KR102292054B1 - Multifunctional soundproofing module to produce electricity and heat complex using pvt(photovoltaic thermal) and soundproof wall construction method using the same - Google Patents

Abstract

The present invention is a soundproof panel 210 formed in a plate shape; a solar panel 220 that is disposed to face the front surface of the soundproof panel 210 at a distance and converts sunlight into electricity; and a photovoltaic thermal (PVT) frame 230 coupled to the soundproof panel 210 and the solar panel 220 and having an inlet 232 and an outlet 234; provides
Between the soundproof panel 210 and the solar panel 220 coupled to the PVT frame 230, a flow path communicating with the inlet 232 and the outlet 234 and flowing through the fluid is formed, and through heat exchange in the flow path The heated fluid is characterized in that it is used as a heat source.
Accordingly, the present invention can be used as a heat source by easily absorbing and transferring the heat of the solar panel 220 or the sound insulation panel 210 . Therefore, energy efficiency can be improved and heating cost can be reduced. In addition, the sound insulation performance can be improved.

Description

A multifunctional soundproofing module that produces electricity and heat by using solar power (PVT) and a soundproof wall construction method using the same }

The present invention relates to a multifunctional soundproofing module for composite production of electricity and heat by utilizing solar energy and a soundproof wall construction method to which the same is applied. , A multifunctional soundproof module that absorbs heat from a photovoltaic panel to improve the efficiency of photovoltaic power generation, uses the absorbed heat as a heat source, and at the same time improves soundproofing performance due to fusion technology, and a soundproof wall construction method using the same will be.

A photovoltaic thermal (PVT) system refers to a system that provides electricity through photovoltaic power generation using a photovoltaic panel and absorbs solar heat to provide a heat source.

Specifically, the photovoltaic (PVT) system absorbs the heat of the photovoltaic panel constituting the photovoltaic panel to compensate for the problem of reducing the efficiency of photovoltaic power generation due to the temperature rise, and the absorbed heat can be used as a heat source, so energy efficiency per unit area can improve

Meanwhile, soundproof walls fused with solar panels are being installed around roads or railways to block noise and secure energy. In addition, attempts are being made to improve the power generation efficiency of the solar panel fused to such a sound barrier.

The related prior art is as follows.

Korean Patent Application Laid-Open No. 10-2017-0117751 relates to a soundproof wall having a photovoltaic panel, and in a photovoltaic soundproofing unit made of a box shape with an empty space formed therein, a sound-absorbing plate made of a sound-absorbing material is located on the inner side of the back plate. provided, between the front plate and the sound-absorbing plate, an air flow passage through which air can flow is formed in the vertical direction; In the air flow passage, a heat sensor capable of measuring the temperature is provided at a plurality of positions; The upper plate or the lower plate is provided with a cooling fan that forms a forced air flow in the air flow passage by rotation.

The cooling fan operates when the temperature value measured by the thermal sensor is greater than or equal to a preset reference temperature value, but if the temperature value of the photovoltaic power generation soundproofing unit is not lower than the preset reference temperature value within a preset time, the cooling fan is It is characterized in that the operation intensity is further increased.

However, this prior art is a fusion of a solar panel, not a solar panel, to the sound barrier, and since the heat generated from the solar panel is only emitted to the outside for cooling the solar panel and is not used as a heat source, the conventional solar Soundproof walls with photovoltaic panels do not correspond to solar thermal (PVT) systems.

Therefore, the conventional sound barrier having a solar panel may have low energy efficiency.

In addition, in the prior art, since a plurality of cooling fans are provided and used for each soundproof unit to dissipate the heat of the solar panel, energy consumption can be increased, and a plurality of air outlets are formed for each soundproofing unit to dissipate heat to the outside. Sound insulation performance may be reduced.

The present invention has been devised to solve the above problems, and provides a multifunctional soundproofing module, a multifunctional soundproofing wall and a heating system that can absorb heat from a solar panel or soundproof panel and use it as a heat source and improve soundproofing performance aim to do

In addition, the present invention is to provide a multifunctional soundproof module, a multifunctional soundproof wall and a heating system, in which the fluid flowing inside the multifunctional soundproofing module can effectively absorb and transmit the heat of the solar panel or soundproofing panel at low cost do.

Another object of the present invention is to provide a multifunctional soundproof module and PVT soundproof wall, which can improve durability with a simple configuration.

Another object of the present invention is to provide a soundproof wall construction method to which a multifunctional soundproofing module that can be used as a heat source by absorbing the heat of a solar panel or soundproofing panel is applied.

In order to solve the above problems, the present invention provides a soundproof panel 210 formed in a plate shape; a solar panel 220 that is disposed to face the front surface of the soundproof panel 210 at a distance and converts sunlight into electricity; and a photovoltaic thermal (PVT) frame 230 coupled to the soundproof panel 210 and the solar panel 220 and having an inlet 232 and an outlet 234; provides

Between the soundproof panel 210 and the solar panel 220 coupled to the PVT frame 230, a flow passage communicating with the inlet 232 and the outlet 234 and through which a fluid flows is formed.

The fluid heated through heat exchange in the flow path is used as a heat source.

The PVT frame 230 is provided with the inlet 232 and the outlet 234 on both sides of the PVT frame 230, and the height of the inlet 232 and the outlet 234 corresponds to each other.

In the flow path, the fluid introduced through the inlet 232 circulates between the soundproof panel 210 and the solar panel 220 and is discharged through the outlet 234 .

The PVT frame 230 includes a baffle 236 that blocks between the soundproof panel 210 and the solar panel 220 , and the flow path is formed by the baffle 236 .

The position or angle of the baffle 236 is determined so that the total amount of change in the moving direction of the fluid flowing along the flow path is reduced.

The PVT frame 230 has the inlet 232 and the outlet 234 corresponding to each other in height on both sides of the PVT frame 230, and the baffle 236 includes a first type baffle 236a, a first It is configured to include a transverse baffle (236b) and a second transverse baffle (236c).

The first type baffle 236a has one end connected to any one selected from the upper and lower surfaces of the PVT frame 230, and the other end is open.

The first transverse baffle 236b has one end connected to the vicinity of the other end of the first vertical baffle 236a and the other end open.

One end of the second transverse baffle 236c is connected to the side surface of the PVT frame 230 and the other end is opened while being spaced apart from the first transverse baffle 236b.

The first transverse baffle 236b or the second transverse baffle 236c is inclined upward toward the air flow direction of the lower space of the first transverse baffle 236b or the second transverse baffle 236c.

The baffle 236 has a wing portion 238 protruding in parallel with the soundproof panel 210 or the solar panel 220 at a side end along the longitudinal direction.

