A system and method for optimizing horn sound

By installing an anti-vibration module on the speaker bracket and using a hydraulic transmission oil system and spiral beryllium copper wire to control the vibration, the problems of noise and loose parts caused by speaker vibration are solved, thereby optimizing the speaker's sound quality and extending its service life.

CN117812507BActive Publication Date: 2026-06-23NANJING LIUJIE VEGETABLE BASKET NETWORK TECH CO LTD

Patent Information

Authority / Receiving Office
CN · China
Patent Type
Patents(China)
Current Assignee / Owner
NANJING LIUJIE VEGETABLE BASKET NETWORK TECH CO LTD
Filing Date
2023-12-28
Publication Date
2026-06-23

AI Technical Summary

Technical Problem

Existing speakers lack structures to reduce vibrations, which causes noise to be generated when components touch each other, affecting sound quality and potentially causing parts to loosen or fall off.

Method used

An anti-vibration module is installed on the horn bracket, including an outer cylinder, rubber block, movable column and hydraulic transmission oil system. Through the pressure control of hydraulic transmission oil and the synergistic effect of spiral beryllium copper wire, vibration is reduced and component contact is prevented.

Benefits of technology

It effectively reduces speaker vibration, lowers noise, prevents parts from loosening and falling off, extends the speaker's lifespan, and ensures optimized sound quality.

✦ Generated by Eureka AI based on patent content.

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Abstract

The application provides a kind of loudspeaker sound optimization system and method, belongs to loudspeaker technical field, containing loudspeaker support, the loudspeaker support is equipped with loudspeaker body, the outside of the loudspeaker support is fixedly connected with connecting outer ring;The outer circumferential surface of the connecting outer ring is fixedly connected with assembly outer ring, and the assembly outer ring is reserved with mounting hole;The upper and lower two side rods on the loudspeaker support are equipped with anti-oscillation module;The other end of the anti-oscillation module is equipped with assembly rod.The application solves the problem that the existing loudspeaker lacks structure to reduce oscillation, and the loudspeaker will produce oscillation during work, which will cause the components to touch each other, and noise will be generated when touching, which will cause the sound quality played by the loudspeaker to deteriorate during work, and the oscillation will also cause the connection between parts to be loose or even detached.
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Description

Technical Field

[0001] This invention belongs to the field of loudspeaker technology, specifically relating to a loudspeaker sound optimization system and method. Background Technology

[0002] A loudspeaker, also known as a loudspeaker, is a commonly used electroacoustic transducer found in almost every sound-producing electronic and electrical device. While it is the weakest component in an audio system, it is also one of the most crucial for sound quality. Loudspeakers come in many varieties and vary greatly in price. Audio energy, through electromagnetic, piezoelectric, or electrostatic effects, causes the cone or diaphragm to vibrate and resonate with the surrounding air, thus producing sound.

[0003] Existing loudspeakers lack structures to mitigate vibrations. During operation, the loudspeaker vibrates, causing components to come into contact with each other, generating noise. This noise degrades the sound quality of the loudspeaker and can also cause connections between components to loosen or even detach. Summary of the Invention

[0004] This invention provides a system and method for optimizing speaker sound. Its purpose is to solve the problem that existing speakers lack structures to reduce vibration. During operation, the speaker will vibrate, which will cause parts to touch each other and generate noise. This noise will degrade the sound quality played by the speaker. At the same time, the vibration may also cause the connection between the parts to loosen or even fall off.

[0005] This invention provides a speaker sound optimization system, including a speaker bracket, on which a speaker body is mounted, and a connecting outer ring is fixedly connected to the outer side of the speaker bracket;

[0006] An assembly outer ring is fixedly connected to the outer circumferential surface of the connecting outer ring, and the assembly outer ring has pre-drilled mounting holes.

[0007] Anti-vibration modules are installed on both the upper and lower side rods of the speaker bracket;

[0008] An assembly rod is installed at the end of the anti-vibration module away from the side rod.

[0009] Furthermore, the cross-section of the connecting outer ring is wavy, and the connecting outer ring is made of rubber.

[0010] Furthermore, the upper and lower sets of anti-vibration modules are located on the same vertical line, and the directions of the upper and lower ends of one set of anti-vibration modules are the same as the directions of the upper and lower ends of the other set of anti-vibration modules.

[0011] Furthermore, the anti-vibration module includes an outer cylinder, a rubber block, and a movable column; a storage chamber one is reserved in the inner wall of the outer cylinder; a storage chamber two is reserved in the lower inner wall of the outer cylinder; storage chamber one and storage chamber two are interconnected, and hydraulic transmission oil and high-pressure air are installed inside storage chamber one and storage chamber two; hydraulic transmission oil is also installed inside the outer cylinder; the rubber block is movably installed inside the outer cylinder, and the rubber block isolates the inside of the outer cylinder into an upper storage chamber. The outer periphery of the rubber block is in contact with the inner wall of the outer cylinder, and the lower storage chamber is connected to the lower storage chamber. One end of the movable column is embedded in the outer cylinder, and the movable column and the outer cylinder are movably connected. The lower end of the movable column is fixedly connected to the upper wall of the rubber block. An anti-vibration unit is installed inside the outer cylinder. The anti-vibration unit includes a spiral beryllium copper wire, a channel, a check switch, and a check switch. The spiral beryllium copper wire is installed in the center inside the outer cylinder and is located in the lower storage chamber. The upper end of copper wire one is fixedly connected to the lower wall of the rubber block, and the lower end of the spiral beryllium copper wire one is fixedly connected to the lower wall of the outer cylinder. The spiral beryllium copper wire one is in a compressed state. Channel one is installed in the lower wall of the outer cylinder. The upper end of channel one is connected to the inside of the outer cylinder, and the lower end of channel one is connected to the inside of storage chamber two. Check switch one is installed in channel one and fixedly connected to the outer cylinder. The hydraulic transmission oil in the lower storage chamber can flow to the storage chamber through channel one. In chamber two; a through-hole is pre-reserved on the rubber block, which is connected to the upper storage chamber; a check switch is installed in the through-hole and fixed to the rubber block, allowing the hydraulic transmission oil in the lower storage chamber to flow into the upper storage chamber through the through-hole; a discharge unit is installed in the outer cylinder; when the pressure of the hydraulic transmission oil in the lower storage chamber reaches a certain level, the discharge unit is used to discharge the hydraulic transmission oil in the lower storage chamber into the upper storage chamber;

[0012] The discharge unit includes a second channel and a third check switch. One end of the second channel is connected to the upper storage chamber, and the other end is connected to the lower storage chamber. The third check switch is installed on the second channel and is used to allow the hydraulic transmission oil in the lower storage chamber to flow into the upper storage chamber through the second channel. A first variable unit is installed in the outer cylinder. The first variable unit is used to change the amount of hydraulic transmission oil in the second channel per unit time.

