KR101033614B1 - Silence device for gas pressure regulator - Google Patents

Abstract

The static pressure reduction device according to the present invention includes a first porous plate provided at the outlet of the inlet pipe in the silencer casing, a second porous plate configured to have a predetermined space therein, and the first porous plate. A first laminar flow converter configured to convert a turbulent flow of the gas passing through the first porous plate into a laminar flow, which is formed in an inner space formed of the stencil plate and the second porous plate, and a gas between the second porous plate and the second porous plate in the silencer casing. It is configured to include a sound absorbing cylinder positioned to form a flow space of the gas absorbing the noise energy of the gas, and a discharge pipe connected to the outside from the other side of the silencer casing to discharge the gas, thereby minimizing the flow noise of the gas decompressed in the pressure regulator It provides the effect of enabling the design use of quieter gas piping.

Pressure regulator, gas, casing, porous plate, sound absorbing material, laminar flow

Description

Silencer Noise Reduction Device {SILENCE DEVICE FOR GAS PRESSURE REGULATOR}

The present invention relates to a gas pressure regulator noise reduction device installed on a gas supply line such as city gas.

In general, a gas constant pressure regulator installed on a gas supply line such as city gas is a device that supplies a constant gas pressure at a pressure suitable for a consumer by lowering the pressure from high pressure to medium pressure and from medium pressure to low pressure.

Such a pressure regulator generates a turbulent flow of gas inside the pressure regulator as the gas velocity increases in the process of depressurizing the supply pressure of the gas, and as a result, the gas is vibrated, causing severe noise to the outside of the pressure regulator.

In particular, when the gas pipe is installed in the downtown area, the noise generated from the gas pressure regulator has a significant effect on the residential environment of the installation area, so a noise reduction device (or silencer) capable of minimizing the generation of noise is required.

1 and 2 is a view showing a silencer disclosed in the registration room 20-397669 which is one of the noise reduction device of the prior art.

The silencer 4 of the registered design includes a plurality of inner perforation networks 10 having hollow portions so that both sides are open to allow gas movement, and a plurality of inner perforation networks having predetermined intervals in the longitudinal direction inside the inner perforation networks 10. The vortex plate 50, the inner wire mesh 20 surrounding the outer side of the inner perforated network 10, the sound absorbing material 30 provided on the outer side of the inner wire mesh 20, and the outer side of the sound absorbing material 30, A cover for supporting both ends to the outer perforated network 60 defining the volume of the sound absorbing material 30, the outer perforated network 70 provided on the outside of the outer wire mesh 60, and the outer perforated network 10 and the outer perforated network. 40 and a sleeve 80 provided on the outer side of the outer perforation network 70.

This registration design, when the gas flows into the silencer from the pressure regulator, turbulence is formed by the vortex plate 50, the energy of the gas through the open hole 12 and the inner wire mesh 20 of the inner perforated network 10 Is transmitted to the sound absorbing material 30 and the sound absorbing material 30 is configured to absorb this to mitigate the noise generated in the movement of the gas.

However, the noise reduction device of the prior art including the registration design as described above, the gas passing through the center portion, the inner perforated network 10, the inner wire mesh 20, the sound absorbing material arranged in a vortex plate 50 and a cylindrical structure around the center portion 30, the outer wire mesh 60, the outer perforated network 70, etc. are composed of a multi-layered structure as a whole, not only complicated structure, but also simply configured to absorb and reduce the noise energy in the gas flow surroundings However, there is a limiting problem in obtaining a higher noise reduction effect.

The present invention has been made to solve the above problems, by using a sound absorbing cylinder provided around the laminar flow conversion unit and the flow space surrounding the porous plate to minimize the flow noise of the gas generated by the pressure drop more quiet It is an object of the present invention to provide a static pressure noise reduction device that enables the configuration of a gas supply line.