The multifunctional soundproofing module 200 further includes; a cover panel 240 disposed to face the rear surface of the soundproofing panel 210 and having a through hole 242, the soundproofing panel 210 or the PVT The frame 230 is coupled to the cover panel 240 .

In addition, in order to solve the above problems, the present invention provides a multifunctional soundproof wall 100 in which any one of the multifunctional soundproofing modules 200 is laminated.

The multi-functional sound insulation wall 100 guides the side ends of each multi-functional sound insulation module 200 from both sides and at least two support frames 300 erected upwards; further comprising, the multi-functional sound insulation module 200 They are sequentially stacked on both sides of the support frame 300 along the support frame 300 .

The support frame 300 is configured to include a through hole 310, and the PVT frame 230 of each multifunctional soundproof module 200 has inlets 232 corresponding to each other in height on both sides of the PVT frame 230. and an outlet 234 , respectively.

The multifunctional soundproof module 200 in which the outlet 234 of the multifunctional soundproof module 200 laminated on one side of the support frame 300 is stacked on the other side of the support frame 300 through the through hole 310 It communicates with the inlet 232 of the.

In addition, the present invention in order to solve the above problems, the multi-functional sound insulation wall 100; a heating demand unit 400 communicating with the outlet 234 of the multifunctional soundproofing module 200 constituting the multifunctional soundproofing wall 100; And, it provides a heating system (10) comprising a; and the multifunctional sound insulation wall (100) and the fluid pressure sending unit (500) in communication with the heating demand unit (400).

In the heating demand unit 400 , the fluid heated through heat exchange in the flow path of the multifunctional soundproof module 200 is discharged.

The fluid pressure sending unit 500 introduces a fluid into the multifunctional soundproof wall 100 and pressurizes it to the heating demand unit 400 .

The fluid pressure sending unit 500 corresponds to a fan, and the fan operates with DC power produced by the solar panel 220 included in the multifunctional soundproof module 200 .

The heating demand unit 400 is a booth or a water tank.

In addition, in order to solve the above-described problem, the present invention includes a manufacturing step (S610) in which the multifunctional soundproof module 200 and the support frame 300 constituting the multifunctional soundproof wall 100 are manufactured; a support frame arrangement step (S620) in which two or more support frames 300 are disposed at regular intervals; and a lamination step (S630) in which the multifunctional soundproof modules 200 are sequentially stacked on both sides of the support frame 300 along the support frame 300; ) is provided.

The multifunctional soundproof module 200 has an inlet 232 and an outlet 234 , and the support frame 300 includes a through hole 310 .

In the lamination step (S630), the outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300, the multifunctional soundproof module 200 stacked on the other side of the support frame 300) The multifunctional soundproofing module 200 is stacked while communicating with the inlet 232 and the through hole 310 of the.

In the manufacturing step (S610), the support frame ( A through hole 310 is formed in 300 .

In the support frame arrangement step (S620), two or more support frames 300 are arranged while matching the height of the through hole 310.

In the support frame arranging step (S620), the support frame 300 is disposed at intervals as much as the width of the multifunctional soundproof module 200 .

According to embodiments of the present invention, in the multifunctional soundproof module 200, the soundproof panel 210 and the photovoltaic panel 220 are disposed to face each other at a distance, and the soundproof panel 210 and the photovoltaic panel 220 are A flow path may be formed in the interspace. Therefore, the heat of the solar panel 220 or the sound insulation panel 210 can be easily transferred to the heating demand unit 400 through the fluid flowing along the flow path, and the sound insulation performance can be improved.

According to embodiments of the present invention, since the fluid heated in the flow path can be used as a heat source in the heating demand unit 400, the energy efficiency of the multifunctional soundproof module 200 can be improved and the heating cost can be reduced. have. In addition, since it brings a cooling effect of the solar panel 220, the power production efficiency of the solar panel can be further increased.

In addition, since the solar panel 220 also performs the function of a sound insulation type sound barrier for shielding the noise that is not absorbed by the sound insulation panel 210, the sound insulation effect is more reliable.

In addition, the fluid heated in the flow path is not discharged directly into the atmosphere, but moves to the heating demand unit 400 , so noise is prevented from leaking into the atmosphere, so that the soundproofing performance can be improved.

According to embodiments of the present invention, the PVT frame 230 may have an inlet 232 and an outlet 234 on both sides (both sides), respectively, and the height of the inlet 232 and the outlet 234 is formed to correspond to each other. can be Therefore, by simply arranging the multifunctional soundproofing module 200 side by side to the left and right, the flow path inside the plurality of multifunctional soundproofing modules 200 can be easily communicated with each other.

In addition, since the flow passages inside the plurality of multifunctional soundproofing modules 200 are in communication with each other, even if there is no separate flow path outside the multifunctional soundproofing module 200, the fluid is easily and low-costly pressurized near the heating demanding part 400. can do.

In addition, for a plurality of multi-functional soundproofing modules 200 in which the internal flow paths are communicated with each other, only one fluid pressure sending unit 500 can flow the fluid through the entire communicating flow path, so the number of fluid pressure sending units 500 is reduced. It can be minimized to reduce manufacturing and maintenance costs.

According to embodiments of the present invention, the flow path of the multifunctional soundproof module 200 is after the fluid introduced into the multifunctional soundproof module 200 circulates in the space between the soundproof panel 210 and the solar panel 220 . can be expelled. Therefore, since the heat transfer area through which heat exchange is performed can be widened with only the minimum number of flow paths in the multifunctional soundproof module 200 , the fluid can effectively absorb and transmit the heat of the solar panel 220 or the soundproof panel 210 .

In addition, since the fluid can flow to the corresponding minimum number of fluid pressure delivery units 500 for the minimum number of flow paths, the number of fluid pressure delivery units 500 can be minimized to reduce manufacturing and maintenance costs.

According to embodiments of the present invention, the baffle 236 may block between the soundproof panel 210 and the photovoltaic panel 220 so that a fluid can flow in the space between the soundproof panel 210 and the photovoltaic panel 220 . You can decide which euro to have. Therefore, the flow path can be easily and inexpensively formed with a simple configuration.

According to embodiments of the present invention, the position or angle of the baffle 236 may be determined so that the total amount of change in the movement direction of the fluid flowing along the flow path is small. Accordingly, since the pressure loss is reduced and the fluid can be flowed with a small power, heat can be effectively absorbed and transmitted at a low cost.

According to the embodiments of the present invention, when the inlet 232 and the outlet 234 are respectively provided at a height corresponding to both sides of the PVT frame 230, one longitudinal baffle 236a and two transverse baffles ( When the baffle 236 is formed of 236b and 236c, heat can be effectively absorbed and transferred at a low cost.

According to the embodiments of the present invention, when the transverse baffles 236b and 236c are inclined to be inclined upward in the air flow direction of the lower space, heat exchange can be performed more effectively.