[0013] The first variable unit includes a first variable column, a second spiral beryllium copper wire, and a first traction unit. The first variable column is horizontally installed in the inner side wall of the outer cylinder. The interior of the first variable column is divided into a first movable chamber and a second movable chamber by the variable part of the first variable column. The variable part of the first variable column is embedded in the second channel and is movably connected to the second channel laterally. When the variable part of the first variable column, facing away from the wall of the first variable column assembly, contacts the side wall of the second channel, the upper and lower parts of the second channel are blocked from each other. The second spiral beryllium copper wire is horizontally installed in the second movable chamber. One end of the second spiral beryllium copper wire is fixedly connected to the variable part of the first variable column, and the other end of the second spiral beryllium copper wire is fixedly connected to the assembly part of the first variable column. The second spiral beryllium copper wire is in a compressed state. The first traction unit is located in the outer cylinder. The first traction unit is used to pull the variable part of the first variable column to move along its central axis.

[0014] A return unit is installed inside the outer cylinder; the return unit includes a check switch four, a channel four, and a check switch five; a through-hole two is reserved on the rubber block; the check switch four is installed in the through-hole two, and the check switch four is used to allow the hydraulic transmission oil in the upper storage chamber to move to the lower storage chamber through the through-hole two; the channel four is installed on the lower wall inside the lower storage chamber and is fixedly connected to the outer cylinder; the upper end of the channel four is connected to the lower storage chamber, and the lower end of the channel four is connected to storage chamber two; the check switch five is installed on the channel four, and the check switch five is used to allow the hydraulic transmission oil in storage chamber two to move to the lower storage chamber through the channel four;

[0015] The outer cylinder houses a second movable unit; the second movable unit comprises a second movable column, a third spiral beryllium copper wire, and a second traction unit; the second movable column is horizontally mounted in a rubber block, with its assembly part fixedly connected to the rubber block, and the interior of the assembly part of the second movable column is divided into a third movable chamber and a fourth movable chamber by the movable part of the second movable column; the movable part of the second movable column is embedded in a second through-hole and is laterally movably connected to the rubber block, with a gap always present between one end of the movable part of the second movable column and the side wall of the second through-hole; the third spiral beryllium copper wire is mounted in the fourth movable chamber, with one end fixedly connected to the movable part of the second movable column, and the other end fixedly connected to the assembly part of the second movable column, and the spiral beryllium copper wire is in an extended state; the second traction unit is located inside the outer cylinder, and the second traction unit is used to pull the movable part of the second movable column to move along its central axis.

[0016] The upper wall of the rubber block has a pre-reserved compression port 2; the traction unit 2 includes an airbag 2 and a channel 5; the airbag 2 is fixedly connected in the compression port 2; the channel 5 is horizontally installed in the rubber block, one end of the channel 5 is connected to the inside of the airbag 2, and the other end of the channel 5 is connected to the inside of the movable chamber 4; hydraulic transmission oil is installed inside the airbag 2 and the channel 5.

[0017] Furthermore, a pressure port is reserved on the lower wall of the lower storage chamber; the traction unit includes an airbag and a channel; the airbag is fixed inside the pressure port; the channel is installed in the lower wall inside the outer cylinder, one end of the channel is connected to the lower end of the airbag, and the other end of the channel is connected to the end of the movable chamber near the movable part of the movable column; hydraulic transmission oil is installed inside the airbag and the channel.

[0018] Furthermore, a three-stage adjustment unit is installed in the outer cylinder; the three-stage adjustment unit includes a three-stage adjustment column, a four-stage spiral beryllium copper wire, and a three-stage traction unit; the three-stage adjustment column is horizontally installed in the lower wall inside the outer cylinder, the assembly part of the three-stage adjustment column is fixedly connected to the outer cylinder, and the inside of the assembly part of the three-stage adjustment column is divided into a five-stage movable chamber and a six-stage movable chamber by the adjustment part of the three-stage adjustment column; the adjustment part of the three-stage adjustment column is embedded in the four-stage channel and is horizontally and movably connected to the outer cylinder; the four-stage spiral beryllium copper wire is installed in the six-stage movable chamber, one end of the four-stage spiral beryllium copper wire is connected to the adjustment part of the three-stage adjustment column, and the other end of the four-stage spiral beryllium copper wire is fixedly connected to the assembly part of the three-stage adjustment column, and the four-stage spiral beryllium copper wire is in a shortened state; the three-stage traction unit is located inside the outer cylinder, and the three-stage traction unit is used to pull the adjustment part of the three-stage adjustment column to move along its central axis.

[0019] Furthermore, a pressure port three is reserved on the lower wall of the outer cylinder near the storage chamber two; the traction unit three includes an air bladder three, a channel six, and a spiral beryllium copper wire four; the air bladder three is fixedly connected in the pressure port three; the channel six is ​​horizontally installed inside the lower wall of the outer cylinder, one end of the channel six is ​​connected to the inside of the air bladder three, and the other end of the channel six is ​​connected to the inside of the active chamber five; hydraulic transmission oil is installed in both the air bladder three and the channel six.

[0020] A method for optimizing speaker sound, comprising the aforementioned speaker sound optimization system, and further comprising the following steps:

[0021] S1: When the speaker is working, the speaker body vibrates, causing the speaker support to vibrate. The anti-vibration module reduces the vibration experienced by the speaker support.

[0022] S2: When the anti-vibration module is subjected to vibration, the movable column moves inward toward the outer cylinder, and then the traction rubber block moves downward relative to the outer cylinder. The space of the lower storage chamber gradually decreases, and the pressure of the hydraulic transmission oil in the lower storage chamber increases. The anti-vibration unit reduces the speed at which the hydraulic transmission oil in the lower storage chamber flows out, thereby creating a resistance effect and reducing the vibration that occurs when the horn is working.

[0023] S3: When the pressure intensity of the anti-vibration module is relatively strong, when the pressure intensity of the hydraulic transmission oil in the lower storage chamber reaches a certain intensity, the discharge unit is adjusted by the change unit to allow some hydraulic transmission oil in the lower storage chamber to change to the upper storage chamber through the channel two. As the pressure intensity of the anti-vibration module increases, the pressure intensity of the hydraulic transmission oil in the lower storage chamber also increases, and the speed at which the hydraulic transmission oil in the lower storage chamber flows out is faster, which in turn causes the pressure intensity in the lower storage chamber to decrease more rapidly. In addition, some hydraulic transmission oil in the lower storage chamber changes to the pressure port one, and the air bladder one is compressed and reduced, which further increases the speed at which the pressure intensity in the lower storage chamber decreases.

[0024] S4: When the pressure intensity borne by the anti-vibration module decreases to a certain level, the spiral beryllium copper wire slowly returns to its original position, and the rubber block moves upward relative to the outer cylinder. At this moment, the hydraulic transmission oil in storage chamber 2 moves to the lower storage chamber through channel 4 under the pressure of air, and the hydraulic transmission oil in the upper storage chamber moves to the lower storage chamber through through port 2. At this moment, with the cooperation of the changing unit 3, the amount of change of hydraulic transmission oil in channel 4 per unit time increases, and the hydraulic transmission oil in storage chamber 2 quickly moves to the lower storage chamber. At this moment, with the cooperation of the changing unit 2, the amount of change of hydraulic transmission oil in through port 2 per unit time decreases, thereby reducing the speed at which the rubber block and the moving column move upward relative to each other. The stroke of the rubber block moving upward relative to the outer cylinder becomes longer, the pressure intensity of the hydraulic transmission oil in the upper storage chamber increases, the amount of change of hydraulic transmission oil in channel 4 per unit time decreases, thereby reducing the speed at which the rubber block and the moving column move upward relative to the outer cylinder.