According to an aspect of the present invention, there is provided a silencer noise reduction device comprising: a silencer casing having an inlet pipe into which gas is introduced to one side thereof; A first porous plate provided at an outlet of the inlet pipe in the silencer casing to allow gas to pass therethrough; A second porous plate connected to the first porous plate and configured to have a predetermined space therein together with the first porous plate; A first laminar flow converter configured to convert the turbulent flow of the gas passing through the first porous plate into a laminar flow formed in an inner space formed of the first and second porous plates; A sound absorbing cylinder positioned to form a gas flow space between the second porous plate and the second porous plate in the silencer casing to absorb noise energy of the gas; And a discharge pipe connected to the outside of the muffler casing from the flow space between the second porous plate and the sound absorbing cylinder on the other side of the muffler casing to discharge gas.

The inlet pipe is connected in an expanded structure inside the silencer casing, and the first porous plate is preferably installed at the outlet of the expanded portion.

The first laminar flow converting unit has a structure in which each unit is filled in the first porous plate and the second porous plate, and each unit has a structure in which guide ribs cut in the cylindrical structure are bent into the cylinder. Can be.

Preferably, the second porous plate is supported by the inlet pipe together with the first porous plate, and the other is supported inside the muffler casing by a support rod.

It is preferable that the said sound absorbing cylinder is arrange | positioned so that a sound insulation space may be provided between the inner surfaces of the said silencer casing.

The sound absorbing body includes a sound absorbing material, an inner support sheet provided inside the sound absorbing material and formed with a plurality of holes, an outer support sheet protecting the sound absorbing material from the outside of the sound absorbing material, and an inner support sheet and an outer side of the sound absorbing material. It comprises a side sheet connecting the support sheet.

At this time, the side sheet may be configured such that its outer diameter is larger than the outer diameter formed by the outer support sheet is supported on the inner surface of the muffler casing.

The discharge pipe is provided with an additional structure for reducing the noise therein, the additional structure, the second laminar flow conversion unit may be formed between the third porous plate and the fourth porous plate installed in the transverse direction of the discharge pipe. .

Since the pressure reduction device according to the present invention is configured to allow a gas having a pressure drop through the pressure regulator to be discharged through a flow space provided with a first porous plate, a laminar flow converter, a second porous plate, and a sound absorbing cylinder. By maximizing the noise reduction efficiency, it is possible to design a quieter gas pipe.

That is, the present invention, the gas pressure reduced in the governor (Governor) is converted from the high frequency to the low frequency while passing through the first porous plate, and converted from the turbulent flow to the laminar flow while passing through the laminar flow converter, the second The noise frequency is further reduced while passing through the stencil, and the residual noise is absorbed by the sound absorbing cylinder and the sound insulation space provided around the flow space, thereby maximizing the noise reduction efficiency.

In addition, since the third porous plate, the laminar flow converting unit, and the fourth porous plate are also configured in the discharge pipe, the present invention has an effect of further improving the noise reduction efficiency.

Hereinafter, exemplary embodiments of the present invention will be described with reference to the accompanying drawings.

3 is an external perspective view illustrating a static pressure noise reduction device according to an exemplary embodiment of the present invention, and FIG. 4 is an exploded perspective view illustrating a static pressure noise reduction device according to an embodiment of the present invention. 5 and 6 are longitudinal cross-sectional views and cross-sectional views of a static pressure noise reduction device according to an embodiment of the present invention, and FIGS. 7 and 8 are perspective views illustrating units of the laminar flow converting unit.

As shown in these drawings, the silencer noise reduction device according to an embodiment of the present invention, which is installed to be connected to the gas pipeline behind the constant pressure, the silencer casing made of a cylindrical structure similar in shape to the capsule ( 110 is provided.

The silencer casing 110 may be divided into three parts, the center portion 111 having a cylindrical structure, and a side portion 115 formed in a substantially hemispherical shape and coupled to both sides of the center portion 111.

 The central portion 111 and the side portion 115 are preferably fixed to each other integrally by a welding method.

One side portion 115 and the central portion 111 of the muffler casing 110 is connected to the inlet pipe 120 through which the gas is introduced and the discharge pipe 130 through which the gas is discharged.

