KR102828651B1 - Soundproof wall facilities including earthquake-resistant functions - Google Patents

Abstract

The present invention provides a soundproof wall facility including an earthquake-resistant function. The soundproof wall facility including an earthquake-resistant function includes a foundation portion whose lower part is buried in the ground along the boundary between an apartment complex and a road, a plurality of support portions installed on the foundation portion so as to be upright at intervals along the longitudinal direction of the foundation portion, a plurality of horizontal frame portions joined to the plurality of support portions in a horizontal direction at upper and lower intervals, and soundproof plates installed in each of installation holes formed in a grid arrangement between the plurality of support portions and the horizontal frame portions, wherein fixing holes are formed at intervals on the foundation portion, lower parts of the plurality of support portions are arranged inside each of the fixing holes, and the fixing holes are filled with an elastic cushioning material, wherein the cushioning material is filled between each of the plurality of support portions and the inner periphery of each of the fixing holes, and a plurality of locations around the lower periphery of the plurality of support portions and a plurality of locations around the inner periphery of each of the fixing holes are elastically connected by metal elastic members formed of metal.

Description

{Soundproof wall facilities including earthquake-resistant functions}

The present invention relates to a soundproof wall facility including an earthquake-resistant function, and more specifically, to a soundproof wall facility including an earthquake-resistant function that enables the soundproof wall to maintain stability and minimize the risk of collapse even when an earthquake occurs.

Soundproof walls installed in apartment complexes are installed to minimize noise pollution in residential areas by blocking or reducing noise from external roads, railways, industrial facilities, etc., and to protect the privacy of apartment complex residents and provide a comfortable living environment.

Conventional soundproof wall structures are basically composed of a foundation structure installed on the ground, supports that support soundproof panels, soundproof panels (soundproof or sound-absorbing panels) that directly block or absorb noise, and an upper finishing material (cap or cover) that prevents rainwater from entering and finishes the exterior.

In addition, if necessary, transparent panels (acrylic, polycarbonate, etc.) are installed on some of the soundproof walls to secure a sense of visual openness and a view from the surrounding environment. In addition to functional characteristics, soundproof walls are designed to include aesthetic elements, eco-friendly materials, and landscape elements such as green spaces, taking into account harmony with the surrounding landscape.

Meanwhile, when an earthquake occurs, the typical problems that occur in conventional soundproof wall structures are as follows.

First, the seismic performance of the support structure and the supporting members of the soundproof wall is insufficient, so when an earthquake occurs, the structure may be damaged by vibration and impact, or the connection between the supporting members and the soundproof panel may become detached, causing the panel to fall off or tip over.

Second, if the foundation structure of a soundproof wall facility does not sufficiently consider the shear force and bending moment that occur during an earthquake, damage such as cracks in the foundation, ground subsidence, or overturning may occur, making the entire facility unstable.

Third, in the case of conventional soundproof walls, the soundproof panels lack sufficient free space or deformation absorption devices to absorb or alleviate the shock and repetitive vibration caused by an earthquake, which may cause damage or detachment of the soundproof panels, which are vulnerable to shock, and cause secondary damage.

Fourth, when the connections or joints of a sound barrier are designed without considering seismic loads, there is a possibility that the continuity of the sound barrier facility may be lost due to disconnection between structural members or damage to bolts and welds, resulting in partial or complete collapse.

Lastly, if existing sound barrier structures are designed with a focus on rigidity and lack flexibility, they may not effectively buffer or disperse vibrations generated by seismic waves, which may result in concentrated damage to the entire structure.

Republic of Korea Patent No. 10-1912711 (Registration date: October 23, 2018)

The present invention has been devised to solve the above-described problems, and the purposes of the present invention are as follows.

The purpose of the present invention is to provide a soundproof wall facility including an earthquake-resistant function. Existing soundproof walls have been focused on the role of performing a noise reduction function, and thus are structurally vulnerable in the event of a natural disaster such as an earthquake. Accordingly, the present invention is designed so that a soundproof wall can maintain stability and minimize the risk of collapse even in the event of an earthquake.

To this end, elastic members and buffering materials were applied between the support and foundation to effectively absorb external impacts and minimize structural deformation. In addition, soundproofing and earthquake-resistant functions were implemented simultaneously to maintain the original purpose of the soundproof wall while ensuring that it can function stably even in the event of an earthquake.

In addition, it is designed to increase structural flexibility and durability by applying a multi-stage support structure and metal elastic members, and to secure long-term stability. In addition, a slope measuring device that can detect the slope of the soundproof wall in real time and a control unit that can automatically adjust based on this are applied to enable more effective earthquake response. Through this, the safe installation of soundproof walls is possible even in areas where earthquakes occur frequently, and the important purpose of the present invention is to minimize structural damage and reduce maintenance costs.

The purpose of the present invention is not limited to the purpose mentioned above, and other purposes and advantages of the present invention which are not mentioned can be understood by the following description, and will be more clearly understood by the embodiments of the present invention. In addition, it will be easily understood that the purposes and advantages of the present invention can be realized by the means and combinations thereof indicated in the claims.

To achieve the above objectives, the present invention provides a soundproof wall facility including an earthquake-resistant function.

The above-mentioned soundproof wall facility including the earthquake-resistant function comprises a foundation part whose lower part is buried in the ground along the boundary between the apartment complex and the road, a plurality of support parts installed on the foundation part to be upright at intervals along the longitudinal direction of the foundation part, a plurality of horizontal frame parts joined horizontally to the plurality of support parts at upper and lower intervals, and soundproof boards installed in each of the installation holes formed in a grid arrangement between the plurality of support parts and the horizontal frame parts.

In the above base, fixing holes are formed at intervals,

The lower part of the above multiple holding units is,

are placed inside each of the above fixed holes,

The above fixing holes are filled with an elastic cushioning material, and the cushioning material is filled between each of the plurality of supporting members and the inner circumference of each of the fixing holes.