[0025] S5: Through the cooperation of the anti-vibration module, the vibration generated during speaker operation is reduced, thereby reducing the impact of vibration-generated noise on speaker sound quality and achieving the purpose of optimizing speaker sound.

[0026] The beneficial effects of this invention are as follows:

[0027] 1. The present invention, through the installation of the connecting outer ring, makes the connection between the speaker bracket and the assembly outer ring a flexible connection, thereby ensuring the normal operation of the anti-vibration module.

[0028] 2. The present invention reduces the vibration generated by the speaker by installing an anti-vibration module, avoids noise caused by contact between components, and achieves the purpose of optimizing the speaker sound. At the same time, it can also prevent the possibility of loosening or falling off between components.

[0029] 3. This invention, through the installation of an anti-vibration unit and a discharge unit, reduces the outflow speed of hydraulic transmission oil in the lower storage chamber via check switches one and two when the anti-vibration module is subjected to vibration. Furthermore, the spiral beryllium copper wire one generates an upward deformation force, reducing the downward movement speed of the moving column and rubber block relative to the outer cylinder, thereby mitigating vibration. When the pressure of the hydraulic transmission oil in the lower storage chamber reaches a certain level, some of the hydraulic transmission oil in the lower storage chamber is discharged into the upper storage chamber via the discharge unit, accelerating the movement of the hydraulic transmission oil from the lower storage chamber to the upper storage chamber. This allows the spiral beryllium copper wire to further mitigate the vibration, reducing the vibration experienced by the rubber block and moving column, thereby preventing loosening or detachment of the wiring or accessories connected to the horn, ensuring the normal operation of the horn, and thus guaranteeing the horn's service life.

[0030] 4. This invention, through the installation of a return unit and a second actuation unit, controls the rate of change of the hydraulic transmission oil in the second through-port via the actuation part of the second actuation column pulled by the second traction unit to make the upward movement rate of the movable column and rubber block relative to the outer cylinder smaller as they are higher, and the upward movement rate of the movable column and rubber block relative to the outer cylinder larger as they are lower. When the rubber block is about to approach the upper end of the outer cylinder, the upward movement rate of the rubber block is reduced to prevent the rubber block and the outer cylinder from colliding, which can not only reduce vibration but also extend the service life. In addition, while ensuring the vibration reduction function, the return of the movable column is accelerated.

[0031] 5. The present invention utilizes an airbag; when the pressure intensity of the anti-vibration module is relatively strong, when the pressure intensity of the hydraulic transmission oil in the lower storage chamber reaches a certain intensity, some of the hydraulic transmission oil in the lower storage chamber moves to the pressure port, the airbag is compressed, and the spiral beryllium copper wire is raised again to reduce the speed of vibration, thereby reducing the vibration borne by the rubber block and the moving column, and ensuring the service life of the anti-vibration module.

[0032] Other features and advantages of the invention will be set forth in the following description, and will be apparent in part from the description, or may be learned by practicing the invention. The objects and other advantages of the invention may be realized and obtained by means of the structures particularly pointed out in the description and the drawings. Attached Figure Description

[0033] The accompanying drawings are provided to further illustrate the invention and form part of the specification. They are used together with the embodiments of the invention to explain the invention and do not constitute a limitation thereof. In the drawings:

[0034] Figure 1 This is a schematic diagram of the main structure of an embodiment of the present invention;

[0035] Figure 2 This is a schematic diagram of the right-side structure according to an embodiment of the present invention;

[0036] Figure 3 This is a schematic diagram of the cross-sectional structure of the connecting outer ring according to an embodiment of the present invention;

[0037] Figure 4 This is a three-dimensional structural diagram of the anti-vibration module according to an embodiment of the present invention;

[0038] Figure 5 This is a schematic diagram of the cross-sectional structure of the anti-oscillation module according to an embodiment of the present invention;

[0039] Figure 6 This is an embodiment of the present invention. Figure 5 A magnified structural diagram at point M;

[0040] Figure 7 This is an embodiment of the present invention. Figure 5 A magnified structural diagram at point N;

[0041] Figure 8 This is an embodiment of the present invention. Figure 5 A magnified structural diagram at point O;

[0042] Figure 9 This is an embodiment of the present invention. Figure 5 A magnified structural diagram at point P;

[0043] Figure 10 This is an embodiment of the present invention. Figure 5 A magnified structural diagram at point Q;

[0044] Reference numerals: 1. Horn bracket; 2. Horn body; 3. Connecting outer ring; 4. Assembly outer ring; 5. Anti-vibration module; 6. Assembly rod; 51. Outer cylinder; 511. Storage chamber one; 512. Storage chamber two; 513. Upper storage chamber; 514. Lower storage chamber; 515. Pressure port one; 516. Pressure port three; 52. Rubber block; 521. Through port one; 522. Through port two; 523. Pressure port two; 53. Movable column; 54. Anti-vibration unit; 541. Spiral beryllium copper wire one; 542. Channel one; 543. Check switch one; 544. Check switch two; 55. Discharge unit; 551. Channel two; 552. Check switch three; 56. Variable unit one; 561. Variable column one; 5611. Activity Chamber 1; 5612, Activity Chamber 2; 562, Spiral Beryllium Copper Wire 2; 563, Traction Unit 1; 5631, Airbag 1; 5632, Channel 3; 57, Return Unit; 571, Channel 4; 572, Check Switch 4; 573, Check Switch 5; 58, Variable Unit 2; 581, Variable Column 2; 5811, Activity Chamber 3; 5812, Activity Chamber 4; 582, Spiral Beryllium Copper Wire 3; 583, Traction Unit 2; 5831, Airbag 2; 5832, Channel 5; 59, Variable Unit 3; 591, Variable Column 3; 5911, Activity Chamber 5; 5912, Activity Chamber 6; 592, Spiral Beryllium Copper Wire 4; 593, Traction Unit 3; 5931, Airbag 3; 5932, Channel 6. Detailed Implementation

[0045] To make the objectives, technical solutions, and advantages of the present invention clearer, the technical solutions of the embodiments of the present invention will be clearly and completely described below with reference to the accompanying drawings. The same reference numerals in the drawings represent the same components. It should be noted that the described embodiments are only some, not all, of the embodiments of the present invention. All other embodiments obtained by those skilled in the art based on the described embodiments of the present invention without creative effort are within the scope of protection of the present invention.