According to embodiments of the present invention, the baffle 236 may include a wing portion 238 protruding in parallel with the soundproof panel 210 or the solar panel 220 at the side end along the longitudinal direction. Therefore, the baffle 236 can stably support the soundproof panel 210 or the solar panel 220 to improve the durability of the multifunctional soundproof module 200 with a simple configuration.

According to embodiments of the present invention, by disposing the cover panel 240 on the rear surface of the soundproof panel 210, the soundproof panel 210 can be protected.

According to embodiments of the present invention, since the multifunctional soundproof module 200 can be laminated on both sides of the support frame 300 using the support frame 300, the durability of the multifunctional soundproof wall 100 with a simple configuration can be improved and the multifunctional soundproof wall 100 can be easily extended at low cost.

According to embodiments of the present invention, a through hole 310 is formed in the support frame 300 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 through the through hole 310 . ) and the inlet 232 may be in communication. Therefore, by simply stacking the multifunctional soundproof module 200 on both sides of the support frame 300 , the flow passages inside the plurality of multifunctional soundproof modules 200 can be easily and stably communicated with each other.

According to embodiments of the present invention, the heating system 10 applies pressure to the fluid, and the fluid absorbs the heat of the solar panel 220 or the soundproof panel 210 included in the multifunctional soundproof wall 100 and heats it. It may be transmitted to the demand unit 400 . Therefore, since the heat of the solar panel 220 or the sound insulation panel 210 can be used as a heat source of the heating demand unit 400, it is possible to improve energy efficiency and reduce the heating cost.

According to embodiments of the present invention, since the fluid pressure transmission unit 500 can receive power from the solar panel 220 of the multifunctional soundproof module 200 located nearby, the power loss can be reduced by receiving power from a short distance. It can be reduced and there is no need to install a separate power supply.

According to embodiments of the present invention, when the heating demand unit 400 is a booth or water tank installed on a roadside or a residential complex near the multifunctional soundproof wall 100, the multifunctional soundproof wall 100 is heated inside. Since the fluid is used as a heat source in a short distance, it is possible to improve energy efficiency by minimizing heat energy loss and reduce the fluid pressure transport cost.

According to embodiments of the present invention, the inlet 232 and outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 are mutually The multifunctional soundproof module 200 may be stacked on both sides of the support frame 300 while communicating. Therefore, the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 are prevented from being misaligned to prevent heat loss or pressure loss. Heat can be transferred effectively and at low cost.

According to embodiments of the present invention, a through hole 310 in the support frame 300 according to the height of the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 . can be formed. Accordingly, the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 are prevented from being misaligned in advance to prevent heat loss or Heat can be efficiently transferred at low cost without pressure loss.

According to embodiments of the present invention, two or more support frames 300 may be disposed while matching the height of the through hole 310 . Accordingly, the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 are prevented from being misaligned in advance to prevent heat loss or Heat can be efficiently transferred at low cost without pressure loss.

According to embodiments of the present invention, the support frame 300 may be disposed at intervals as much as the width of the multifunctional soundproof module 200 . Therefore, by preventing an empty space from being formed between the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 , Heat can be efficiently transferred at low cost without heat loss or pressure loss.

In addition to the above-described effects, the specific effects of the present invention will be described together while describing specific details for carrying out the invention below.

1 is a view showing a heating system according to an embodiment of the present invention.
2 to 10 are a perspective view, a semi-perspective view, an exploded perspective view, a front view, a right side view, a left side view, a rear view, a top view and a bottom view of a multifunctional soundproof module according to an embodiment of the present invention.
11 to 13 are perspective views illustrating a baffle of a PVT frame according to an embodiment of the present invention.
14 is a table showing the pressure loss and temperature difference for various baffle types.
15 is a perspective view illustrating an embodiment in which a wing portion is provided on the baffle of FIG. 11 .
16 is a perspective view showing an embodiment in which a cover part is provided on the PVT frame of FIG. 15, FIG. 17 is a plan view of the PVT frame of FIG. 16, and FIG. 18 is a soundproof panel, a solar panel and a cover panel in the PVT frame of FIG. It is a cross-sectional view showing the combined state.
19 is a perspective view showing a multifunctional soundproof wall according to an embodiment of the present invention, and Figure 20 is a side view showing a support frame according to an embodiment of the present invention.
21 is a flowchart illustrating a method of constructing a soundproof wall to which a multifunctional soundproofing module is applied according to an embodiment of the present invention.

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

The present invention is not limited to the embodiments disclosed below, but can be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete and to completely convey the scope of the invention to those of ordinary skill in the art. It is provided to inform you. Therefore, the present invention is not limited to the embodiments disclosed below, and all changes and equivalents included in the technical spirit and scope of the present invention as well as substituting or adding the configuration of any one embodiment and the configuration of other embodiments to each other It should be understood to include water or substitutes.

The accompanying drawings are only for easy understanding of the embodiments disclosed in the present specification, and the technical spirit disclosed in the present specification is not limited by the accompanying drawings, and all changes and equivalents included in the spirit and scope of the present invention It should be understood to include water or substitutes. In the drawings, in consideration of the convenience of understanding, the size or thickness may be exaggeratedly large or small, but the protection scope of the present invention should not be construed as being limited thereto.

The terms used herein are used only to describe specific embodiments or examples, and are not intended to limit the present invention. And singular expressions include plural expressions unless the context clearly dictates otherwise. In the specification, terms such as includes, consists of, etc. are intended to designate that the features, numbers, steps, operations, components, parts, or combinations thereof described in the specification exist. That is, in the specification, terms such as include and consist of. It should be understood that this does not preclude the possibility of addition or existence of one or more other features or numbers, steps, operations, components, parts, or combinations thereof.

Terms including an ordinal number, such as first, second, etc., may be used to describe various elements, but the elements are not limited by the terms. The above terms are used only for the purpose of distinguishing one component from another.

When a component is referred to as being “connected” or “connected” to another component, it is understood that the other component may be directly connected or connected to the other component, but other components may exist in between. it should be On the other hand, when it is mentioned that a certain element is "directly connected" or "directly connected" to another element, it should be understood that the other element does not exist in the middle.

When an element is referred to as being "on" or "below" another element, it should be understood that other elements may be present in the middle as well as disposed directly on the other element. .

Unless defined otherwise, all terms used herein, including technical and scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in commonly used dictionaries should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

In describing the embodiment, the longitudinal direction may refer to a direction in which the elongated member is extended when there is an elongated member.

1 is a view showing a heating system according to an embodiment of the present invention.

Referring to FIG. 1 , a heating system 10 according to an embodiment is configured to include a multifunctional soundproof wall 100 , a heating demand unit 400 , and a fluid pressure transmission unit 500 .