A plurality of locations around the lower circumference of the plurality of supporting members and a plurality of locations inside each of the fixing holes are elastically connected by metal elastic members formed of metal.

Here, each of the above multiple holding units,

The upper pillar and,

A central body on a plate connected to the lower part of the upper support,

Including a lower support extending downward from the lower end of the central body and inserted into each of the fixing holes,

The above upper supporter is,

The first pillar of polygonal shape,

A second support member is connected to the outer periphery of the first support member and has a circumference,

Including a third pillar connected to the outer periphery of the second pillar,

The above central body,

It is recommended that it be inserted into the step portion connected to the fixing hole at the top of the above-mentioned base portion.

And, in the inner circumference of the above fixed holes,

Cylinders having axes protruding into the inside of the above-mentioned fixed holes are installed,

At the end of the shaft of each of the above cylinders, a rotary ball is installed to roll,

The above rotary ball is in contact with the circumference of the lower support so as to roll,

The above cylinders are driven by the control of the control unit,

A slope measuring device is installed on the upper support to measure the slope of the upper support and transmit the measured slope to the control unit.

In the above control unit, a reference slope is preset,

It is preferable that the above control unit controls in real time the axes of the cylinders to protrude or insert so that the measured inclination reaches the reference inclination.

In addition, the lower support is formed in a circular shape,

In the above mentioned land,

A buried foundation is formed in which a lift groove of a certain depth is formed,

In the above-mentioned elevator home, elevator cylinders having an elevator shaft that is driven to be elevated by the control of the above-mentioned control unit are installed,

The above-mentioned base is located in the above-mentioned elevator home,

It is preferable that the lower part of the above-mentioned base be supported by being connected to the upper part of the above-mentioned lifting shaft of the above-mentioned lifting cylinders.

In particular, the control unit controls the axles of the cylinders to protrude or insert in real time so that the measured inclination reaches the reference inclination, but if a preset limit time is exceeded, the lifting axles of the lifting cylinders are lowered so that the base is accommodated inside the lifting groove.

In addition, on the outer periphery of the base, rails are formed along the up-down direction, and on the inner periphery of the elevator home, rail grooves are formed to guide movement by being combined with the rails.

In addition, a square-shaped elastic tube is installed along the inner periphery of each of the above installation holes, and a joining frame to which each of the above soundproofing plates is joined is installed on the inner periphery of the elastic tube.

In addition, the soundproof board includes a square-shaped outer frame elastically connected to the joining frame, unit soundproof boards arranged with front-back spacing on the inner side of the outer frame, and an elastic connecting member connecting the outer perimeters of the unit soundproof boards, and the outer perimeter of the elastic connecting member is connected to the inner perimeter of the outer frame.

Additionally, each of the unit soundproofing plates has a grid-shaped lattice hole formed inside, filled with a gel-like soundproofing material.

Each of the above grid holes is formed at a position where their positions intersect each other in each of the unit soundproofing plates.

In addition, among the above unit soundproofing plates, two adjacent unit soundproofing plates are connected through joint members. The joint members are made of an elastic material.

At each end of the above connecting members, a catch is formed.

The above connecting members penetrate the two unit soundproofing plates, and each of the hanging ends is in close contact with the outer surfaces of the two unit soundproofing plates.

By solving the above problems, the present invention provides a soundproof wall facility including an earthquake-resistant function, thereby preventing the collapse of the soundproof wall and maintaining structural safety when an earthquake occurs. Unlike conventional general soundproof walls, in the present invention, when an earthquake or external impact is applied, elastic members and buffers can absorb impact, thereby minimizing deformation and damage. In addition, by applying a cylinder and a rotating ball structure, the soundproof wall can flexibly respond to external impact, thereby having the effect of securing long-term durability.

In particular, it includes a function that can continuously detect and adjust the slope of the sound barrier in real time through a slope measuring device and a control unit, so that the structural balance can be automatically maintained even if an earthquake occurs. This prevents the risk of the sound barrier tilting or falling, and enables an immediate response in an earthquake situation.

These earthquake-resistant soundproof walls can reduce maintenance costs and ensure a long lifespan, and can be applied in various environments such as roads, railways, and apartment complexes. In addition, they can effectively respond to external shocks such as strong winds and traffic vibrations in addition to earthquakes, so they are highly utilized.

In addition, the present invention applies a modular structure separated into an upper support, a central body, and a lower support to facilitate assembly and maintenance on site, and is designed to allow individual parts to be replaced as needed. This makes the installation and management of the soundproof wall more convenient, and can be expected to have the effect of increasing long-term operational efficiency.

As a result, the present invention can overcome the limitations of existing soundproof walls and provide a soundproof facility that can be safely maintained even in the event of a natural disaster. This has the technical advantage of minimizing damage to life and property and implementing a safer and more efficient soundproof wall.

In addition to the effects described above, the specific effects of the present invention are described below together with specific details for carrying out the invention.

Figure 1 is a drawing showing the configuration of a soundproof wall facility including an earthquake-resistant function of the present invention.
Figure 2 is a drawing showing a configuration in which a support member is elastically supported by metal elastic members in a fixing hole.
Figure 3 is a drawing showing an example of the configuration of a support member according to the present invention.
Figure 4 is a drawing showing an example of a configuration in which the lower support is supported within a fixing hole.
Figure 5 is a drawing showing an example of further forming a buried foundation underground.
Figure 6 is a drawing showing an example of a soundproofing plate according to the present invention being coupled to an installation hole.
Figure 7 is a drawing showing an example in which multiple soundproofing panels are formed.
Figure 8 is a drawing showing an example in which grid holes are formed in unit soundproofing plates.
Figure 9 is a drawing showing an example in which unit soundproofing plates are connected through joint members.

Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings so that a person having ordinary skill in the art to which the present invention pertains can easily implement the present invention.

The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly explain the present invention, parts irrelevant to the description are omitted, and the same reference numerals are used for identical or similar components throughout the specification.

Hereinafter, the expression “any component is provided or arranged on the “upper (or lower)” part of the description or “upper (or lower)” part of the description means that any component is provided or arranged in contact with the upper surface (or lower surface) of the description.

Additionally, it is not limited to not including any other configuration between the above description and any configuration provided or arranged on (or under) the description.

The following describes a soundproof wall facility including an earthquake-resistant function of the present invention with reference to the attached drawings.

Fig. 1 is a drawing showing the configuration of a soundproof wall facility including an earthquake-resistant function of the present invention. Fig. 2 is a drawing showing a configuration in which a support member is elastically supported by metal elastic members in a fixing hole.

Referring to FIGS. 1 and 2, a soundproof wall structure including an earthquake-resistant function of the present invention comprises a foundation (100) having a lower portion buried in the ground along a boundary between an apartment complex and a road, a plurality of support members (300) installed on the foundation (100) to be upright with intervals along the longitudinal direction of the foundation (100), a plurality of horizontal frame members (400) joined to the plurality of support members (300) in a horizontal direction with intervals above and below, and soundproof panels (500) installed in each of installation holes (401) formed in a grid arrangement between the plurality of support members (300) and the plurality of horizontal frame members (400).

In the above base part (100), fixing holes (110) are formed at intervals.

The lower part of the above plurality of supporting members (300) is placed inside each of the above fixing holes (110).

The above fixed holes (110) are filled with an elastic cushioning material, and the cushioning material is filled between each of the plurality of supporting members (300) and the inner circumference of each of the above fixed holes (110).

A plurality of locations around the lower portion of the plurality of supporting members (300) and a plurality of locations around the inner circumference of each of the fixing holes (110) are elastically connected by metal elastic members (120) formed of metal.

Referring to the above configuration, the soundproof wall facility including the earthquake-resistant function of the present invention is composed of major components such as a foundation (100), a support (300), a horizontal frame (400), and a soundproof board (500), and is designed to function stably even when an earthquake or external impact occurs. In particular, the soundproof wall is enabled to react flexibly by using a fixing hole (110) formed in the foundation (100) and a buffer material and a metal elastic member (120) filled therein.

When an earthquake occurs, the support member (300) is connected to the foundation member (100) in a manner that allows for elastic movement rather than being a fixed structure, so that it can absorb shock. Specifically, the lower part of the support member (300) is placed inside a fixed hole (110) formed in the foundation member (100), and the inside of this fixed hole (110) is filled with an elastic cushioning material. This cushioning material effectively absorbs shock between the support member (300) and the fixed hole (110) when an earthquake or external shock is applied, thereby preventing structural damage.

In addition, several locations around the lower portion of the support member (300) and several locations around the inner circumference of the fixing hole (110) are elastically connected through a metal elastic member (120). This metal elastic member (120) allows the support member (300) to shake within a certain range, while controlling it so that deformation exceeding a certain level does not occur. In other words, it prevents the soundproof wall from shaking violently or collapsing when an earthquake occurs, and allows it to maintain stability by appropriately absorbing vibrations.

In order to maintain the structural balance of the soundproof wall, a plurality of support members (300) and horizontal frame members (400) are connected to each other in a grid arrangement. This structure effectively distributes the force applied to the entire soundproof wall, so that even if an earthquake or external impact occurs, the load is not concentrated on a specific part. In addition, a soundproof plate (500) is installed in the installation hole (401) formed in the horizontal frame member (400), so that the soundproof wall can continuously perform its original function of blocking noise.

The soundproof wall structure of the present invention has the following effects through these structural characteristics. First, when an earthquake or external impact is applied, the buffer material and the metal elastic member (120) effectively absorb the impact, thereby minimizing damage to the soundproof wall. Second, the connection method between the support member (300) and the foundation member (100) is designed to be elastic, so that the soundproof wall can flexibly respond to external impact, thereby improving long-term durability. Third, the soundproof wall can shake within a certain range, so that it can maintain balance even in a strong earthquake, and reduce the risk of collapse.

In addition, the soundproof wall of the present invention has the effect of reducing maintenance costs. If an existing soundproof wall is damaged due to an earthquake or external impact, a complete repair work is required, but the soundproof wall of the present invention has a reduced structural damage due to the role of the shock-absorbing buffer material and the metal elastic member (120), so that the maintenance cycle is extended and costs are reduced.

As a result, the soundproof wall structure of the present invention maintains the noise blocking function of existing soundproof walls, while enhancing the earthquake resistance performance so that it can be safely maintained even in the event of an earthquake or external impact. Through this, it can be practically utilized in various environments such as roads, railways, and apartment complexes, and can minimize damage to life and property.

Fig. 3 is a drawing showing an example of a configuration of a support member according to the present invention. Fig. 4 is a drawing showing an example of a configuration in which a lower support member is supported within a fixing hole.

Referring to FIGS. 3 and 4, each of the plurality of support members (300) includes an upper support member (310), a plate-shaped central body (320) connected to the lower end of the upper support member (310), and a lower support member (330) extending downward from the lower end of the central body (320) and inserted into each of the fixing holes (110).

The upper support (310) includes a first support (311) having a polygonal shape, a second support (312) that is connected to the outer periphery of the first support (311) and has a circumference, and a third support (313) that is connected to the outer periphery of the second support (312).

The above central body (320) is inserted into the step portion (111) connected to the fixing hole (110) at the top of the base portion (100).

And, at multiple locations on the inner circumference of the above-mentioned fixing holes (110), cylinders (130) having axes (131) protruding toward the inside of the above-mentioned fixing holes (110) are installed.