To this end, referring to the drawings, holes 112 (see FIG. 5) 116 are formed in the left side portion 115 and the central portion 111, respectively, and the inflow pipe 120 is formed in each of the holes 112 and 116. And the discharge pipe 130 are inserted and connected respectively. The inlet pipe 120 and the outlet pipe 130 are preferably connected to the muffler casing 110 to be fixed by welding or the like.

In the drawings of the embodiment of the present invention, the inlet pipe 120 and the discharge pipe 130 is illustrated a structure connected to be positioned at an approximately 90 degree angle around the silencer casing 110, but is not necessarily limited to this, 180 degrees angle Alternatively, it may be configured to be connected at different angles.

Inlet pipe 120 is provided with a flange portion 123 at the inlet 121, the outlet 125 side is deeply inserted into the silencer casing (110). The inserted outlet 125 is connected to the structure for noise reduction which will be described in detail below. In addition, the outlet 125 side of the inlet pipe may be configured with an extension 126 having an expanded structure inside the silencer casing 110.

The discharge pipe 130 has an inlet 131 is located inside the muffler casing 110 and the flange 135 is provided at the outlet 135. A structure for noise reduction is also installed inside the discharge pipe 130. This is described in detail below.

Now, the noise reduction structure configured inside the silencer casing 110 will be described in order with respect to the direction in which gas flows.

The first porous plate 140 is provided at the outlet 125 of the inlet pipe 120.

The first porous plate 140 is configured to allow the gas introduced through the inlet pipe 120 to pass therethrough, and converts the noise frequency due to the gas flow introduced into the silencer casing 110 from high frequency to low frequency. Done.

The first porous plate 140 is preferably made of a network structure having a plurality of holes formed in the plate body.

The first laminar flow converting unit 150 made of a vortex polishing structure is provided at the rear of the first porous plate 140 so as to convert the flow of the gas passing through the first porous plate 140 from turbulent flow to laminar flow.

As shown in FIG. 7, the first laminar flow converting unit 150 is configured by uniformly arranging polishing units 151, and each unit 151 is bent inward in a cylindrical structure in which both sides are open. A plurality of guide ribs 155 are formed. The guide rib 155 has a structure in which three surfaces are cut from the circumferential surface of the cylinder 152 and bent inwardly of the cylinder 152, so that the guide rib guiding the flow of gas into the inside of the cylinder 152 ( 155 protrudes, and a surface of the cylinder 152 is formed with a structure in which a plurality of holes 153 through which gas passes.

Each of the unit 151, as shown in Figure 8, is configured to be uniformly laminated and filled in the second porous plate 160 having a cylindrical structure to be described later, the stacking direction is the second porous plate ( It is arranged in the same direction as the cylindrical direction of 160. That is, when the cylinder of the second porous plate 160 is arranged in the horizontal direction, the respective unit bodies 151 are also continuously arranged in the horizontal direction, and such a continuous arrangement structure is formed inside the second porous plate 160. It is arranged in a tightly stacked manner to change the flow state of the gas.

The unit body 151 constituting the laminar flow converting unit as described above is just one example, and may be changed and applied to various shapes and structures as long as it can convert gas flow from turbulent flow to laminar flow.

Such units 151 are filled in the first porous plate 140 and the second porous plate 160 to form the first laminar flow converter 150. That is, the first laminar flow converting unit 150 is formed by filling the unit bodies 151 in the network structure formed by the first porous plate 140 and the second porous plate 160.

The second porous plate 160 has a net-shaped structure as a whole so that the gas passing through the first laminar flow converting unit 150 can be discharged. The second porous plate 160 is formed of a cylindrical portion 161 and one side portion 163. .

The second porous plate 160 serves to reduce the noise frequency generated while the gas flows as in the first porous plate 140 to a lower low frequency.

Here, the fixing structures of the first porous plate and the second porous plate will be described.