Here, photovoltaic thermal (PVT) may refer to a mechanism of a photovoltaic system that provides electricity by photovoltaic power generation and at the same time absorbs solar heat to provide a heat source.

Specifically, the PVT (photovoltaic) system absorbs the heat of the solar panel to compensate for the problem of reduction in the efficiency of photovoltaic power generation due to the increase in temperature, and the absorbed heat can be used as a heat source, thereby improving the energy efficiency per unit area. .

Also, here, the multifunctional soundproof wall 100 may mean a soundproof wall that can generate photovoltaic power with a photovoltaic panel and provide a heat source by absorbing the heat of the photovoltaic panel.

[Multifunctional soundproof wall]

The multifunctional soundproof wall 100 is configured to include one or more multifunctional soundproof modules 200 and a support frame 300 stacked. The multifunctional soundproof module 200 and the support frame 300 will be described later with reference to FIGS. 2 to 20 .

In addition, the multifunctional soundproof wall 100 may be in communication with the heating demand 400 and the fluid pressure transmission unit 500 through a flow path such as a tube or tube.

The fluid heated through heat exchange with the solar panel 220 or the soundproof panel 210 in the flow path inside the plurality of multifunctional soundproof modules 200 included in the multifunctional soundproof wall 100 is supplied to the heating demand unit 400. can be emitted. Here, the flow path inside the multifunctional soundproof module 200, the solar panel 220, and the soundproof panel 230 will be described later.

[Heating Demand Department]

The heating demand unit 400 may communicate with the outlet 234 of the multifunctional soundproof module 200 to be described later or the through hole 310 of the support frame 300 to be described later. In addition, the heating demand unit 400 may be in communication with the fluid pressure transmission unit (500).

In the heating demand unit 400, the heated fluid is discharged through heat exchange with the solar panel 220 or the soundproof panel 210 from the flow path inside the multifunctional soundproof module 200 constituting the multifunctional soundproof wall 100, The temperature of the heating demand unit 400 may be increased. The flow path inside the multifunctional soundproof module 200 will be described later.

For example, when the heating demand unit 400 is a booth, a high-temperature fluid is discharged to the booth, so that the air temperature inside the booth may increase. In addition, when the heating demand unit 400 is a water tank, a high-temperature fluid is discharged to the water tank, so that the temperature of the water stored in the water tank may increase. However, the heating demand unit 400 is not limited to this configuration.

[Fluid pressure sending unit]

The fluid pressure sending unit 500 may communicate with the outlet 234 of the multifunctional soundproof module 200 to be described later or the through hole 310 of the support frame 300 to be described later. In addition, the fluid pressure sending unit 500 may communicate with the heating demand unit 400 .

The fluid pressure sending unit 500 may introduce a fluid into the multifunctional soundproof module 200 constituting the multifunctional soundproof wall 100 through an inlet 232 to be described later by applying pressure to the fluid.

In addition, the fluid pressure sending unit 500 can apply pressure to the fluid so that the fluid introduced into the multifunctional soundproof module 200 flows along the flow path provided in the multifunctional soundproof module 200, and the multifunctional soundproof module 200 ) can be discharged through the outlet (234). Here, the flow path and the outlet 234 inside the multifunctional soundproof module 200 will be described later.

In addition, the fluid pressure sending unit 500 may pressurize the fluid discharged from the multifunctional soundproof module 200 to the heating demand unit 400 by applying pressure to the fluid.

Here, the fluid pressure sending unit 500 may correspond to a fan, and the fluid may correspond to air. In addition, the fluid pressure transmission unit 500 may be operated with DC power (direct current power) produced by the solar panel 220 to be described later.

In this way, the heating system 10 applies pressure to the fluid to absorb the heat of the solar panel 220 or the soundproof panel 210 included in the multifunctional soundproof wall 100 and the fluid to the heating demand unit 400. can be conveyed

Therefore, since the heat of the solar panel 220 or the sound insulation panel 210 can be used as a heat source of the heating demand unit 400, it is possible to improve energy efficiency and reduce the heating cost.

In addition, the fluid heated in the flow path is not discharged directly into the atmosphere, but moves to the heating demand unit 400 , so noise is prevented from leaking into the atmosphere, so that the soundproofing performance can be improved.

In addition, since the fluid pressure transmission unit 500 can receive power from the solar panel 220 of the multifunctional soundproof module 200 located nearby, it is possible to reduce power loss by supplying power at a short distance, and a separate power source No need to install a feeder.

In addition, when the heating demand unit 400 is a booth or water tank installed in a roadside or residential complex near the multifunctional soundproof wall 100, the fluid heated inside the multifunctional soundproof wall 100 is used as a heat source in a short distance. By minimizing thermal energy loss, energy efficiency can be improved and fluid pressure transportation costs can be reduced.

2 to 10 are a perspective view, a semi-perspective view, an exploded perspective view, a front view, a right side view, a left side view, a rear view, a top view and a bottom view of a multifunctional soundproof module according to an embodiment of the present invention.

2 to 4 , the multifunctional soundproof module 200 according to an embodiment is configured to include a soundproof panel 210 , a solar panel 220 , a PVT frame 230 and a cover panel 240 . do.

Meanwhile, in the description of the soundproof panel 210 and the like, the front side may mean a surface positioned in the front direction of FIG. 3 and the rear surface may mean a surface positioned in the rear direction of FIG. 3 . Also, the front may refer to the front direction of FIG. 3 , and the rear may refer to the rear direction of FIG. 3 .

[Soundproof panel]

The sound insulation panel 210 may be formed in a plate shape and may be coupled to the PVT frame 230 . For example, the soundproof panel 210 may be inserted into the inside of the PVT frame 230 as shown in FIG. 3 and coupled with at least one of the upper surface, the lower surface, or both sides of the PVT frame 230 .

In addition, the soundproof panel 210 may be combined with the front surface of the cover panel 240 .

In addition, the sound insulation panel 210 may be disposed to face the rear surface of the solar panel 220 at a distance.

The soundproof panel 210 may be made of a sound-absorbing material and may reduce noise by absorbing sound. At this time, sound waves are converted into thermal energy, so that the sound insulation panel 210 may generate heat.

In addition, the sound insulation panel 210 may function as a heat insulating material that prevents heat generated from the sound insulation panel 210 or the solar panel 220 from escaping to the outside through the sound insulation panel 210 .

[Solar Panel]

The solar panel 220 may be formed in a plate shape and may be coupled to the PVT frame 230 . For example, the edge or rim of the back side of the solar panel 220 may be coupled to the PVT frame 230 as shown in FIG. 2 .

In addition, the solar panel 220 may be disposed to face the front surface of the soundproof panel 210 at an interval.

The solar panel 220 may include one or more solar cell modules 222 and convert sunlight into electricity through the solar cell module 222 .