At the end of the shaft (131) of each of the above cylinders (130), a rotary ball (132) is installed to roll.

The above rotary ball (132) is brought into contact with the circumference of the lower support (330) so as to roll.

The above cylinders (130) are driven by the control of the control unit (600).

A slope measuring device (610) is installed on the upper support (310) to measure the slope of the upper support (310) and transmit the measured slope to the control unit (600).

In the above control unit (600), a standard slope is preset.

The above control unit (600) controls in real time the axis (131) of the cylinders (130) to protrude or insert so that the measured inclination reaches the reference inclination.

The above lower support (330) is formed in a circular shape.

The soundproof wall structure of the present invention includes a multi-stage support structure, an automatic adjustment system based on a rotating ball (132) and a cylinder (130), and a real-time slope adjustment function linked to a control unit (600) to maximize earthquake-resistant function. Through these components, the soundproof wall can flexibly react when an earthquake or external impact occurs and adjust its balance in real time to maintain structural stability.

The shock absorption function through the multi-stage structure of the support member (300) is explained.

The support member (300) is composed of an upper support member (310), a central body (320), and a lower support member (330), and each element is separated but connected to each other, allowing for structurally flexible movement when an earthquake occurs.

The lower support (330) is formed in a circular shape and is inserted into the fixing hole (110) of the base (100).

At this time, the central body (320) is inserted into the step (111) at the top of the foundation (100), thereby preventing excessive shaking of the support member (300) and providing stable support when an earthquake occurs.

The shock-absorbing and balancing actions of the cylinder (130) and the rotating ball (132) are described.

A cylinder (130) is installed at multiple locations on the inner circumference of the fixed hole (110), and a rotary ball (132) is placed at the end of the shaft (131) of the cylinder (130).

The perimeter of the lower support (330) comes into contact with the rotary ball (132), and when the cylinder (130) is driven, the rotary ball (132) plays a role in smoothly adjusting the movement of the lower support (330).

When an earthquake occurs and the soundproof wall shakes, the lower support (330) makes contact with the rotating ball (132) and rolls to cushion the impact and maintain a stable position within the foundation (100).

The real-time balance adjustment function of the control unit (600) is described.

A slope measuring device (610) is installed on the upper support (310) to continuously monitor the slope of the soundproof wall.

The measured slope is transmitted to the control unit (600), and the control unit (600) has a reference slope set in advance.

When the soundproof wall tilts or deforms during an earthquake, the control unit (600) adjusts the axis (131) of the cylinder (130) in real time to protrude or insert.

This allows the sound barrier to automatically adjust its balance when affected by an earthquake, preventing it from collapsing or tilting severely.

Through this, the slope of the sound barrier can be continuously detected and automatically adjusted by driving the control unit (600) and cylinder (130), so that a stable state can be maintained even when an earthquake occurs. Unlike existing sound barriers, the balance can be automatically maintained without direct human intervention, reducing the maintenance burden.

In addition, the rotary ball (132) and cylinder (130) absorb shock when they come into contact with the lower support (330), and induce the soundproof wall to shake naturally without collapsing. Accordingly, the soundproof wall can be stably maintained even when subjected to external shocks such as earthquakes or strong winds.

In addition, thanks to the multi-stage structure of the support member (300) and the impact relief system based on the rotary ball (132), the load applied to the soundproof wall is effectively distributed, and structural fatigue is reduced. Through the roles of the cylinder (130) and the rotary ball (132), wear of the support member (300) can be minimized, which extends the maintenance cycle and has a cost-saving effect.

The soundproof wall of the present invention is designed to withstand various external impacts such as earthquakes, strong winds, and traffic vibrations, beyond a simple soundproofing function. Therefore, it can be utilized in various environments such as highways, railways, apartment complexes, and industrial complexes, and can be particularly reliably applied in areas where earthquakes occur frequently.

The lower support (330) is formed in a circular shape, so that it can move smoothly inside the fixed hole (110) and make smooth contact with the cylinder (130) and the rotary ball (132).

In addition, since the central body (320) is stably inserted into the step portion (111), structural balance can be easily achieved when installing a soundproof wall, and individual parts can also be easily replaced as needed.

Accordingly, the present invention has significantly improved the seismic performance of existing soundproof walls by including a multi-stage support structure, shock mitigation and balance maintenance functions using a cylinder (130) and a rotating ball (132), and a real-time automatic adjustment function via a control unit (600). Through this, even if an earthquake or external impact occurs, the soundproof wall can maintain balance and minimize structural damage, and maintenance cost reduction and long-term durability increase effects can be expected. In addition, it has an innovative technological advantage that the soundproof wall can maintain stability on its own without human intervention through a real-time balance adjustment function.

Therefore, the soundproof wall facility of the present invention overcomes the limitations of existing soundproof walls and has high practicality as an earthquake-resistant soundproof wall system that can be safely and effectively used in various environments such as highways, railways, and apartment complexes.

Figure 5 is a drawing showing an example of further forming a buried foundation underground.

Referring to Fig. 5, a buried foundation (200) is formed in the ground, in which a lifting groove (210) of a certain depth is formed.

In the above-mentioned elevator home (210), elevator cylinders (220) having an elevator shaft (221) that is driven to ascend and descend by the control of the control unit (600) are installed.

The above-mentioned base part (100) is positioned in the above-mentioned lifting home (210), and the lower end of the above-mentioned base part (100) is supported by being joined to the upper end of the lifting shaft (221) of the above-mentioned lifting cylinders (220).

In particular, the control unit (600) controls the shaft (131) of the cylinders (130) to protrude or insert in real time so that the measured slope reaches the reference slope, but if a preset limit time is exceeded, the control unit lowers the lifting shaft (221) of the lifting cylinders (220) so that the base (100) is accommodated inside the lifting home (210).

