KR101333997B1 - Ventilated sounddproof wall - Google Patents

Abstract

According to the present invention, in the ventilated soundproof wall having a soundproof panel 20 coupled to be rotatable for ventilation with respect to the soundproof wall strut 10, to have a restoring force upon opening by ventilation of the soundproof panel 20 In order to delay the restoring force in the process of returning the soundproof panel 20 to its original position by the elastic portion 30 and the elastic portion 30 coupled between the soundproof wall support 10 and the side surface of the soundproof panel 20. A ventilation soundproof wall having an air buffer portion 40 hinged at both ends is provided between the panel 20 and the soundproof wall strut 10.

Description

Ventilated sounddproof wall

The present invention relates to a soundproof wall of a road, and more particularly, to allow the rotatable soundproof wall to be partially opened against a wind pressure above a threshold acting on the soundproof wall of the road, thereby protecting the props of the soundproof wall and at the same time rotating upon sudden stop of the wind pressure. The present invention relates to a ventilation type soundproof wall that can improve the function of the soundproof wall post and extend its life by preventing the overload resilience from being transferred to the post in the process of returning the soundproof wall to its original state.

In order to prevent noise generated from the vehicle from being transmitted to a building adjacent to the road or the like, a soundproof wall is generally installed on the road to block the noise.

Road noise barriers are installed to block the noise of vehicles on highways, highways, motorways, bridges, or railways that cross high-rise buildings, and the height of noise barriers is relatively high. It may be damaged by wind pressure caused by wind pressure such as gusts. In particular, in the case of soundproof walls of roads in coastal areas, inland valleys and mountains, which are vulnerable to typhoons and gusts, the pressure resistance design is important for wind pressure.

At this time, since the moment due to the wind pressure increases in proportion to the height of the soundproof wall, a soundproof wall of a more durable material must be constructed to prevent breakage of the soundproof wall or inclination of the prop. Due to this problem, when the wind load is expected to reduce the projected area in the wind load direction by rotating the soundproof plate, a technique that can reduce the load of the entire soundproof wall is disclosed by the Utility Model Registration No. 281792.

According to Korean Utility Model No. 281792, an outer frame fitted between a support post and a support, a sound insulation board fitted in a flowable manner within the outer frame, and the sound insulation board are elastically oriented on either side of the rotating shaft in accordance with a wind pressure equal to or greater than the design wind load. A ventilation soundproof plate is provided that includes a compression spring installed between the outer frame and the soundproof plate so as to be rotated by a rotation, and fixing means connecting the soundproof plate to the outer frame within a design wind load and dropping according to the wind pressure above the design wind load. have. At this time, the soundproof plate has a compression spring located in the housing provided on the rotating shaft, the rotation of the soundproof plate is compressed by the displacement of the compression spring, the soundproof plate is opened and then returned to its original position by the rigidity of the compression spring.

As described above, the sound insulation board is opened by the wind load corresponding to the restoring force of the compression spring against the wind load acting on the sound insulation board. When the soundproof plate is opened due to the large wind load, the restoring force of the corresponding compression spring is stored in the compressed spring compressed with the force corresponding to the magnitude of the applied wind load, so that when the soundproof plate is restored to its original state and closed, Strong resilience will work. Accordingly, a strong impact amount acts between the soundproof plate restored and the support frame of the soundproof plate. At this time, the impact amount I = F · t is given. Here, F is a restoring force generated by compression of the compression spring, and t is the contact time between the soundproof plate and the soundproof plate support frame.

As such, when the soundproof plate is restored and closed, the shorter the contact time t between the soundproof plate and the soundproof plate support frame and the magnitude of the restoring force (F) stored in the compression spring, the greater the amount of impact between the soundproof plate and the soundproof plate support frame.

On the other hand, the restoring force stored in the compression spring is stored in proportion to the magnitude of the wind load as described above. In general, the pressure of the wind load acting on the opening of the soundproof wall is about 23 to 55 m / s in terms of wind speed at 150 to 300 kg / m2. It has the force of gust to (super) typhoon by the force of, and when the gusts disappear momentarily, the soundproof plate is restored to its original position, and this force (F) acts between the soundproof plate and the soundproof plate support frame, The contact time t, which is time, is within 0.1 ms. Accordingly, when the gusts are momentarily stopped, a very strong impact is applied between the soundproofing plate and the soundproofing plate support frame by the restoring force and contact time by the compression spring, and the soundproofing plate falls off, and the soundproofing plate and the soundproofing plate support frame are broken. It is becoming.