[0046] See Figure 1-10 This invention proposes a speaker sound optimization system, comprising a speaker bracket 1, a speaker body 2 mounted on the speaker bracket 1, and a connecting outer ring 3 fixedly connected to the outer side of the speaker bracket 1; an assembly outer ring 4 fixedly connected to the outer circumference of the connecting outer ring 3, with pre-drilled mounting holes on the assembly outer ring 4; anti-vibration modules 5 are mounted on both the upper and lower side rods of the speaker bracket 1; an assembly rod 6 is mounted on the end of the anti-vibration module 5 away from the side rod, and the structure of the assembly rod 6 can be designed according to actual assembly needs. The anti-vibration modules 5 reduce the vibration generated by the speaker, prevent noise caused by contact between components, and achieve the purpose of optimizing the speaker sound, while also preventing the possibility of loosening or detachment of components.

[0047] See Figure 2 and Figure 3 The outer ring 3 has a wavy cross-section and is made of rubber. This makes the connection between the speaker bracket 1 and the assembly outer ring 4 a flexible connection, thereby ensuring the normal operation of the anti-vibration module 5.

[0048] See Figure 1 The upper and lower sets of anti-vibration modules 5 are positioned on the same vertical line, and the directions of the upper and lower ends of one set of anti-vibration modules 5 are the same as those of the other set. This ensures that the upper and lower sets of anti-vibration modules 5 can effectively reduce the horn oscillation.

[0049] See Figure 4 and 5 The anti-vibration module 5 includes an outer cylinder 51, a rubber block 52, and a movable column 53. The outer cylinder 51 is a hollow columnar component. A storage chamber 1 511 is reserved in the inner wall of the outer cylinder 51. A storage chamber 2 512 is reserved in the lower wall inside the outer cylinder 51. Storage chamber 1 511 and storage chamber 2 512 are connected to each other, and hydraulic transmission oil and high-pressure air are installed inside storage chamber 1 511 and storage chamber 2 512. Hydraulic transmission oil is also installed inside the outer cylinder 51. The rubber block 52 is movably installed inside the outer cylinder 51. 52 separates the inside of the outer cylinder 51 into an upper storage chamber 513 and a lower storage chamber 514. The outer peripheral surface of the rubber block 52 is in contact with the inner wall of the outer cylinder 51. One end of the movable column 53 is embedded in the outer cylinder 51. The movable column 53 and the outer cylinder 51 are movably connected. The lower end of the movable column 53 is fixedly connected to the upper wall of the rubber block 52. An anti-vibration unit 54 is installed inside the outer cylinder 51. The anti-vibration unit 54 is used to form a reverse resistance when the anti-vibration module 5 is subjected to vibration, thereby reducing the speed at which the movable column 53 moves into the outer cylinder 51.

[0050] When the anti-vibration module 5 is subjected to vibration, the movable column 53 shortens, and then the traction rubber block 52 moves downward relative to the outer cylinder 51. The anti-vibration unit 54 controls the speed at which the hydraulic transmission oil in the lower storage chamber 514 flows out, forming an upward resistance, thereby reducing the speed at which the movable column 53 moves into the outer cylinder 51.

[0051] See Figure 5-7The anti-vibration unit 54 includes a spiral beryllium copper wire 541, a channel 542, a check switch 543, and a check switch 544. The spiral beryllium copper wire 541 is installed in the center inside the outer cylinder 51 and is located in the lower storage chamber 514. The upper end of the spiral beryllium copper wire 541 is fixed to the lower wall of the rubber block 52, and the lower end of the spiral beryllium copper wire 541 is fixed to the lower wall inside the outer cylinder 51. The spiral beryllium copper wire 541 is in a compressed state. The channel 542 is installed in the lower wall inside the outer cylinder 51. The upper end of the channel 542 is fixed to the inner wall of the outer cylinder 51. When connected, the lower end of channel 1 542 is connected to the inside of storage chamber 2 512; check switch 1 543 is installed on channel 1 542 and fixedly connected to the outer cylinder 51, so that the hydraulic transmission oil in the lower storage chamber 514 can flow into storage chamber 2 512 through channel 1 542; a through port 1 521 is reserved on the rubber block 52, and the through port 1 521 is connected to the upper storage chamber 513; check switch 2 544 is installed on through port 1 521 and fixedly connected to the rubber block 52, so that the hydraulic transmission oil in the lower storage chamber 514 can flow into the upper storage chamber 513 through through port 1 521.

[0052] When the anti-vibration module 5 is subjected to vibration, the movable column 53 moves inward toward the outer cylinder 51, thereby pulling the rubber block 52 downward relative to the outer cylinder 51. The spiral beryllium copper wire 541 in the lower storage chamber 514 is compressed and shortened. Due to the reduction in space of the lower storage chamber 514, the pressure of the hydraulic transmission oil in the lower storage chamber 514 increases. Some of the hydraulic transmission oil in the lower storage chamber 514 flows into the upper storage chamber 513 through the through port 521. The rubber block 52 undergoes the same displacement. The change in space of the lower storage chamber 514 is smaller than the change in space of the upper storage chamber 513. Therefore, the excess hydraulic transmission oil in the lower storage chamber 514 flows into the storage chamber 512 through the channel 542. The speed of the hydraulic transmission oil flowing out of the lower storage chamber 514 is reduced by the check switch 543 and the check switch 544, thereby forming a resistance effect. Together with the spiral beryllium copper wire 541, it reduces the vibration that occurs when the horn is working.

[0053] See Figure 5 and Figure 6 The outer cylinder 51 is equipped with a discharge unit 55; the discharge unit 55 includes a second channel 551 and a third check switch 552; the second channel 551 is installed on the inner side wall of the outer cylinder 51, the upper end of the second channel 551 extends upward and connects to the upper end of the upper storage chamber 513, and the lower end of the second channel 551 extends downward and connects to the lower end of the lower storage chamber 514; the third check switch 552 is installed on the second channel 551 and is fixedly connected to the outer cylinder 51, and the hydraulic transmission oil in the lower storage chamber 514 can flow into the upper storage chamber 513 through the second channel 551.

[0054] When the anti-vibration module 5 is subjected to vibration, the movable column 53 moves inward toward the outer cylinder 51, and then the traction rubber block 52 moves downward relative to the outer cylinder 51. The spiral beryllium copper wire 541 is compressed and shortened, the space of the lower storage chamber 514 shrinks, the pressure of the hydraulic transmission oil in the lower storage chamber 514 increases, some of the hydraulic transmission oil in the lower storage chamber 514 moves to the upper storage chamber 513, and the remaining hydraulic transmission oil moves to the second storage chamber 512. When the vibration of the anti-vibration module 5 is relatively strong, when the pressure of the hydraulic transmission oil in the lower storage chamber 514 reaches a certain intensity, some of the hydraulic transmission oil in the lower storage chamber 514 flows into the upper storage chamber 513 through the second channel 551.