In addition, although not shown in the drawing, rails are formed along the outer periphery of the base (100) in the up-down direction, and rail grooves are formed along the inner periphery of the lifting groove (210) to guide movement by being combined with the rails.

The present invention includes an underground storage system using a buried foundation (200) and an elevating cylinder (220) to maximize the stability of a soundproof wall in the event of an earthquake. Through this, when there is a risk of the soundproof wall being overturned by a serious external force, the foundation (100) is stored underground to minimize structural damage and maintain durability.

The placement of the embedded foundation (200) on the elevator platform (210) and its basic support role are explained.

A landing groove (210) of a certain depth is formed in the ground, and a buried foundation (200) is installed inside it.

The base (100) of the soundproof wall is positioned on the elevator home (210) and the lower part is supported by being connected to the elevator shaft (221) of the elevator cylinder (220).

Normally, the sound barrier is positioned above ground to function normally, but when necessary, the lifting cylinder (220) is operated to allow the sound barrier to be stored underground to a certain extent.

Describes real-time slope adjustment and automatic storage operation.

A slope measuring device (610) is installed on the upper support (310) of the soundproof wall, and the slope of the soundproof wall is continuously detected through this measuring device.

When the slope deviates from the standard slope, the control unit (600) adjusts the balance by protruding or inserting the shaft (131) of the cylinder (130). If the slope is not stable even after exceeding the preset limit time, the lifting cylinder (220) operates to lower the lifting shaft (221) and control the base (100) to be stored inside the lifting groove (210). Through this, when there is a risk of the soundproof wall collapsing, stability can be maintained by partially storing it in the ground.

Describes the stable movement action through rails and rail homes.

Although not shown in the drawing, a rail is formed along the outer circumference of the base (100) along the up-down direction, and a rail groove is formed along the inner circumference of the lifting groove (210) to be combined with the rail. This rail and rail groove structure guides the soundproof wall to move stably in the vertical direction, and plays a role in allowing the lifting cylinder (220) to move smoothly without shaking when lifting the soundproof wall.

Additionally, it serves as a guide to ensure that the sound barrier is returned to its correct location when it is reinstalled.

The present invention can prevent overturning and structural damage by partially retracting the sound barrier into the ground when real-time balance adjustment fails or the risk increases. Through this, the sound barrier can be safely protected without easily collapsing even when a strong earthquake occurs.

In addition, existing soundproof walls are structurally fixed, making it difficult to take separate measures when an earthquake occurs. However, in the present invention, a response system can be implemented that detects the state of the soundproof wall in real time through the automatic control system of the control unit (600) and automatically places it underground when necessary.

In addition, when external impacts such as strong earthquakes or typhoons are expected, the sound barrier can be buried underground in advance to minimize the impact and reduce damage to the sound barrier. This increases the durability of the sound barrier and can be expected to reduce maintenance costs.

Describes stable lifting operation through a lifting cylinder (220) and rail system.

The lifting shaft (221) of the lifting cylinder (220) is connected to the lower part of the base (100), and the soundproof wall can be raised and lowered stably through the rail and rail groove structure.

Since the sound barrier can be moved to the exact location without shaking vertically, not only is the earthquake resistance enhanced, but long-term structural stability is also secured.

The earthquake-resistant soundproof wall of the present invention can be used in areas where earthquakes occur frequently, coastal areas with strong winds, and near roads and railways with heavy traffic, and because it can automatically respond to the external environment, it can be effectively applied not only to earthquakes but also to various natural disasters such as strong typhoons, heavy rain, and shock vibration.

Therefore, the present invention overcomes the limitations of the earthquake-resistant performance of existing soundproof walls by including an underground storage function using a landfill foundation (200) and an elevating cylinder (220). If the soundproof wall is at risk of falling due to an earthquake or external impact, it is designed to automatically adjust in real time and, if necessary, to minimize structural damage by partially storing it underground.

In particular, the sound barrier can be raised and lowered stably through the lifting cylinder (220), rail and rail home structure, and the control unit (600) automatically detects and adjusts the inclination of the sound barrier, thereby implementing an innovative structure in which the sound barrier can respond to an earthquake on its own without separate human intervention.

Due to these technical advantages, the soundproof wall structure of the present invention can be practically utilized in various environments such as highways, railways, apartment complexes, and industrial complexes, and has high practicality as an earthquake-resistant soundproof wall system that can effectively respond to external shocks such as earthquakes, typhoons, strong winds, and traffic vibrations.

Figure 6 is a drawing showing an example of a soundproofing plate according to the present invention being coupled to an installation hole.

Referring to Fig. 6, a square-shaped elastic tube (410) is installed along the inner circumference of each of the installation holes (401), and a joining frame (420) to which each of the soundproof plates (500) is joined is installed on the inner circumference of the elastic tube (410).

The present invention provides a structure that applies an elastic tube (410) and a joining frame (420) so that a soundproofing panel (500) of a soundproofing wall can be stably joined to an installation hole (401). This prevents the soundproofing panel (500) from being easily detached due to external impact or vibration, increases durability, and maximizes the soundproofing effect.

Describes the shock absorption and soundproofing plate fixing function through an elastic tube (410).

A square-shaped elastic tube (410) is arranged along the inner circumference of each installation hole (401). Since the elastic tube (410) has elasticity, it can gently wrap and stably fix the soundproofing plate (500) when it is installed. When an external impact or vibration occurs, the elastic tube (410) absorbs the impact and prevents the soundproofing plate (500) from shaking or falling off easily.

The stable support role of a soundproof board (500) using a joining frame (420) is explained.

A joining frame (420) for joining a soundproofing plate (500) is installed on the inner periphery of the elastic tube (410). The joining frame (420) firmly fixes the soundproofing plate (500) and supports the soundproofing plate (500) so that its shape is not deformed.