In order to compensate for this problem, a frame and a plate are manufactured using a material having a large weight, but there is a problem in that the manufacturing cost increases.

Therefore, it is necessary to improve the durability of the soundproof wall by minimizing the impact caused by the restoration of the ventilation soundproof board while efficiently ventilating the wind load, and to develop a condition that can reduce the manufacturing cost due to the weight of the soundproof wall.

It is an object of the present invention to provide a ventilation soundproof wall that can suppress the impact of the restoring force of the ventilation soundproof plate.

Another object of the present invention is to provide a ventilation soundproof wall that can reduce the manufacturing cost by minimizing the weight and the material required of the soundproof wall due to the suppression of the impact of the restoring force of the ventilation soundproof plate.

According to the present invention, in the ventilated soundproof wall having a soundproof panel 20 coupled to be rotatable for ventilation with respect to the soundproof wall strut 10, to have a restoring force upon opening by ventilation of the soundproof panel 20 In order to delay the restoring force in the process of returning the soundproof panel 20 to its original position by the elastic portion 30 and the elastic portion 30 coupled between the soundproof wall support 10 and the side surface of the soundproof panel 20. A ventilation soundproof wall having an air buffer portion 40 hinged at both ends is provided between the panel 20 and the soundproof wall strut 10.

Here, it is preferable that the upper side surface of the sound insulation panel 20 is hinged relative to the side surface of the sound barrier wall support 10 relative to the rotation shaft 22.

In addition, the frame 24 provided on the side of the sound insulation panel 20 has a pair of restoration to have elastic restoring force when the sound insulation panel 20 is opened with respect to the elastic portion 30 coupled to the rotating shaft 22. It is preferred that the pins 26a, 26b are coupled around the axis of rotation 22.

In addition, it is preferable that a hinge coupling piece 28 for hinge coupling of one end of the air buffer unit 40 is provided at a portion below the rotating shaft 22 coupled to the frame 24 of the soundproof panel 20.

In addition, the elastic portion 30 is preferably made of a torsion spring 32 which is coaxially coupled to the rotating shaft 22 of the soundproof panel 20.

In addition, the torsion spring 32 is a circumferentially wound elastic body, and end portions 36a and 36b at both ends thereof are supported inside the restoration pins 26a and 26b coupled to the frame 24 of the soundproof panel 20. desirable.

In addition, the air buffer 40 is composed of a gas spring 42 having a rod 44 'having a piston 44 embedded in a pneumatic cylinder filled with gas, and the piston rod 44' of the gas spring 42. ) Is hinged to the hinge coupling piece 28 of the soundproof panel 20 by a hinge shaft 48a, and the cylinder 46 end of the gas spring 42 is hinged on the side of the soundproof wall support 10. It is preferably hinged by the axis 48b.

Each end of the piston rod 44 'and the cylinder 46 is preferably hinged to the hinge shaft 48b of the soundproof wall support 10 and the hinge shaft 48a of the soundproof panel 20, respectively.

In addition, inside the cylinder 46 of the gas spring 42, the first gas filling portion 46a positioned on the piston rod 44 'side with respect to the piston 44 and the second gas filling portion 46b positioned on the opposite side thereof. It is preferable that a hole 44h having a very small diameter compared to the cylinder 46 penetrates parallel to the piston rod 44 'in the piston 44 positioned therebetween.

According to the present invention, with respect to the restoring force by the elastic part 30, the air buffer part 40 generates a large buffering pressure Pb instantaneously and then gradually decreases the buffering pressure Pb to the restoring force Ft generated. Can be delayed in time. Accordingly, the sound insulation panel 20 can be prevented from being returned to its original position by the elastic portion 30 so as to alleviate the impact between the sound insulation panel 20 and the soundproof wall strut 10, and simplify the installation configuration to produce the cost. It can contribute to the weight reduction of the structure by reducing the cost and simplifying the configuration.