In addition, the solar panel 220 may function as a sound insulating material.

[PVT Frame]

The PVT frame 230 may correspond to a tubular form penetrated back and forth and may be combined with the soundproof panel 210 , the solar panel 220 and the cover panel 240 .

For example, the PVT frame 230 may be coupled with the edge of the rear side of the solar panel 220 forward, as shown in FIGS. 2 and 3, and may be coupled with the edge of the front side of the cover panel 240 backward. have. In addition, the PVT frame 230 may be coupled to one or more surfaces of the upper surface, lower surface, and both sides of the soundproof panel 210 and the inside.

In addition, the PVT frame 230 may have an inlet 232 and an outlet 234 . For example, the PVT frame 230 may have an inlet 232 and an outlet 234 on both sides (both sides), respectively, as shown in FIGS. 2 to 4 . At this time, the height of the inlet 232 and the outlet 234 may be formed to correspond to each other.

Between the soundproof panel 210 and the solar panel 220 coupled to the PVT frame 230, a flow path communicating with the inlet 232 and the outlet 234 and through which the fluid flows may be formed.

Here, in the flow path, the fluid introduced through the inlet 232 circulates in the space between the soundproof panel 210 and the photovoltaic panel 220 to absorb the heat of the soundproof panel 210 or the photovoltaic panel 220 and It may be discharged through the outlet 234 .

Here, the circulation may mean that the fluid introduced from the inlet 232 is not discharged directly to the outlet 234 , but moves around various spaces between the soundproof panel 210 and the solar panel 220 . As the fluid circulates, the heat transfer area for heat exchange may be increased.

In addition, the flow path may be formed through a baffle (baffle, 236) provided in the PVT frame (230). In this regard, look at FIGS. 11 to 14 .

Meanwhile, the fluid heated through heat exchange in the flow path may be used as a heat source in the heating demand unit 400 described above.

In this way, in the multifunctional soundproof module 200, the soundproof panel 210 and the solar panel 220 are disposed to face each other at a distance, and a flow path is formed in the space between the soundproof panel 210 and the solar panel 220. can be

Therefore, the heat of the solar panel 220 or the sound insulation panel 210 can be easily transferred to the heating demand unit 400 through the fluid, and the sound insulation performance can be improved.

In addition, since the fluid heated in the flow path can be used as a heat source in the heating demand unit 400 , the energy efficiency of the multifunctional soundproof module 200 can be improved and the heating cost can be reduced.

In addition, the PVT frame 230 may have an inlet 232 and an outlet 234 on both sides (both sides), respectively, and the height of the inlet 232 and the outlet 234 may be formed to correspond to each other. For example, as shown in the figure, the inlet 232 and the outlet 234 may be formed on both sides of the PVT frame 230 .

Therefore, by simply arranging the multifunctional soundproofing module 200 side by side to the left and right, the flow path inside the plurality of multifunctional soundproofing modules 200 can be easily communicated with each other.

In addition, since the flow passages inside the plurality of multifunctional soundproofing modules 200 are in communication with each other, even if there is no separate flow path outside the multifunctional soundproofing module 200, the fluid is easily and low-costly pressurized near the heating demanding part 400. can do.

In addition, for a plurality of multi-functional soundproofing modules 200 in which the internal flow paths are communicated with each other, only one fluid pressure sending unit 500 can flow the fluid through the entire communicating flow path, so the number of fluid pressure sending units 500 is reduced. It can be minimized to reduce manufacturing and maintenance costs.

In addition, the flow path of the multifunctional soundproof module 200 may be discharged after the fluid introduced into the multifunctional soundproof module 200 circulates in the space between the soundproof panel 210 and the solar panel 220 .

Therefore, in the multifunctional soundproof module 200, the heat transfer area through which heat exchange is made can be widened with only the minimum number (eg, one) of flow paths, so that the fluid effectively absorbs the heat of the solar panel 220 or the soundproof panel 210 and can be delivered.

In addition, since it is possible to flow the fluid to the minimum number (eg, one) of the fluid pressure-sending unit 500 for the minimum number (eg, one) of the flow path, it is possible to manufacture and Maintenance costs can be reduced.

[Cover Panel]

The cover panel 240 may be disposed to face the rear surface of the soundproof panel 210 and may be combined with the soundproof panel 210 or the PVT frame 230 . In addition, the cover panel 240 may include one or more through-holes 242 .

In this way, by disposing the cover panel 240 on the rear surface of the soundproof panel 210, the soundproof panel 210 can be protected.

5 to 10 , the multifunctional soundproof module 200 according to an embodiment is a solar panel 220 on the front side as shown in the front view of FIG. 5 , and a cover panel 240 on the rear side as in the rear view of FIG. ), the right side / left side view of Figs. 6 / 7 and the top view / bottom view of Figs. 9 / 10, both sides and upper and lower surfaces may correspond to a combination mainly composed of the PVT frame 230.

On the other hand, the soundproof panel 210 may be inserted into the multifunctional soundproofing module 200 and not exposed to the outside, as described above.

[baffler]

11 to 13 are perspective views illustrating a baffle of a PVT frame according to an embodiment of the present invention.

11 to 13 , the PVT frame 230 according to an embodiment may include a baffle 236 . The baffle 236 may have a thin plate shape as shown in FIGS. 11 to 13 , but is not limited thereto.

In addition, a flow path like the dotted line of FIGS. 11 to 13 may be formed by the baffle 236 .

Specifically, when the soundproof panel 210 and the solar panel 220 are coupled to the PVT frame 230 as shown in FIG. 3 , the baffle 236 is a space between the soundproof panel 210 and the solar panel 220 . It may be disposed on and both ends of the longitudinal direction of the baffle 236 may be in contact with the front surface of the soundproof panel 210 and the rear surface of the solar panel 220 .

Therefore, since the baffle 236 can block between the soundproof panel 210 and the solar panel 220 , it is possible to determine the flow path through which the fluid can flow in the space between the soundproof panel 210 and the solar panel 220 . have. That is, the baffle 236 may form a flow path like the dotted line of FIGS. 11 to 13 .

The configuration of the baffle 236 will be described in detail in FIGS. 11 to 13 .

In FIG. 11 , the baffle 236 is composed of five longitudinal baffles (hereinafter, referred to as longitudinal baffles), of which three longitudinal baffles have one end connected to the upper surface of the PVT frame 230 and the other end open. The other two longitudinal baffles have one end connected to the lower surface of the PVT frame 230 and the other end open.

By the configuration of the baffle 236, the fluid has six longitudinal paths (three descending paths and three ascending paths) in which the moving direction is greatly changed.