The soundproofing plate (500) is maintained in balance by the joining frame (420), while ensuring appropriate fluidity through the elasticity of the elastic tube (410).

Since the soundproofing plate (500) is not simply directly fixed to the installation hole (401), but is fixed through an elastic tube (410) and a joining frame (420), it does not easily fall off due to external impact, wind, vibration, etc. Accordingly, the durability of the soundproofing plate (500) is increased, the maintenance cycle is extended, and costs can be reduced.

In addition, the soundproof wall may be subject to various external vibrations and impacts in highways, railways, industrial areas, etc., and the elastic tube (410) alleviates these and prevents the soundproof panel (500) from being damaged. When an earthquake or strong wind occurs, the elastic tube (410) can appropriately control the movement of the soundproof panel (500) to minimize deformation.

In addition, since the elastic tube (410) is structured to wrap around the soundproofing plate (500) and the installation hole (401) so that no gap is created between them, the soundproofing plate (500) is perfectly sealed, thereby maximizing the soundproofing effect. In the existing soundproofing wall, there was a problem that noise leaked out due to a small gap being created between the soundproofing plate and the frame, but by applying the structure of the present invention, such a problem can be prevented.

In addition, the structure using the elastic tube (410) and the joining frame (420) makes it easy to install and replace the soundproofing plate (500). Only a specific soundproofing plate (500) can be replaced during maintenance, and the flexibility of the elastic tube (410) makes it easier to install than the existing fixed soundproofing plate.

Accordingly, the present invention provides a structure for stably connecting a soundproofing plate (500) to an installation hole (401) using an elastic tube (410) and a connecting frame (420). Through this, various effects such as preventing the soundproofing plate (500) from falling off, reinforcing the shock absorption function, maximizing the soundproofing effect, reducing maintenance costs, and reinforcing earthquake-resistant performance can be obtained.

Figure 7 is a drawing showing an example in which multiple soundproofing panels are formed.

Referring to FIG. 7, the soundproofing plate (500) includes a square-shaped outer frame (510) that is elastically connected to the connecting frame (420), unit soundproofing plates (520) that are arranged with a front-back interval on the inner side of the outer frame (510), and an elastic connecting member (530) that connects the outer perimeter of the unit soundproofing plates (520).

The outer perimeter of the above elastic connecting member (530) is connected to the inner perimeter of the outer frame (510).

In the soundproof wall facility of the present invention, the soundproof panel (500) is not a simple integral structure, but has a multilayer structure composed of an outer frame (510), a unit soundproof panel (520), and an elastic connecting member (530). This is designed to enhance noise blocking performance, while also improving earthquake resistance and increasing the durability of the soundproof panel.

The soundproofing plate (500) is not a simple single plate, but has a structure in which a number of unit soundproofing plates (520) are arranged with spacing between the front and rear inside the outer frame (510).

By placing soundproofing panels with gaps between the front and back, noise is absorbed and dispersed as it passes through the multi-structure, providing a higher soundproofing effect than existing soundproofing walls.

In particular, it is effective in simultaneously blocking high-frequency and low-frequency noises such as vehicle noise and railway noise.

Additionally, the unit soundproofing plates (520) are not able to move independently of each other, but are connected by elastic connecting members (530).

The outer perimeter of the elastic connecting member (530) is connected to the inner perimeter of the outer frame (510), so that the entire soundproofing plate is elastically fixed to the outer frame (510).

When external impact or vibration is applied, the elastic connecting member (530) absorbs the impact, preventing damage to the soundproofing panel (500) and enabling the soundproofing wall to remain stable in the long term.

In addition, while existing integral soundproofing panels were easily at risk of being damaged by strong vibrations or wind, the soundproofing panel (500) of the present invention can effectively disperse vibrations by utilizing the elasticity of the elastic connecting member (530).

When an earthquake or strong wind occurs, the unit soundproofing panels (520) can individually absorb minute vibrations, thereby improving the structural stability of the entire soundproofing wall.

In particular, maintenance of the soundproofing panel (500) becomes easier and the soundproofing effect can be maintained for a long period of time even in environments where continuous vibration is applied, such as highways and railways.

The present invention can absorb and disperse more noise than a single soundproofing plate by applying a multilayered unit soundproofing plate (520) arranged with a front-back interval. This effectively blocks both low-frequency and high-frequency noise, thereby providing a soundproofing effect superior to that of existing soundproofing walls.

In addition, since the soundproofing plate (500) is elastically fixed by the elastic connecting member (530) and the connecting frame (420), the soundproofing plate does not easily fall off or break even when an external impact is applied. In addition, even in road and railway environments where continuous vibration is applied, the deformation of the soundproofing plate is small, which has the effect of reducing maintenance costs.

In addition, the multilayer structure of the soundproofing plate (500) and the role of the elastic connecting member (530) allow the soundproofing wall to maintain balance when an earthquake occurs, and minimize deformation and damage to the soundproofing plate. Even when strong winds blow, the elastic connecting member (530) absorbs shock, preventing the soundproofing plate from shaking excessively and helping to prevent the soundproofing wall from falling over.

In addition, although it is a multilayer structure, individual replacement and maintenance of the soundproofing panel (500) is easy thanks to the elastic connecting member (530) and the connecting frame (420). While existing soundproofing walls require complete replacement when damaged, if the structure of the present invention is applied, only damaged unit soundproofing panels (520) can be individually replaced, thereby reducing maintenance costs.

Figure 8 is a drawing showing an example in which grid holes are formed in unit soundproofing plates.

Referring to Fig. 8, each of the unit soundproofing plates (520) has a grid-shaped grid hole (521) filled with a gel-like soundproofing material formed inside.