1 is a perspective view of a ventilation sound barrier according to a preferred embodiment of the present invention.
Figure 2 is an exploded perspective view showing a configuration for mitigating the impact of the restoring force on the ventilation panel in the ventilation soundproof wall according to an embodiment of the present invention.
3 is a cross-sectional view showing the operation of the air buffer unit 40 in the ventilation soundproof wall according to the preferred embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings it will be described in detail with respect to the ventilation soundproof wall according to an embodiment of the present invention.

1 is a perspective view of a ventilation soundproof wall according to a preferred embodiment of the present invention, Figure 2 is an exploded view showing a configuration for mitigating the impact of the restoring force on the ventilation panel in the ventilation soundproof wall according to the preferred embodiment of the present invention 3 is a cross-sectional view showing the operation of the air buffer unit 40 in the ventilated soundproof wall according to the preferred embodiment of the present invention.

As shown in Figures 1 to 3, the ventilated soundproof wall according to a preferred embodiment of the present invention is the soundproof wall support 10, the soundproof panel 20 is coupled to enable the rotation for ventilation with respect to the soundproof wall support 10 In order to open with a restoring force when a predetermined pressure or more is applied to the soundproof panel 20, the elastic part 30 coupled between the soundproof wall support 10 and the side surface of the soundproof panel 20, and the elastic part 30. In order to delay the restoring force in the process of returning the soundproof panel 20 to its original position, the air buffer unit 40 is hinged between both ends of the soundproofing panel 20 and the soundproof wall support 10.

Here, the soundproof wall strut 10 is hinged relative to the side of the soundproof wall strut 10 relative to the side of the soundproof wall strut 10.

The soundproof panel 20 is provided with a frame 24 to be coupled to the soundproof wall support 10 so as to rotate upon ventilation of strong winds with respect to the rotating shaft 22 on both sides of the soundproof wall support 10.

The frame 24 provided on the side of the soundproof panel 20 has a pair of restoring pins to have elastic restoring force when the soundproof panel 20 is opened with respect to the elastic part 30 coupled to the rotating shaft 22 ( 26a, 26b are coupled around the axis of rotation 22. In addition, a hinge coupling piece 28 for hinge coupling of one end of the air buffer unit 40 is provided at a portion below the rotating shaft 22 coupled to the frame 24 of the sound insulation panel 20.

The elastic part 30 rotates the rotation of the soundproof panel 20 to return the soundproof panel 20 to its original position by the restoring force Ft when the soundproof panel 20 is opened by the wind pressure acting on the soundproof panel 20. It consists of a torsion spring 32 which is coaxially coupled to the rotating shaft 22 of the soundproof panel 20 as a member for storing the restoring force proportional to the. The torsion spring 32 is a circumferentially wound elastic body whose end portions 36a and 36b are supported inside the restoration pins 26a and 26b, respectively.

The air buffer portion 40 is composed of a gas spring 42 having a rod 44 'having a piston 44 embedded therein in a pneumatic cylinder filled with gas, and an end of the piston 44 of the gas spring 42 is soundproofed. The hinge shaft 48a is hinged to the hinge coupling piece 28 of the panel 20, and the cylinder 46 end of the gas spring 42 is connected to the hinge shaft 48b provided on the side of the soundproof wall support 10. By hinges. At this time, the hinge engagement positions with respect to the end of the cylinder 46 of the gas spring 42 and the end of the piston rod 44 'may be reversed.

Inside the cylinder 46 of the gas spring 42, the first gas filling portion 46a positioned on the piston rod 44 ′ side and the second gas filling portion 46b positioned on the opposite side of the piston 44 are provided. And a hole 44h having a very small diameter compared to the cylinder 46 is penetrated in parallel to the piston rod 44 '.