[0055] An actuation unit 56 is installed in the outer cylinder 51. The actuation unit 56 includes an actuation column 561, a spiral beryllium copper wire 562, and a traction unit 563. The actuation column 561 is horizontally installed in the inner side wall of the outer cylinder 51, located between the passage 551 and the inner wall of the outer cylinder 51. The assembly part of the actuation column 561 is fixedly connected to the inner side wall of the outer cylinder 51. The interior of the actuation column 561 is divided into two chambers, a first chamber 5611 and a second chamber 5612, by the actuation part of the actuation column 561. It is located between the second activity chamber 5612 and the second passage 551; the hydraulic transmission oil is installed inside the first activity chamber 5611; the moving part of the first moving column 561 is embedded in the second passage 551 and is laterally and movably connected to the second passage 551. The moving part of the first moving column 561 can contact and connect with the side wall of the second passage 551 away from the wall of the first moving column 561 assembly part, and when the moving part of the first moving column 561 contacts the side wall of the second passage 551 away from the wall of the first moving column 561 assembly part, the upper and lower parts of the second passage 551 block each other.

[0056] A spiral beryllium copper wire 2 562 is horizontally installed in the movable chamber 2 5612. One end of the spiral beryllium copper wire 2 562 is fixedly connected to the moving part of the moving column 1 561, and the other end of the spiral beryllium copper wire 2 562 is fixedly connected to the assembly part of the moving column 1 561. The spiral beryllium copper wire 2 562 is in a compressed state. A pressure port 1 515 is reserved on the lower wall of the lower storage chamber 514.

[0057] Traction unit 563 is located in outer cylinder 51; traction unit 563 includes airbag 5631 and channel 5632; airbag 5631 is fixed inside the pressure port 515; channel 5632 is installed in the lower wall inside outer cylinder 51, one end of channel 5632 is connected to the lower end of airbag 5631, and the other end of channel 5632 is connected to the end of movable chamber 5611 near the movable part of movable column 561; hydraulic transmission oil is installed inside airbag 5631 and channel 5632.

[0058] Because the outer cylinder 51 is vertically oriented, the pressure of the hydraulic transmission oil at the lower end of the lower storage chamber 514 is greater than that at the upper end. When the anti-vibration module 5 experiences significant pressure, the rubber block 52 and the movable column 53 move downwards relative to the outer cylinder 51. The pressure of the hydraulic transmission oil at the lower end of the lower storage chamber 514 reaches a certain level, causing the hydraulic transmission oil in the lower storage chamber 514 to compress the air bladder 5631. The air bladder 5631 then contracts, allowing the hydraulic transmission oil inside to move through the channel 3 5632 into the movable chamber 5611. The moving part of the traction moving column 561 moves away from the channel 2 551. The upper and lower parts of the channel 2 551 are connected. Some hydraulic transmission oil in the lower storage chamber 514 moves to the upper storage chamber 513 through the channel 2 551. The further the stroke of the moving column 53 and the rubber block 52, the stronger the pressure of the hydraulic transmission oil in the lower storage chamber 514. The further the lateral movement of the moving part of the moving column 561, the greater the amount of hydraulic transmission oil in the channel 2 551 changes per unit time. Some hydraulic transmission oil in the lower storage chamber 514 moves to the pressure port 515, and the airbag 5631 is compressed and compressed.

[0059] See Figure 9 and 10 Inside the outer cylinder 51, a return unit 57 is installed; the return unit 57 includes a check switch 4 572, a channel 4 571, and a check switch 573; the rubber block 52 has a through-hole 2 522, the upper end of which is connected to the upper storage chamber 513, and the lower end of which is connected to the lower storage chamber 514; the check switch 4 572 is installed in the through-hole 2 522, and the hydraulic transmission oil in the upper storage chamber 513 can pass through the through-hole 2 522. 522 is moved to the lower storage chamber 514; Channel 4 571 is installed on the lower wall inside the lower storage chamber 514 and is fixedly connected to the outer cylinder 51. The upper end of Channel 4 571 is connected to the lower storage chamber 514, and the lower end of Channel 4 571 is connected to the second storage chamber 512; Check switch 573 is installed on Channel 4 571 and is fixedly connected to the outer cylinder 51. The hydraulic transmission oil in storage chamber 1 511 and storage chamber 2 512 can be moved to the lower storage chamber 514 through Channel 4 571.

[0060] When the pressure on the anti-vibration module 5 is reduced to a certain level, the rubber block 52 moves upward with the assistance of the spiral beryllium copper wire 541. At this moment, the hydraulic transmission oil in the upper storage chamber 513 moves to the lower storage chamber 514 through the through port 522. The hydraulic transmission oil in storage chamber 511 and storage chamber 512 moves to the lower storage chamber 514 through the channel 571 under the pressure of air.

[0061] An alteration unit 2 58 is installed in the outer cylinder 51; the alteration unit 2 58 includes an alteration column 2 581, a spiral beryllium copper wire 3 582, and a traction unit 2 583; the alteration column 2 581 is horizontally installed in the rubber block 52 and is located between the through opening 1 521 and the through opening 2 522. The assembly part of the alteration column 2 581 is fixedly connected to the rubber block 52. The inside of the assembly part of the alteration column 2 581 is divided into a movable chamber 3 5811 and a movable chamber 4 5812 by the alteration part of the alteration column 2 581. 811 is located between the fourth activity chamber 5812 and the second through-hole 522; the fourth activity chamber 5812 contains hydraulic transmission oil; the variable part of the variable column 2 581 is embedded in the second through-hole 522 and is laterally and movably connected to the rubber block 52. The shorter the distance between the variable part of the variable column 2 581 and the second through-hole 522, the less the amount of change of the hydraulic transmission oil in the second through-hole 522 per unit time, and there is always a gap between one end of the variable part of the variable column 2 581 and the side wall of the second through-hole 522.

[0062] A spiral beryllium copper wire 3 582 is installed in the movable chamber 4 5812. One end of the spiral beryllium copper wire 3 582 is fixedly connected to the movable part of the movable column 2 581, and the other end of the spiral beryllium copper wire 3 582 is fixedly connected to the assembly part of the movable column 2 581. The spiral beryllium copper wire 3 582 is in an extended form. A pressure port 2 523 is reserved on the upper wall of the rubber block 52. The pressure port 2 523 is located between the through port 1 521 and the movable column 2 581. The traction unit 2 583 is located inside the outer cylinder 51.

[0063] The traction unit 2 583 includes airbag 2 5831 and channel 5 5832; airbag 2 5831 is fixed in the compression port 2 523; channel 5 5832 is installed laterally in the rubber block 52, one end of channel 5 5832 is connected to the inside of airbag 2 5831, and the other end of channel 5 5832 is connected to the inside of the movable chamber 4 5812; hydraulic transmission oil is installed inside airbag 2 5831 and channel 5 5832.