Each of the above grid holes (521) is formed at a position where the positions intersect each other in each of the unit soundproofing plates (520).

In the present invention, a structure is applied in which a grid hole (521) is formed inside a unit soundproofing plate (520) and a gel-like soundproofing material is filled inside the grid hole (521). Through this, the noise blocking performance is maximized while the structural stability of the soundproofing plate (520) is maintained and external shock or vibration can be effectively absorbed.

Inside the unit soundproofing plate (520), a grid-shaped grid hole (521) is formed, and the inside of the grid hole (521) is filled with a gel-like soundproofing material, which absorbs and disperses the noise when the sound is transmitted into the soundproofing plate. By applying a multilayer grid structure rather than a conventional single-plate structure, the noise is reflected and absorbed more effectively inside the soundproofing plate, thereby increasing the noise blocking effect.

It provides multiple soundproofing functions through the cross arrangement of grid holes (521).

The grid holes (521) formed in each of the unit soundproofing plates (520) are arranged at positions that intersect each other, so that noise passing through one unit soundproofing plate (520) is additionally absorbed and dispersed when passing through the grid holes (521) of the next unit soundproofing plate (520).

Through this, noise passing through the soundproof wall is gradually attenuated, further enhancing the noise blocking effect.

Shock absorption and vibration reduction effects are achieved by utilizing soundproofing materials on gel.

The inside of the grid hole (521) is filled with a gel-like soundproofing material, so that when the soundproofing plate (520) receives an external impact, the gel can absorb the impact and disperse the energy.

In particular, when the soundproof wall shakes due to an earthquake, strong wind, traffic vibration, etc., the gel inside the soundproof panel (520) generates internal friction and absorbs shock, preventing the soundproof panel from being easily deformed.

The present invention applies a multi-soundproofing system utilizing a lattice structure rather than a simple single soundproofing panel, so that noise blocking performance is greatly improved compared to existing soundproofing walls.

In particular, the cross-arranged grid holes (521) form a multi-sound-absorbing structure, allowing sound to be gradually attenuated inside the soundproofing panel.

This can effectively block out strong noise from highways, railways, industrial complexes, etc.

Since the soundproofing material in the gel form of the present invention acts to absorb shock, the soundproofing plate (520) is not easily damaged when subjected to external shock.

In particular, the durability of sound barriers is increased even in environments with heavy traffic, such as roads, railways, and continuous vibrations, which can extend the maintenance cycle and reduce costs.

In addition, the soundproofing material on the gel disperses the shock internally when an earthquake occurs, and reduces the structural deformation of the soundproofing plate (520) itself, allowing the soundproofing wall to maintain balance. Even when a strong wind blows, the soundproofing wall does not shake, but the gel material inside absorbs the shock, preventing the soundproofing wall from being easily damaged.

In addition, the weight of the soundproofing plate (520) is reduced and the structural stability is strengthened.

By forming the grid holes (521), the overall weight of the soundproofing board (520) can be reduced, making installation easier and reducing the load burden of the soundproofing wall. Even though the weight of the soundproofing board (520) is reduced, structural stability can be maintained because the gel-like soundproofing material is filled inside.

The present invention provides superior performance to existing soundproof walls by applying a structure in which a grid hole (521) is formed inside a unit soundproofing plate (520) and the inside is filled with a gel-like soundproofing material.

Figure 9 is a drawing showing an example in which unit soundproofing plates are connected through joint members.

Referring to Fig. 9, among the unit soundproofing plates (520), two adjacent unit soundproofing plates (520) are connected through joint members (540). The joint members (540) are made of an elastic material.

At each end of the above connecting members (540), a catch (541) is formed.

The above connecting members (540) penetrate the two unit soundproofing plates (520), and each of the hanging ends (541) is in close contact with the outer surfaces of the two unit soundproofing plates (520).

In the soundproofing wall system of the present invention, a structure is applied in which unit soundproofing panels (520) are connected with a joint member (540) formed of an elastic material. Through this, organic bonding between soundproofing panels (520) is possible, and external shocks or vibrations can be effectively absorbed, thereby improving the durability of the soundproofing wall.

An elastic bond is formed between soundproofing plates (520) through a joint member (540).

The unit soundproofing plates (520) do not exist individually, but are connected to each other by a connecting member (540). The connecting member (540) is formed of an elastic material, allowing the soundproofing plates (520) to react flexibly when subjected to external impact or vibration.

Through this, the soundproofing plates (520) can absorb and disperse vibrations while being connected to each other rather than moving independently.

The fixing action of the soundproof plate (520) by the catch (541) is explained.

A catch (541) is formed at each end of the joint member (540). After the joint member (540) penetrates the unit soundproofing plates (520), the catch (541) is in close contact with the outer surface of the unit soundproofing plates (520), thereby preventing the joint member (540) from coming off.

This allows the soundproofing plates (520) to be firmly connected while maintaining a certain level of fluidity.

When an earthquake or strong wind occurs, the soundproofing plates (520) are bound to vibrate or shake. At this time, the connecting member (540) elastically connects the soundproofing plates (520), thereby reducing the deformation of the individual soundproofing plates (520) and effectively dispersing the impact.

In particular, since the individual soundproof panels (520) do not shake independently but are connected and disperse the shock, the stability of the entire soundproof wall increases.

The present invention prevents the soundproofing panels (520) from shaking individually by utilizing a joint member (540), and enables elastic movement while maintaining the overall sense of unity. Through this, the soundproofing panels (520) do not easily fall off or shake, and the soundproofing wall can be structurally stable even in strong winds or earthquakes.

In addition, the joint member (540) is formed of an elastic material, so it effectively absorbs external impact. Since the soundproofing panels (520) are not individually impacted, but are connected through the joint member (540) to disperse the impact, the durability of the soundproofing wall increases. As a result, the soundproofing wall can be used for a long time, and the maintenance cycle can be extended, so that management costs can be reduced.