Therefore, when the restoring force Ft by the torsion spring 32 of the elastic part 30 acts on the piston rod 44 'to the inside of the cylinder 46, the gas of the second gas filling part 46b is compressed at a moment. At the same time, as the gas of the first gas filling part 46a expands, the buffer pressure Pb opposing the restoring force Ft acts on the piston 44. At this time, the buffer pressure Pb is generated in the cylinder 46 as opposed to the sudden restoring force Ft of the torsion spring 32 of the elastic portion 30, and the buffer pressure Pb is changed over time. Accordingly, the gas compressed in the second gas filling part 46b moves to the first gas filling part 46b through the hole 44h formed in the piston 44, and the buffer pressure Pb is changed according to the movement time. Will decrease.

Therefore, with respect to the restoring force by the elastic part 30, the air buffer part 40 temporarily generates a large buffering pressure Pb and then gradually decreases the buffering pressure Pb to timely delay the restoring force Ft. You can. Accordingly, the sound insulation panel 20 can be prevented from being returned to its original position by the elastic portion 30 so as to alleviate the impact between the sound insulation panel 20 and the soundproof wall strut 10, and simplify the installation configuration to produce the cost. It can contribute to the weight reduction of the structure by reducing the cost and simplifying the configuration.

10: soundproof wall prop
20: soundproof panel
22:
24: Frame
26a, 26b: restore pin
28: hinged engagement piece
30:
32: torsion spring
36a, 36b: end
40: air buffer
42: gas spring
44: piston
44 ': piston rod
44h: hall
46a: first gas filling part
46b: second gas filling part
48a, 48b: hinge shaft

Claims (9)

delete delete In the ventilation type soundproof wall having a soundproof panel 20 coupled to enable rotation for ventilation with respect to the soundproof wall prop 10,
Torsion spring 32 which is coaxially coupled to the rotating shaft 22 of the soundproof panel 20 between the soundproof wall support 10 and the side of the soundproof panel 20 in order to have a restoring force upon opening by ventilation of the soundproof panel 20. An elastic portion (30) consisting of;
In order to delay the restoring force in the process of returning the sound insulation panel 20 to its original position by the elastic portion 30, an air buffer portion 40 hinged between both ends of the sound insulation panel 20 and the soundproof wall support 10 is provided. Equipped,
The upper side of the soundproof panel 20 is hinged relative to the side of the soundproof wall strut 10 relative to the rotation axis 22,
The frame 24 provided on the side of the soundproof panel 20 has a pair of restoring pins to have elastic restoring force when the soundproof panel 20 is opened with respect to the elastic part 30 coupled to the rotating shaft 22 ( 26a, 26b) is characterized in that the ventilation sound-proof wall is coupled around the axis of rotation (22). According to claim 3, The hinge coupling piece 28 for one end of the air buffer portion 40 is hinged to the lower portion of the rotary shaft 22 coupled to the frame 24 of the soundproof panel 20 is provided. Ventilation soundproof wall. delete 4. The torsion spring (32) according to claim 3, wherein the torsion spring (32) is a circumferentially wound elastic body whose end portions (36a, 36b) are supported inside the restoration pins (26a, 26b) coupled to the frame of the soundproof panel (20). Ventilated soundproof wall, characterized in that. 4. The gas shock absorbing part (40) according to claim 3, wherein the air buffer part (40) consists of a gas spring (42) having a rod (44 ') in which a piston (44) is embedded in a pneumatic cylinder filled with gas. The end of the rod 44 'is hinged to the hinge coupling piece 28 of the soundproof panel 20 with a hinge shaft 48a, and the end of the cylinder 46 of the gas spring 42 has a side of the soundproof wall support 10. Ventilated soundproof wall, characterized in that the hinge is coupled by a hinge shaft (48b) provided in. 8. The piston rod 44 'and each end of the cylinder 46 are hinged to the hinge axis 48b of the soundproof wall strut 10 and the hinge axis 48a of the soundproof panel 20, respectively. Ventilation soundproof wall characterized in that. 9. The gas cylinder (42) according to claim 7 or 8, wherein the inside of the cylinder (46) of the gas spring (42) is opposite to the first gas filling portion (46a) located on the piston rod (44 ') side with respect to the piston (44). It is characterized in that it has a second gas filling portion (46b) positioned between, the hole 44h having a smaller diameter compared to the cylinder 46 is penetrated in parallel to the piston rod 44 'in the piston (44) located between them. Ventilation soundproof wall.

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