[0064] When the pressure on the anti-vibration module 5 decreases to a certain level, with the assistance of the spiral beryllium copper wire 541, the rubber block 52 slowly moves upward relative to the outer cylinder 51. The pressure of the hydraulic transmission oil in the upper storage chamber 513 gradually increases. At this moment, the hydraulic transmission oil in the upper storage chamber 513 compresses the second airbag 5831, causing the second airbag 5831 to be compressed. The hydraulic transmission oil inside the second airbag 5831 moves through the fifth channel 5832 into the fourth movable chamber 5812, and then compresses the moving part of the second movable column 581 to almost penetrate laterally. The side of the passage 522 that is farther from the moving column 581 moves, thereby reducing the amount of change of the hydraulic transmission oil in the passage 522 per unit time, and reducing the rate at which the rubber block 52 and the moving column 53 move upward relative to the outer cylinder 51; the longer the upward movement of the rubber block 52 relative to the outer cylinder 51, the stronger the pressure of the hydraulic transmission oil in the upper storage chamber 513, and the less the amount of change of the hydraulic transmission oil in the passage 571 per unit time, thereby reducing the rate at which the rubber block 52 and the moving column 53 move upward relative to the outer cylinder 51.

[0065] See Figure 5 and Figure 10 The outer cylinder 51 houses a variable unit 3 59; the variable unit 3 59 includes a variable column 3 591, a spiral beryllium copper wire 4 592, and a traction unit 3 593; the variable column 3 591 is horizontally installed in the lower wall inside the outer cylinder 51, and is located between channel 4 571 and channel 1 542. The assembly part of the variable column 3 591 is fixedly connected to the outer cylinder 51. The inside of the assembly part of the variable column 3 591 is divided into movable chamber 5 5911 and movable chamber 6 5912 by the variable part of the variable column 3 591. Movable chamber 5 5911 is located between movable chamber 6 5912 and channel 4 571; hydraulic transmission oil is installed in movable chamber 5 5911; the variable part of the variable column 3 591 is embedded in channel 4 571 and is movably connected to the outer cylinder 51 laterally. The shorter the distance between the variable part of the variable column 3 591 and channel 4 571, the less the amount of change of the hydraulic transmission oil in channel 4 571 per unit time.

[0066] A spiral beryllium copper wire 4 592 is installed in the movable chamber 6 5912. One end of the spiral beryllium copper wire 4 592 is connected to the moving part of the moving column 3 591, and the other end of the spiral beryllium copper wire 4 592 is fixedly connected to the assembly part of the moving column 3 591. The spiral beryllium copper wire 4 592 is in a shortened form. A pressure port 3 516 is reserved on the lower wall of the outer cylinder 51 near the storage chamber 2 512. The traction unit 3 593 is located inside the outer cylinder 51.

[0067] The traction unit 3 593 includes an airbag 3 5931, a channel 6 5932, and a spiral beryllium copper wire 4 592; the airbag 3 5931 is fixed in the pressure port 3 516; the channel 6 5932 is horizontally installed inside the lower wall of the outer cylinder 51, one end of the channel 6 5932 is connected to the inside of the airbag 3 5931, and the other end of the channel 6 5932 is connected to the inside of the movable chamber 5 5911; hydraulic transmission oil is installed in both the airbag 3 5931 and the channel 6 5932.

[0068] When the anti-vibration module 5 is subjected to vibration, the movable column 53 moves downward relative to the outer cylinder 51, and then the traction rubber block 52 moves downward relative to the outer cylinder 51. The hydraulic transmission oil in the lower storage chamber 514 moves to the second storage chamber 512. The pressure of the hydraulic transmission oil in the first storage chamber 511 and the second storage chamber 512 increases. The hydraulic transmission oil in the second storage chamber 512 compresses the third airbag 5931. The hydraulic transmission oil in the third airbag 5931 moves to the fifth movable chamber 5911 through the sixth channel 5932, and then... The pressure on the variable column 591 shifts towards the side away from the channel 571, thereby increasing the amount of hydraulic transmission oil in the channel 571 per unit time. When the pressure on the anti-vibration module 5 is reduced to a certain level, with the cooperation of the spiral beryllium copper wire 541, the movable column 53 and the rubber block 52 move upward relative to the outer cylinder 51. Under the pressure of the air, the hydraulic transmission oil in the storage chamber 1 511 and the storage chamber 2 512 quickly shifts through the channel 571 to the lower storage chamber 514.

[0069] A method for optimizing speaker sound, comprising the aforementioned speaker sound optimization system, and further comprising the following steps:

[0070] S1: When the horn is working, the horn body 2 vibrates, causing the horn support 1 to vibrate. The anti-vibration module 5 reduces the vibration experienced by the horn support 1.

[0071] S2: When the anti-vibration module 5 is subjected to vibration, the movable column 53 moves inward toward the outer cylinder 51, and then the traction rubber block 52 moves downward relative to the outer cylinder 51. The space of the lower storage chamber 514 gradually decreases, and the pressure of the hydraulic transmission oil in the lower storage chamber 514 increases. The anti-vibration unit 54 reduces the speed at which the hydraulic transmission oil in the lower storage chamber 514 flows out, thereby creating a resistance effect and reducing the vibration that occurs when the horn is working.

[0072] S3: When the pressure intensity of the anti-vibration module 5 is relatively strong, when the pressure intensity of the hydraulic transmission oil in the lower storage chamber 514 reaches a certain intensity, the discharge unit 55 is adjusted by the change unit 1 56 to allow some of the hydraulic transmission oil in the lower storage chamber 514 to move to the upper storage chamber 513 through the channel 2 551. As the pressure intensity of the anti-vibration module 5 increases, the pressure intensity of the hydraulic transmission oil in the lower storage chamber 514 also increases, and the speed at which the hydraulic transmission oil in the lower storage chamber 514 flows out is faster, which in turn causes the pressure intensity in the lower storage chamber 514 to decrease more rapidly. In addition, some of the hydraulic transmission oil in the lower storage chamber 514 moves to the pressure port 1 515, and the airbag 1 5631 is compressed and reduced, which further increases the speed at which the pressure intensity in the lower storage chamber 514 decreases.

[0073] S4: When the pressure on the anti-vibration module 5 decreases to a certain level, the spiral beryllium copper wire 541 slowly returns to its original position, and the rubber block 52 moves upward relative to the outer cylinder 51. At this moment, the hydraulic transmission oil in storage chamber 2 512 moves to the lower storage chamber 514 under the pressure of air through channel 4 571, and the hydraulic transmission oil in the upper storage chamber 513 moves to the lower storage chamber 514 through through port 2 522. At this moment, with the cooperation of the changing unit 3 59, the amount of hydraulic transmission oil changing per unit time in channel 4 571 increases, and storage chamber 2 512... The hydraulic transmission oil in the middle quickly changes to the lower storage chamber 514; at this moment, with the cooperation of the second change unit 58, the change in the hydraulic transmission oil in the second through port 522 per unit time decreases, which in turn makes the upward movement of the rubber block 52 and the moving column 53 relatively smaller; the upward movement of the rubber block 52 relative to the outer cylinder 51 becomes longer, the pressure intensity of the hydraulic transmission oil in the upper storage chamber 513 becomes stronger, the change in the hydraulic transmission oil in the fourth channel 571 per unit time decreases, which in turn makes the upward movement rate of the rubber block 52 and the moving column 53 relative to the outer cylinder 51 decrease;

[0074] S5: Through the cooperation of the anti-vibration module 5, the vibration generated during speaker operation is reduced, thereby reducing the impact of the noise generated by the vibration on the speaker sound quality, and achieving the purpose of optimizing the speaker sound.