In FIG. 12 , the baffle 236 has a first-type baffle 236a having one end connected to the upper surface of the PVT frame 230 and the other end open, and one end connected to the vicinity of the other end of the first-type baffle 236a. Including a first transverse baffle 236b having the other end open and a second transverse baffle 236c having one end connected to the side surface of the PVT frame 230 and having the other end spaced apart from the first transverse baffle 236b and opened is composed At this time, as shown in FIG. 12 , the first vertical baffle 236a is disposed closer to the side provided with the inlet 232 among both sides of the PVT frame 230 , and the first transverse baffle 236b and the second transverse baffle ( 236c) may be disposed only between the side where the outlet 234 is provided and the first type baffle 236a among both sides of the PVT frame 230 . That is, as shown in FIG. 12 , the transverse baffle 236 may not be disposed between the first vertical baffle 236a and the side provided with the inlet 232 among both sides of the PVT frame 230 .

Due to the configuration of the baffle 236, the fluid has one vertical path (downward path) and three horizontal paths (two right paths and one left path) in which the moving direction is greatly changed.

13, the first transverse baffle 236b and the second transverse baffle 236c among the baffles 236 of FIG. It is configured to be inclined upward toward the direction (air movement direction).

By the configuration of the baffle 236, the fluid moves in one vertical path (downward path), two inclined paths (one right ascending path and one left ascending path) and one horizontal path (right path) in which the direction of movement changes greatly. ) has

14 is a table showing the pressure loss and temperature difference for various baffle types.

Referring to FIG. 14 , a path, a baffle shape, a pressure loss, and a temperature difference between an inlet and an outlet can be found for types 1 to 5. 11, 12, and 13 described above correspond to Type 2, Type 4-1, and Type 5, respectively.

Here, the pressure loss is also referred to as differential pressure, and may mean energy of the fluid lost due to a change in the velocity, direction, etc. of the fluid flowing through the flow path. As the pressure loss increases, the energy efficiency may be low because a large power is required to flow the fluid.

Therefore, in principle, when the position or angle of the baffle 236 is determined so that the total amount of change in the movement direction of the fluid flowing along the flow path is small, the pressure loss is small and the fluid can be flowed with a small power, so that the energy efficiency is increased. can That is, when the position or angle of the baffle 236 is determined so that the total amount of change in the movement direction of the fluid flowing along the flow path is determined, heat can be effectively absorbed and transmitted at low cost.

On the other hand, all types of Figure 14 are provided with the inlet 232 and the outlet 234 on both sides of the PVT frame 230, respectively, the height of the inlet 232 and the outlet 234 is assumed to be formed to correspond to each other.

Types 1 to 3, unlike Types 4-1 to 5, have only a longitudinal path because the baffle shape is composed of only longitudinal baffles. more than twice as large

Therefore, when the inlet 232 and the outlet 234 are provided with heights corresponding to both sides of the PVT frame 230, respectively, configuring the baffle 236 only as a longitudinal baffle like Type 1 to Type 3 is a pressure loss This cursor may be more inappropriate than Type 4-1 to Type 5.

On the other hand, in Type 1 to Type 3, it can be seen that as the number of longitudinal baffles increases (that is, as the number of vertical paths increases), the pressure loss increases, but the temperature difference between the inlet 232 and the outlet 234 also increases.

Here, the temperature difference between the inlet 232 and the outlet 234 may mean thermal energy absorbed by the fluid from the soundproof panel 210 or the solar panel 220 .

Specifically, in Type 1 to Type 3, as the number of longitudinal baffles increases, the number of turns of the fluid increases, so that the pressure loss may increase. Accordingly, as the number of longitudinal baffles increases, a large power is required to flow the fluid, and thus energy efficiency may be lowered.

However, as the number of longitudinal baffles increases, the heat transfer area through which the fluid comes into contact with the soundproof panel 210 and the solar panel 220 and heats up substantially increases, so that the fluid absorbs more heat, so that the inlet 232 and the outlet The temperature difference of 234 may be large. Therefore, the fluid absorbs more heat from the solar panel, so that the power generation efficiency can be improved, and the high-temperature fluid can be used as a heat source, so that the energy efficiency can be increased.

However, when the number of longitudinal baffles is increased in Types 1 to 3, since the pressure loss is larger than the temperature difference, the overall energy efficiency may decrease as the number of longitudinal baffles increases.

In summary, when the inlet 232 and the outlet 234 are provided at a height corresponding to both sides of the PVT frame 230, respectively, configuring the baffle 236 only as a longitudinal baffle like Type 1 to Type 3 is the whole It may be inappropriate due to low energy efficiency.

Types 4-1 to 5, unlike Types 1 to 3, have a transverse path because the baffle shape includes a transverse baffle. It may be less than half.

On the other hand, the temperature difference in Type 4-1 to Type 5 is similar to Type 1 and Type 2.

Here, the similar temperature difference may mean that the heat transfer area in which the fluid is in contact with the sound insulation panel 210 and the solar panel 220 and heat exchange is substantially similar.

Therefore, when the inlet 232 and the outlet 234 are provided with a height corresponding to both sides of the PVT frame 230, respectively, configuring the baffle 236 as in Type 4-1 to Type 5 requires a small power. It can absorb heat effectively.

That is, when the baffle 236 is configured in the form of types 4-1 to 5, (i) at low cost (with small power), the solar panel is effectively cooled to improve the solar power generation efficiency, and (ii) at low cost Since a high-temperature heat source can be used (with small power), the overall energy efficiency can be improved.

In addition, since it is simple and easy to configure the baffle 236 in the type 4-1 to type 5 shape, it can be manufactured at a lower cost than when the flow path is formed by other methods.

On the other hand, the type 5 (FIG. 13) is configured to be inclined so that the transverse baffles 236b and 236c of the type 4-1 (FIG. 12) go upward in the air flow direction of the lower space, as described above.

With this configuration, in Type 5, high-temperature air can be easily discharged along the inclined transverse baffle, so that heat exchange is effectively made, so that the temperature difference between the inlet 232 and the outlet 234 is greater than that of Type 4-1 or Type 4-2. can grow

[Wings]

15 is a perspective view illustrating an embodiment in which a wing portion is provided on the baffle of FIG. 11 .

Referring to FIG. 15 , the baffle 236 may include a wing portion 238 .

Specifically, the baffle 236 may include a wing portion 238 protruding in parallel with the soundproof panel 210 or the solar panel 220 at the side end along the longitudinal direction.

In this way, by having the baffle 236 with the wing portion 238, when the soundproof panel 210 and the solar panel 220 are coupled to the PVT frame 230 as shown in FIG. 3, the baffle 236 is soundproofed. By stably supporting the panel 210 or the solar panel 220, it is possible to improve the durability of the multifunctional soundproof module 200 with a simple configuration.

