the entire width direction of the connecting portion 153. It can be expected to improve the product life to a level similar to that of reinforcement over the period. Furthermore, as the cross-sectional area of the connecting portion 153 widens, the strength of the vibration formed by the sound wave vibrator 100 weakens. driving efficiency can be improved.

Unless otherwise stated, the description of the upper plate spring 150 can be applied to the lower plate spring 160 as well. The lower plate spring 160 may also include the aforementioned central portion, rim portion, connection portion, and reinforcement portion. A detailed description of the lower plate spring 160 will be omitted.

As described above, although the embodiments have been described with limited drawings, those skilled in the art can make various modifications and variations from the above description. For example, the described techniques may be performed in an order different from the described method, and/or components of the described structure, device, etc. may be combined or combined in a different form from the described method, or other components or equivalents may be used. Appropriate results can be achieved even if substituted or substituted by

100: sonic vibrator
110: outer housing
111: side
112: flange
113: bottom
120: inner housing
121: side
122: flange
124: upper step part
126: lower step
130: end plate
140: exercise body
141: magnet
142: upper magnetic protection plate
143: lower magnetic protection plate
150: top plate spring
151: central part
152: border
153: connection part
154: reinforcement part
1541: center side reinforcement part
1542: Rim side reinforcement part
155: upper plate support block
160: lower plate spring
165: lower plate support block
170: shaft
171: upper female screw part
172: lower female thread
180: coil
185: deviation block
192: upper bolt
194: lower bolt

Claims (5)

housing;
a coil installed in the housing to form a magnetic field in a height direction of the housing by an applied voltage;
a moving body capable of vibrating in a height direction of the housing by a magnetic field formed by the coil;
a plate spring installed between the housing and the moving body and elastically deformable according to the movement of the moving body; and
A support block installed between the leaf spring and the moving body to allow the moving body to be spaced apart from the leaf spring,
The height of the support block is set equal to or greater than the maximum amplitude of the moving body to prevent the moving body from colliding with the plate spring during the vibration of the moving body. According to claim 1,
The sound wave vibrator, characterized in that the support block is integrally formed with the leaf spring. According to claim 1,
The plate spring includes an upper plate spring located on the upper side of the moving body and a lower plate spring located on the lower side of the moving body,
The support block includes an upper plate support block positioned between the upper plate spring and the moving body, and a lower plate supporting block positioned between the lower plate spring and the moving body,
The acoustic vibrator, characterized in that the central position of the coil is offset from the central position between the upper plate support block and the lower plate support block based on the height direction of the housing. According to claim 3,
the housing,
an outer housing forming an exterior of the sound wave vibrator; and
Including an inner housing installed inside the outer housing and accommodating the upper plate spring, the upper plate support block, the moving body, the lower plate support block, and the lower plate spring sequentially disposed along the height direction of the outer housing; ,
On the inner surface of the inner housing, (i) the coil shifted to one side along the height direction of the outer housing, and (ii) disposed in a space in the inner housing where the coil is not located to support the coil. Acoustic vibrator, characterized in that the displacement block for the installation. According to claim 1,
The leaf spring,
central part;
an edge portion spaced outward from the central portion; and
A connection portion interconnecting the central portion and the edge portion,
the housing,
an inner housing provided with an upper step portion accommodating at least a portion of the rim portion; and
and an end plate fixed to an upper side of the inner housing to prevent the rim portion accommodated in the upper stepped portion from being separated from the upper stepped portion.

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