In addition, rather than simply fixing the soundproofing plates (520), by connecting them through a connecting member (540), the gap between the soundproofing plates is reduced, thereby preventing noise from leaking out. In the case of existing soundproofing walls, there were many cases where some noise leaked out at the connecting portion between the soundproofing plates (520), but by applying the structure of the present invention, the noise blocking effect can be maximized.

In addition, due to the structure of the joint member (540) and the catch (541), the soundproofing board (520) can be easily joined and separated. If a specific soundproofing board (520) is damaged, only the damaged soundproofing board (520) can be replaced without having to dismantle the entire soundproofing wall, making maintenance easy.

The present invention overcomes the limitations of existing soundproof walls and significantly improves earthquake resistance by applying a structure that elastically connects unit soundproof panels (520) using a joint member (540). Through this, various effects such as increased structural stability of the soundproof wall, improved noise blocking effect, enhanced shock absorption function, reduced maintenance costs, and increased earthquake and strong wind resistance can be expected.

The present invention is not limited to the specific preferred embodiments described above, and anyone with ordinary skill in the art to which the present invention pertains may make various modifications without departing from the gist of the present invention claimed in the claims, and such modifications are within the scope of the claims.

100: Base
110: Fixed hole
111: Single jaw
120: Metal elastic member
130: Cylinder
131: Axis
132: Rotating Ball
200: Landfill foundation
210: Elevator platform
220: Lifting cylinder
221: Elevator shaft
300: Landlord
310: Top support
311: First Landlord
312: Second Landlord
313: Third Landlord
320: Central body
330: Bottom support
400: Horizontal frame section
401: Installation hole
410: Elastic tube
420: Combined Frame
500: Soundproofing panel
510: Outer Frame
520: Unit soundproofing panel
521: Lattice Hall
530: Elastic connecting member
540: Absence of joint
541: The Hanging Tower
600: Control Unit
610: Gradient Meter

Claims (4)

A foundation whose lower part is buried underground along the boundary between an apartment complex and a road;
A plurality of support members installed on the foundation so as to be erected at intervals along the length direction of the foundation member;
A plurality of horizontal frame sections joined horizontally to the plurality of supporting sections at vertical intervals;
Including soundproofing plates installed in each of the installation holes formed in a grid arrangement between the above plurality of supporting members and the above horizontal frame members,
In the above base, fixing holes are formed at intervals,
The lower part of the above multiple holding units is,
are placed inside each of the above fixed holes,
The above fixing holes are filled with an elastic cushioning material, and the cushioning material is filled between each of the plurality of supporting members and the inner circumference of each of the fixing holes.
The multiple locations around the lower portion of the above-mentioned plurality of supporting members and the multiple locations inside each of the above-mentioned fixing holes are elastically connected by metal elastic members formed of metal.
Each of the above plurality of support members includes an upper support member, a central body in the form of a plate connected to the lower end of the upper support member, and a lower support member extending downward from the lower end of the central body and inserted into each of the fixing holes.
The upper support member includes a first support member having a polygonal shape, a second support member that is connected to the outer periphery of the first support member and has a circumference, and a third support member that is connected to the outer periphery of the second support member.
The above central body is inserted into a step portion connected to the fixing hole at the top of the base portion,
At multiple locations on the inner circumference of the above fixing holes, cylinders having axes protruding inwardly of the above fixing holes are installed, and at an end of the axis of each of the cylinders, a rotary ball is installed to roll, and the rotary ball comes into contact with the circumference of the lower support so as to roll, the cylinders are driven by the control of the control unit, and an inclination measuring device is installed on the upper support to measure the inclination of the upper support and transmit the measured inclination to the control unit, and a reference inclination is preset in the control unit, and the control unit controls in real time the axes of the cylinders to protrude or insert so that the measured inclination reaches the reference inclination,
The above lower support is formed in a cylindrical shape, and a buried foundation is formed in the ground in which an elevator groove of a certain depth is formed, and in the elevator groove, elevator cylinders having an elevator shaft that is elevated and driven by the control of the control unit are installed, and the foundation is positioned in the elevator groove, and the lower end of the foundation is supported by being connected to the upper end of the elevator shaft of the elevator cylinders,
If the above control unit exceeds a preset limit time, it controls the lifting shafts of the above lifting cylinders to lower the base so that it is accommodated inside the above lifting home.
On the outer periphery of the above-mentioned base, rails are formed along the up-down direction, and on the inner periphery of the above-mentioned lift home, rail grooves are formed to guide movement by being combined with the above-mentioned rails.
A square elastic tube is installed along the inner circumference of each of the above installation holes, and a joining frame to which each of the above soundproofing plates is joined is installed along the inner circumference of the elastic tube.
The above soundproof board includes a square-shaped outer frame elastically connected to the joining frame, unit soundproof boards arranged with front-back spacing on the inner side of the outer frame, and an elastic connecting member connecting the outer perimeters of the unit soundproof boards, and the outer perimeter of the elastic connecting member is connected to the inner perimeter of the outer frame,
Inside each of the above unit soundproofing plates, a grid-shaped lattice hole is formed, filled with a gel-like soundproofing material.
Each of the above grid holes is characterized in that they are formed at positions where their positions intersect each other in each of the unit soundproofing plates.
Soundproof wall facility including earthquake-resistant function.
In paragraph 1,
Among the above unit soundproofing plates, two adjacent unit soundproofing plates are connected through joint members,
The above joint members are made of elastic material,
At each end of the above connecting members, a catch is formed,
The above connecting members are characterized in that they penetrate the two unit soundproofing plates, and each of the hanging ends is in close contact with the outer surface of the two unit soundproofing plates.
Soundproof wall facility including earthquake-resistant function. delete delete