The first porous plate 140 is fixed to one surface of the second porous plate 160 by welding or the like. In this state, one side, that is, one side of the first porous plate 140 and the second porous plate 160 is inserted into the inlet pipe 120 or is fixed and supported by welding or the like, and the second porous plate on the opposite side The other side of the support 160 is supported by the support rod 165 is supported inside the silencer casing 110.

At this time, the support rod 165 is preferably installed in a cross-shaped structure protruding from the upper, lower, left, right of the second porous plate 160 having a cylindrical structure.

Next, an outer side of the second porous plate 160 is provided with a sound absorbing cylinder 170.

The sound absorbing cylinder 170 is configured to absorb noise energy generated while the gas flows as heat energy due to vibration, and a sound absorbing material 171 made of a material such as polyurethane material is formed to form a porous structure. The silencer casing 110 is formed in a cylindrical or hemispherical structure, respectively, along the inner surface structure of the casing.

In order to maintain the shape of the sound absorbing material 171, the sound absorbing tube 170 has an inner support sheet 172 having a plurality of holes formed on its inner surface, and an outer support sheet 173 having a closed structure on its outer surface. do.

In particular, both side surfaces of the sound absorbing cylinder 170 is provided with a side sheet 175 connecting the inner support sheet 172 and the outer support sheet 173, the outer diameter of the side sheet 175 is an outer support sheet ( The outer surface of 173 is formed to protrude more than the outer diameter formed. This is to form a predetermined sound insulation space 177 between the outer support sheet 173 of the sound absorbing cylinder 170 and the inner surface of the silencer casing 110.

The inner support sheet 172, the outer support sheet 173, and the side sheet 175 are preferably made of a metal sheet.

It is preferable that such an installation structure of the sound absorbing cylinder 170 is applied to not only the center sound absorbing cylinder 170A having a cylindrical structure but also to both sound absorbing cylinders 170B having a hemispherical structure.

Now, a structure for noise reduction configured on the discharge pipe 130 will be described.

The noise reduction structure configured in the discharge pipe 130 includes a third porous plate 180, a second laminar flow converting unit 185, and a fourth porous plate 190 in the gas flow direction.

The structure has a configuration in which a third porous plate 180 and a fourth porous plate 190 are provided at both sides of the second laminar flow converting unit 185.

Here, the second laminar flow converting unit 185 has a unit body 151 (see FIG. 7) like the first laminar flow converting unit 150 provided in the silencer casing 110, and includes a third porous plate 180 and a fourth porous plate ( It is preferably made of a configuration filled in the network structure consisting of 190).

In addition, the third porous plate 180 and the fourth porous plate 190 have a structure in which a plurality of holes are formed in a disc-shaped structure, and it is preferable that the third porous plate 180 and the fourth porous plate 190 have a structure fixed to each other through the cylindrical connector 195. Of course, the cylindrical connecting member 195 may be omitted.

In the drawings, reference numeral 139 denotes a purge valve.

Referring to Figure 9, looking at the gas flow path of the static pressure reducer according to an embodiment of the present invention as described above, the gas discharged from the constant pressure flows into the silencer casing 110 through the inlet pipe 120 The first porous plate 140, the first laminar flow converting unit 150, the second porous plate 160, the flow space 167 inside the sound absorbing cylinder 170, the inlet 131 of the discharge pipe, and the third It is discharged to the gas pipe connected to the discharge pipe through the porous plate 180, the second laminar flow converter 185, the fourth porous plate 190, the outlet 135 of the discharge pipe.

Such a noise reduction device according to the present invention has the effect of reducing the noise generated when the pressure drops while passing through the pressure regulator as much as possible, the operation will be described.

As the gas introduced through the inlet pipe 120 passes through the first porous plate 140, the noise frequency is converted from the high frequency to the low frequency. Thereafter, after the gas is converted from the turbulent flow to the laminar flow while passing through each unit 151 of the first laminar flow converting unit 150, the gas passes through the second porous plate 160 and flows inside the silencer casing 110. It is discharged to the space 167. At this time, while the gas passes through the hole of the second porous plate 160, the noise frequency is converted from the high frequency to the low frequency, thereby reducing the noise.