[0075] The foregoing has shown and described the basic principles, main features, and advantages of the present invention. Those skilled in the art should understand that the present invention is not limited to the above embodiments. The embodiments and descriptions in the specification are merely illustrative of the principles of the invention. Various changes and modifications can be made to the invention without departing from its spirit and scope, and all such changes and modifications fall within the scope of the present invention as claimed. The scope of protection of this invention is defined by the appended claims and their equivalents.

Claims

1. A loudspeaker sound optimization system, comprising a loudspeaker bracket (1), wherein a loudspeaker body (2) is mounted on the loudspeaker bracket (1), characterized in that, The outer side of the speaker bracket (1) is fixedly connected to the connecting outer ring (3); An assembly outer ring (4) is fixedly connected to the outer circumferential surface of the connecting outer ring (3), and an installation hole is reserved on the assembly outer ring (4); Anti-vibration modules (5) are installed on the upper and lower side rods of the speaker bracket (1). The anti-vibration module (5) has an assembly rod (6) installed at the end away from the side rod. The anti-vibration module (5) includes an outer cylinder (51), a rubber block (52), and a movable column (53); a storage chamber 1 (511) is reserved in the inner wall of the outer cylinder (51); a storage chamber 2 (512) is reserved in the lower wall inside the outer cylinder (51); the storage chamber 1 (511) and the storage chamber 2 (512) are connected to each other, and hydraulic transmission oil and high-pressure air are installed inside the storage chamber 1 (511) and the storage chamber 2 (512); hydraulic transmission oil is also installed inside the outer cylinder (51); the rubber block (52) is movably installed inside the outer cylinder (51), and the rubber block (52) separates the inside of the outer cylinder (51) into an upper storage chamber (513) and a lower storage chamber. The outer periphery of the rubber block (52) is in contact with the inner wall of the outer cylinder (51) in the chamber (514); one end of the movable column (53) is embedded in the outer cylinder (51), the movable column (53) and the outer cylinder (51) are movably connected, and the lower end of the movable column (53) is fixedly connected to the upper wall of the rubber block (52); an anti-vibration unit (54) is installed inside the outer cylinder (51); the anti-vibration unit (54) includes a spiral beryllium copper wire I (541), a channel I (542), a check switch I (543), and a check switch II (544); the spiral beryllium copper wire I (541) is installed in the center inside the outer cylinder (51) and is located in the lower storage chamber (514), the spiral... The upper end of beryllium copper wire one (541) is fixedly connected to the lower wall of rubber block (52), and the lower end of the spiral beryllium copper wire one (541) is fixedly connected to the lower wall inside the outer cylinder (51). The spiral beryllium copper wire one (541) is in a compressed state. The first channel (542) is installed in the lower wall inside the outer cylinder (51). The upper end of the first channel (542) is connected to the inside of the outer cylinder (51), and the lower end of the first channel (542) is connected to the inside of the second storage chamber (512). The first check switch (543) is installed in the first channel (542) and fixedly connected to the outer cylinder (51). The hydraulic transmission oil in the lower storage chamber (514) can flow to the second storage chamber through the first channel (542). (512) In the rubber block (52), a through-hole (521) is reserved on the rubber block (52), which is connected to the upper storage chamber (513); the check switch (544) is installed in the through-hole (521) and fixedly connected to the rubber block (52), and the hydraulic transmission oil in the lower storage chamber (514) can flow to the upper storage chamber (513) through the through-hole (521); a discharge unit (55) is installed in the outer cylinder (51); when the pressure of the hydraulic transmission oil in the lower storage chamber (514) reaches a certain intensity, the discharge unit (55) is used to discharge the hydraulic transmission oil in the lower storage chamber (514) to the upper storage chamber (513); The discharge unit (55) includes a second channel (551) and a third check switch (552); one end of the second channel (551) is connected to the upper storage chamber (513), and the other end is connected to the lower storage chamber (514); the third check switch (552) is installed on the second channel (551), and the third check switch (552) is used to allow the hydraulic transmission oil in the lower storage chamber (514) to flow into the upper storage chamber (513) through the second channel (551); the outer cylinder (51) is equipped with a first variable unit (56); the first variable unit (56) is used to change the amount of change of the hydraulic transmission oil in the second channel (551) per unit time; The first variable unit (56) includes a first variable column (561), a second spiral beryllium copper wire (562), and a first traction unit (563). The first variable column (561) is horizontally installed in the inner side wall of the outer cylinder (51). The inside of the first variable column (561) is divided into a first movable chamber (5611) and a second movable chamber (5612) by the variable part of the first variable column (561). The variable part of the first variable column (561) is embedded in the second channel (551) and is movably connected to the second channel (551) horizontally. The wall surface of the variable part of the first variable column (561) facing away from the mounting part of the first variable column (561) and the second channel (5612) are connected to the second channel (5612). 51) When the side walls come into contact, the upper and lower parts of the second channel (551) block each other; the spiral beryllium copper wire 2 (562) is horizontally installed in the second movable chamber (5612), one end of the spiral beryllium copper wire 2 (562) is fixedly connected to the moving part of the first movable column (561), and the other end of the spiral beryllium copper wire 2 (562) is fixedly connected to the assembly part of the first movable column (561), and the spiral beryllium copper wire 2 (562) is in a compressed state; the traction unit 1 (563) is located in the outer cylinder (51), and the traction unit 1 (563) is used to pull the moving part of the first movable column (561) to move along its central axis; Inside the outer cylinder (51) is a return unit (57); the return unit (57) includes a check switch four (572), a channel four (571), and a check switch five (573); the rubber block (52) has a through-hole two (522) that runs vertically through it; the check switch four (572) is installed in the through-hole two (522), and the check switch four (572) is used to allow the hydraulic transmission oil in the upper storage chamber (513) to move to the lower storage chamber (514) through the through-hole two (522). The fourth channel (571) is installed on the lower wall of the lower storage chamber (514) and is fixedly connected to the outer cylinder (51). The upper end of the fourth channel (571) is connected to the lower storage chamber (514), and the lower end of the fourth channel (571) is connected to the second storage chamber (512). The fifth check switch (573) is installed on the fourth channel (571). The fifth check switch (573) is used to allow the hydraulic transmission oil in the second storage chamber (512) to move to the lower storage chamber (514) through the fourth channel (571). The outer cylinder (51) houses a second variable unit (58); the second variable unit (58) includes a second variable column (581), a spiral beryllium copper wire (582), and a second traction unit (583); the second variable column (581) is horizontally installed in the rubber block (52), the assembly part of the second variable column (581) is fixedly connected to the rubber block (52), and the interior of the assembly part of the second variable column (581) is isolated into a third movable chamber (5811) and a fourth movable chamber (5812) by the variable part of the second variable column (581); the variable part of the second variable column (581) is embedded in the second through opening (522) and is laterally and movably connected to the rubber block (52), so A gap is always provided between one end of the changing part of the second changing column (581) and the side wall of the second through-hole (522); the third spiral beryllium copper wire (582) is installed in the fourth moving chamber (5812), one end of the third spiral beryllium copper wire (582) is fixedly connected to the changing part of the second changing column (581), and the other end of the third spiral beryllium copper wire (582) is fixedly connected to the assembly part of the second changing column (581), and the third spiral beryllium copper wire (582) is in an extended form; the second traction unit (583) is located inside the outer cylinder (51), and the second traction unit (583) is used to pull the changing part of the second changing column (581) to move along its central axis; The upper wall of the rubber block (52) has a pressure port two (523) reserved; the traction unit two (583) includes an airbag two (5831) and a channel five (5832); the airbag two (5831) is fixed in the pressure port two (523); the channel five (5832) is installed horizontally in the rubber block (52), one end of the channel five (5832) is connected to the inside of the airbag two (5831), and the other end of the channel five (5832) is connected to the inside of the active chamber four (5812); the airbag two (5831) and the channel five (5832) are both filled with hydraulic transmission oil.