[Cover part]

16 is a perspective view showing an embodiment in which a cover part is provided in the PVT frame of FIG. 15, FIG. 17 is a plan view of the PVT frame of FIG. 16, and FIG. 18 is a soundproof panel, a solar panel and a cover panel in the PVT frame of FIG. It is a cross-sectional view showing the combined state.

16 to 18 , the PVT frame 230 may include a cover part 239 .

Specifically, the side end of the PVT frame 230 may be provided with cover portions (239a, 239b) surrounding the side end of the solar panel 220 or the cover panel 240.

In this way, when the PVT frame 230 is provided with the cover part 239, the soundproof panel 210, the solar panel 220, and the cover panel 240 are coupled to the PVT frame 230 as shown in FIG. , PVT frame 230 is to improve the durability of the multifunctional soundproof module 200 with a simple configuration by stably supporting each panel (210, 220, 240) disposed between the cover portion 239 and the baffle 238. can

[Support frame]

19 is a perspective view showing a multifunctional soundproof wall according to an embodiment of the present invention, and Figure 20 is a side view showing a support frame according to an embodiment of the present invention.

19 and 20, the multifunctional soundproof wall 100 according to an embodiment is configured to include a plurality of stacked multifunctional soundproof modules 200 and a support frame 300, and the support frame 300 is A through hole 310 may be provided. However, it is not limited to this configuration, and the multifunctional soundproof wall 100 may be composed of, for example, only a plurality of stacked multifunctional soundproofing modules 200 .

Since the multifunctional soundproof module 200 is as described in FIGS. 2 to 18 , only the support frame 300 will be looked at.

The support frame 300 guides the side ends of each multifunctional soundproof module 200 from both sides and can be erected upward. For example, the support frame 300 may correspond to an H-shaped steel, as shown in FIG. 19 .

When two or more support frames 300 are erected, the multifunctional soundproof modules 200 may be sequentially stacked on both sides of the support frame 300 along the support frame 300 .

In addition, the support frame 300 may be configured to include a through hole (310).

The through hole 310 of the support frame 300 is the outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300 and the multifunctional soundproof module stacked on the other side of the support frame 300 ( The inlet 232 of 200 may be communicated.

Specifically, the PVT frame 230 of each multifunctional soundproofing module 200 has an inlet 232 and an outlet 234 on both sides of the PVT frame 230, respectively, and the inlet 232 and the outlet 234. The heights of may correspond to each other. In addition, the through hole 310 of the support frame 300 may be formed to match the height of the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 . In addition, when the multifunctional soundproof module 200 is laminated on both sides of the support frame 300 , the side of the PVT frame 230 of the multifunctional soundproof module 200 is the side where the through hole 310 of the support frame 300 is formed. can be contacted with

At this time, when the multifunctional soundproof module 200 is laminated on both sides of the support frame 300 along the support frame 300, the exhaust port ( 234 ) and the inlet 232 may communicate through the through hole 310 . For example, the outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300 and the inlet 232 of the multifunctional soundproof module 200 stacked on the other side of the support frame 300 are It may communicate directly with the same through-hole 310 .

In this way, since the multifunctional soundproof module 200 can be laminated on both sides of the support frame 300 by using the support frame 300, the durability of the multifunctional soundproof wall 100 can be improved with a simple configuration, and The functional sound insulation wall 100 can be easily extended at low cost.

In addition, the through hole 310 is formed in the support frame 300 and the outlet 234 and the inlet 232 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 through the through hole 310 are formed. can communicate.

Therefore, by simply stacking the multifunctional soundproof module 200 on both sides of the support frame 300 , the flow passages inside the plurality of multifunctional soundproof modules 200 can be easily and stably communicated with each other.

21 is a flowchart illustrating a method of constructing a soundproof wall to which a multifunctional soundproofing module is applied according to an embodiment of the present invention.

Referring to FIG. 21 , the soundproof wall construction method 600 to which the multifunctional soundproofing module is applied according to an embodiment may include a manufacturing step (S610), a support frame arrangement step (S620) and a lamination step (S630). have.

In the manufacturing step (S610), the multifunctional soundproof module 200 and the support frame 300 constituting the multifunctional soundproof wall 100 may be manufactured.

Here, the PVT frame 230 of the multifunctional soundproof module 200 may be manufactured to have an inlet 232 and an outlet 234 , and the support frame 300 may be configured to include a through hole 310 . have.

In addition, the PVT frame 230 of the multifunctional soundproof module 200 has an inlet 232 and an outlet 234 on both sides of the PVT frame 230, respectively, and the height of the inlet 232 and the outlet 234 is each other. It can be made to match.

In addition, the through hole 310 in the support frame 300 according to the height of the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 in the lamination step (S630) to be described later. ) can be formed.

In this way, the through-holes 310 are formed in the support frame 300 according to the heights of the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 , so that the support frame (300) The inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides and the through hole 310 of the support frame 300 are prevented from being misaligned in advance to prevent heat loss or pressure loss. can be delivered effectively at low cost.

In the supporting frame arrangement step ( S620 ), two or more supporting frames 300 may be arranged at regular intervals.

At this time, two or more support frames 300 may be disposed while matching the height of the through hole 310 .

In this way, two or more support frames 300 are arranged while matching the height of the through-holes 310, so that the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and By preventing the through-hole 310 of the support frame 300 from being misaligned in advance, heat can be effectively transferred at low cost without heat loss or pressure loss.

In addition, the support frame 300 may be disposed at intervals as much as the width of the multifunctional soundproof module 200 . Accordingly, when the multifunctional soundproof module 200 is laminated on both sides of the support frame 300 , the side of the PVT frame 230 of the multifunctional soundproof module 200 is the side where the through hole 310 of the support frame 300 is formed. can be contacted with

In this way, by disposing the support frame 300 at intervals as much as the width of the multifunctional soundproof module 200, the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 ) and the through hole 310 of the support frame 300 to prevent an empty space from being formed, so that heat can be effectively transferred at a low cost without heat loss or pressure loss.

In the lamination step (S630), the outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300, the inlet of the multifunctional soundproof module 200 stacked on the other side of the support frame 300 ( 232) and the through-hole 310 of the support frame 300, the multifunctional soundproof module 200 may be stacked while communicating with each other.

In this way, while the inlet 232 and outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole 310 of the support frame 300 communicate with each other, the support frame 300 ) By stacking the multifunctional soundproof module 200 on both sides, the inlet 232 and outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300 and the through hole of the support frame 300 ( 310), it is possible to effectively transfer heat at low cost without heat loss or pressure loss.

As described above, the present invention has been described with reference to the illustrated drawings, but the present invention is not limited by the embodiments and drawings disclosed in the present specification. It is obvious that variations can be made.

In addition, although the effects of the configuration of the present invention are not explicitly described and described while describing the embodiments of the present invention, it is natural that the effects predictable by the configuration should also be recognized.