Gas discharged into the flow space 167 inside the muffler casing 110 is discharged from the flow space 167 to the discharge pipe 130, at this time, the sound absorbing cylinder 170 and the sound insulation space formed on the inner wall of the muffler casing 110 By 177 converting the sound energy by reducing the thermal energy it is possible to further reduce the residual noise generated in the gas flow.

Thereafter, the gas passes through the inside of the discharge pipe 130, passes through the third porous plate 180, the second laminar flow converting unit 185, and the fourth porous plate 190, and is reduced as much as possible to fine noise. Discharged outside).

As a result, the gas flow noise generated by the pressure drop while passing through the pressure regulator is discharged after being maximally reduced while passing through the noise reduction device of the present invention as described above, thereby enabling the configuration of a more quiet gas supply line.

1 and 2 are views showing the silencer disclosed in the registration room 20-397669.

3 is an external perspective view of a static pressure noise reduction device according to an embodiment of the present invention.

Figure 4 is an exploded perspective view showing a static pressure noise reduction device according to an embodiment of the present invention.

5 and 6 are a longitudinal cross-sectional view and a cross-sectional view showing a static pressure noise reduction device according to an embodiment of the present invention.

7 is a perspective view showing a unit of the laminar flow converting unit of the present invention.

8 is a perspective view showing the laminated structure of the laminar flow converter of the present invention.

9 is a view showing a gas flow state of the static pressure reduction device according to an embodiment of the present invention.

Claims (9)

A silencer casing to which an inlet pipe into which gas is introduced is connected to one side; A first porous plate provided at an outlet of the inlet pipe in the silencer casing to allow gas to pass therethrough; A second porous plate connected to the first porous plate and configured to have a predetermined space therein together with the first porous plate; A first laminar flow converter configured to convert the turbulent flow of the gas passing through the first porous plate into a laminar flow formed in an inner space formed of the first and second porous plates; A sound absorbing cylinder positioned to form a gas flow space between the second porous plate and the second porous plate in the silencer casing to absorb noise energy of the gas; And a discharge pipe connected to the outside of the muffler casing from the flow space between the second porous plate and the sound absorbing cylinder on the other side of the muffler casing to discharge gas. The method according to claim 1, The inlet pipe is connected to the expanded structure inside the silencer casing, the static pressure noise reduction device, characterized in that the first porous plate is installed at the outlet of the expanded portion. The method according to claim 1, The first laminar flow converting unit has a structure in which each unit is uniformly stacked and filled in the first and second porous plates, and each unit has the guide ribs cut in the cylindrical structure, respectively, being bent into the cylinder. Noise reduction device, characterized in that formed in the structure. The method according to claim 1, The second porous plate, the one side is supported by the inlet pipe together with the first porous plate, the other is a static pressure noise reduction device, characterized in that supported by the support rod inside the silencer casing. The method according to claim 1, The sound absorbing body is disposed so as to have a sound insulating space between the inner surface of the silencer casing, characterized in that the silencer noise reduction device. The method according to claim 5, The sound absorbing body includes a sound absorbing material, an inner support sheet provided inside the sound absorbing material and formed with a plurality of holes, an outer support sheet protecting the sound absorbing material from the outside of the sound absorbing material, and an inner support sheet and an outer support on the side of the sound absorbing material. Noise reduction device, characterized in that it comprises a side seat for connecting the seat. The method according to claim 6, The side sheet is a noise reduction device, characterized in that the outer diameter is formed larger than the outer diameter formed by the outer support sheet is configured to be supported on the inner surface of the silencer casing. The method according to claim 1, The discharge pipe is a noise reduction device, characterized in that the additional structure is installed inside the noise reduction. The method according to claim 8, The additional structure for reducing the noise of the discharge pipe, the noise reduction device, characterized in that the second laminar flow conversion unit is provided between the third porous plate and the fourth porous plate installed in the transverse direction of the discharge pipe.

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