2. The speaker sound optimization system according to claim 1, characterized in that: The cross-section of the connecting outer ring (3) is wavy, and the connecting outer ring (3) is made of rubber.

3. The speaker sound optimization system according to claim 2, characterized in that: The upper and lower sets of anti-vibration modules (5) are on the same vertical line, and the upper and lower ends of one set of anti-vibration modules (5) are in the same direction as the upper and lower ends of the other set of anti-vibration modules (5).

4. The speaker sound optimization system according to claim 3, characterized in that: The lower storage chamber (514) has a pre-reserved pressure port (515) on its lower wall surface; the traction unit (563) includes an airbag (5631) and a channel (5632); the airbag (5631) is fixed inside the pressure port (515); the channel (5632) is installed in the lower wall inside the outer cylinder (51), one end of the channel (5632) is connected to the lower end of the airbag (5631), and the other end of the channel (5632) is connected to the end of the movable chamber (5611) near the movable column (561); hydraulic transmission oil is installed inside the airbag (5631) and the channel (5632).

5. The speaker sound optimization system according to claim 4, characterized in that: The outer cylinder (51) houses a three-stage variable unit (59); the three-stage variable unit (59) includes a three-stage variable column (591), a spiral beryllium copper wire (592), and a three-stage traction unit (593); the three-stage variable column (591) is horizontally installed in the lower wall inside the outer cylinder (51), the assembly part of the three-stage variable column (591) is fixedly connected to the outer cylinder (51), and the interior of the assembly part of the three-stage variable column (591) is divided into a five-stage movable chamber (5911) and a six-stage movable chamber (5912) by the variable part of the three-stage variable column (591); the variable part of the three-stage variable column (591) is embedded in the four-stage channel (571). The spiral beryllium copper wire four (592) is installed in the movable chamber six (5912). One end of the spiral beryllium copper wire four (592) is connected to the moving part of the moving column three (591), and the other end of the spiral beryllium copper wire four (592) is fixedly connected to the assembly part of the moving column three (591). The spiral beryllium copper wire four (592) is in a shortened form. The traction unit three (593) is located inside the outer cylinder (51). The traction unit three (593) is used to pull the moving part of the moving column three (591) to move along its central axis.

6. The speaker sound optimization system according to claim 5, characterized in that: A pressure port three (516) is reserved on the lower wall of the outer cylinder (51) near the storage chamber two (512); the traction unit three (593) includes an airbag three (5931) and a channel six (5932); the airbag three (5931) is fixed in the pressure port three (516); the channel six (5932) is horizontally installed inside the lower wall of the outer cylinder (51), one end of the channel six (5932) is connected to the inside of the airbag three (5931), and the other end of the channel six (5932) is connected to the inside of the active chamber five (5911); hydraulic transmission oil is installed in both the airbag three (5931) and the channel six (5932).

7. A method for optimizing loudspeaker sound, applied to the loudspeaker sound optimization system described in claim 6, characterized in that: It also includes the following steps: S1: When the horn is working, the horn body (2) oscillates, causing the horn support (1) to oscillate. The anti-oscillation module (5) reduces the oscillation borne by the horn support (1). S2: When the anti-vibration module (5) is subjected to vibration, the movable column (53) moves towards the inside of the outer cylinder (51), and then the traction rubber block (52) moves downward relative to the outer cylinder (51), the space of the lower storage chamber (514) gradually decreases, the pressure intensity of the hydraulic transmission oil in the lower storage chamber (514) increases, and the speed of the hydraulic transmission oil flowing out of the lower storage chamber (514) is reduced by the anti-vibration unit (54), thereby forming a resistance effect, and thus reducing the vibration that occurs when the horn is working; S3: When the pressure intensity of the anti-vibration module (5) is relatively strong, when the pressure intensity of the hydraulic transmission oil in the lower storage chamber (514) reaches a certain intensity, the discharge unit (55) is adjusted by the first variable unit (56) to allow some of the hydraulic transmission oil in the lower storage chamber (514) to move to the upper storage chamber (513) through the second channel (551). As the pressure intensity of the anti-vibration module (5) increases, the pressure intensity of the hydraulic transmission oil in the lower storage chamber (514) increases, and the speed at which the hydraulic transmission oil in the lower storage chamber (514) flows out is faster, which in turn makes the pressure intensity in the lower storage chamber (514) decrease more rapidly; and some of the hydraulic transmission oil in the lower storage chamber (514) moves to the first pressure port (515), and the first airbag (5631) is compressed and reduced, which further increases the speed at which the pressure intensity in the lower storage chamber (514) decreases. S4: When the pressure intensity borne by the anti-vibration module (5) is reduced to a certain intensity, the spiral beryllium copper wire (541) slowly returns to its original position, and the rubber block (52) moves upward relative to the outer cylinder (51). At this moment, the hydraulic transmission oil in storage chamber two (512) moves to the lower storage chamber (514) under the pressure of air through channel four (571), and the hydraulic transmission oil in the upper storage chamber (513) moves to the lower storage chamber (514) through through port two (522). At this moment, with the cooperation of the changing unit three (59), the amount of change of the hydraulic transmission oil in channel four (571) per unit time increases, and the storage chamber two (512) The hydraulic transmission oil in the first storage chamber (514) quickly changes to the lower storage chamber (514); at this moment, with the cooperation of the second variable unit (58), the amount of change of the hydraulic transmission oil in the second through port (522) per unit time decreases, which in turn makes the speed of the rubber block (52) and the moving column (53) relative to the upward movement decrease; the stroke of the rubber block (52) relative to the outer cylinder (51) increases, the pressure intensity of the hydraulic transmission oil in the upper storage chamber (513) increases, the amount of change of the hydraulic transmission oil in the fourth channel (571) per unit time decreases, which in turn makes the speed of the rubber block (52) and the moving column (53) relative to the outer cylinder (51) decrease; S5: Through the cooperation of the anti-vibration module (5), the vibration generated during the operation of the speaker is reduced, thereby reducing the impact of the noise generated by the vibration on the speaker sound quality, and achieving the purpose of optimizing the speaker sound.