10: heating system
100: multifunctional sound insulation wall
200: multifunctional soundproof module
210: soundproof panel 220: solar panel
230: PVT frame
232: inlet 234: outlet
236: baffle 238: wing
239: cover part
240: cover panel
300: support frame 310: through hole
400: heating demand unit 500: fluid pressure transmission unit
600: Soundproof wall construction method applying a multifunctional soundproofing module

Claims (20)

Soundproof panel 210 formed in a plate shape;
a solar panel 220 that is disposed to face the front surface of the soundproof panel 210 at a distance and converts sunlight into electricity; and
and a photovoltaic thermal (PVT) frame 230 coupled to the soundproof panel 210 and the solar panel 220 and having an inlet 232 and an outlet 234 on both sides of the upper portion;
Between the soundproof panel 210 and the solar panel 220 coupled to the PVT frame 230, a flow path communicating with the inlet 232 and the outlet 234 and flowing the fluid is formed,
The fluid heated through heat exchange in the flow path is used as a heat source,
The height of the inlet 232 and the outlet 234 corresponds to each other,
The PVT frame 230 is provided with a baffle (baffle, 236) that blocks between the soundproof panel 210 and the solar panel 220,
The flow path is formed by the baffle (236),
The baffle 236 is
a first type baffle 236a having one end connected to the upper surface of the PVT frame 230 and having the other end open;
a first transverse baffle (236b) having one end connected to the vicinity of the other end of the first vertical baffle (236a) and having the other end open; and
A second transverse baffle (236c) having one end connected to the side surface of the PVT frame (230) and the other end being spaced apart from the first transverse baffle (236b) and opened;
The first type baffle 236a is disposed closer to the side provided with the inlet 232 among both sides of the PVT frame 230,
The first transverse baffle 236b and the second transverse baffle 236c are disposed only between the side having the outlet 234 and the first longitudinal baffle 236a among both sides of the PVT frame 230. A multi-functional soundproofing module (200).
The method according to claim 1,
The first transverse baffle (236b) or the second transverse baffle (236c) is characterized in that it is inclined upward toward the air flow direction of the lower space of the first transverse baffle (236b) or the second transverse baffle (236c). Functional sound insulation module (200).
The method according to claim 1,
The baffle 236 is a multifunctional soundproof module 200, characterized in that it has a wing portion 238 protruding in parallel with the soundproof panel 210 or solar panel 220 at the side end along the longitudinal direction.
The method according to claim 1,
It further includes; a cover panel 240 disposed to face the rear surface of the soundproof panel 210 and having a through hole 242;
The sound insulation panel (210) or the PVT frame (230) is a multifunctional sound insulation module (200), characterized in that combined with the cover panel (240).
As a multifunctional soundproof wall 100 laminated with a multifunctional soundproof module 200,
The multifunctional soundproof module 200,
Soundproof panel 210 formed in a plate shape;
a solar panel 220 that is disposed to face the front surface of the soundproof panel 210 at a distance and converts sunlight into electricity; and
and a photovoltaic thermal (PVT) frame 230 coupled to the soundproof panel 210 and the solar panel 220 and having an inlet 232 and an outlet 234;
Between the soundproof panel 210 and the solar panel 220 coupled to the PVT frame 230, a flow path communicating with the inlet 232 and the outlet 234 and flowing the fluid is formed,
The fluid heated through heat exchange in the flow path is used as a heat source,
The multifunctional soundproof wall 100,
It further includes; guide the side ends of the multi-functional soundproof module 200 from both sides and at least two support frames 300 erected upwards;
The multifunctional soundproof module 200 is sequentially stacked on both sides of the support frame 300 along the support frame 300,
The PVT frame 230 of each multifunctional soundproof module 200 has an inlet 232 and an outlet 234 on both sides of the PVT frame 230, respectively, and the height of the inlet 232 and the outlet 234 is respond to each other,
The support frame 300 is configured to include a through hole 310,
The through hole 310 is formed to match the height of the inlet 232 and the outlet 234 of the multifunctional soundproof module 200 stacked on both sides of the support frame 300,
When the multifunctional soundproof module 200 is stacked on the support frame 300 , the side of the PVT frame 230 of the stacked multifunctional soundproof module 200 is formed with the through hole 310 of the support frame 300 . in contact with the face,
The outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300 and the inlet 232 of the multifunctional soundproof module 200 stacked on the other side of the support frame 300 are the same Multifunctional soundproof wall (100), characterized in that it communicates directly with the through hole (310).
The multifunctional sound insulation wall 100 of claim 5;
A heating demand part communicating with the outlet 234 of the multifunctional soundproofing module 200 constituting the multifunctional soundproofing wall 100 and discharging the heated fluid through heat exchange in the flow path of the multifunctional soundproofing module 200 ( 400); and,
The multifunctional sound insulation wall 100 and the heating demand unit 400 communicates with the fluid to flow into the multifunctional sound insulation wall 100 and the fluid pressure transfer unit 500 for pressurizing the heating demand unit 400; A heating system (10) comprising.
7. The method of claim 6,
The fluid pressure sending unit 500 corresponds to a fan,
The fan is a heating system (10), characterized in that it operates with DC power produced by the solar panel (220) included in the multifunctional soundproof module (200).
7. The method of claim 6,
The heating demand unit 400 is a heating system (10), characterized in that the booth (booth) or water tank.
As a construction method of the multifunctional soundproof wall of claim 5,
A manufacturing step (S610) in which the multifunctional soundproof module 200 and the support frame 300 constituting the multifunctional soundproof wall 100 are manufactured;
The multifunctional soundproof module 200 has an inlet 232 and an outlet 234,
The support frame 300 is configured to include a through hole 310,
a support frame arrangement step (S620) in which two or more support frames 300 are disposed at regular intervals;
A lamination step (S630) in which the multifunctional soundproofing modules 200 are sequentially stacked on both sides of the support frame 300 along the support frame 300;
In the lamination step (S630), the outlet 234 of the multifunctional soundproof module 200 stacked on one side of the support frame 300, the multifunctional soundproof module 200 stacked on the other side of the support frame 300. Soundproof wall construction method (600) to which the multifunctional soundproofing module is applied, characterized in that the multifunctional soundproofing module (200) is laminated while the inlet (232) and the through hole (310) communicate with each other.
10. The method of claim 9,
In the manufacturing step (S610), the support frame ( A through hole 310 is formed in 300),
In the support frame arrangement step (S620), two or more support frames 300 are arranged while matching the height of the through hole 310,
In the support frame arrangement step (S620), a soundproof wall construction method to which a multifunctional soundproof module is applied, characterized in that the support frame 300 is disposed at intervals as much as the width of the multifunctional soundproof module 200 (600) .

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