KR102500016B1 - Manufacturing method of indoor fine dust reduction and air purification system using bio-moss benches including carbonized cork moss panels capable of purifying water quality, decomposing pollutants, antifouling performance, and reducing CO2 - Google Patents

Abstract

The present invention relates to a method for manufacturing a fine dust reduction and air purification system for indoor use using biomoss benches including carbonized cork moss panels capable of purifying water, decomposing pollutants, achieving antifouling performance, and reducing CO_2. The method for manufacturing a fine dust reduction and air purification system for indoor use, according to the present invention, comprises the steps of: preparing a design carbonized cork panel (100); and combining the design carbonized cork panel (100) with a design carbonized cork panel protection frame (200). Therefore, indoor fine dust can be reduced, and the air can be purified.

Description

Manufacturing method of indoor fine dust reduction and air purification system using bio moss bench including carbonized cork moss panel capable of water purification, pollutant decomposition, antifouling performance and CO2 reduction {Manufacturing method of indoor fine dust reduction and air purification system using bio-moss benches including carbonized cork moss panels capable of purifying water quality, decomposing pollutants, antifouling performance, and reducing CO2}

The present invention relates to a method for manufacturing an indoor fine dust reduction and air purification system using a bio moss bench including a carbonized cork moss panel capable of water purification, pollutant decomposition, antifouling performance and CO ₂ reduction, and specifically, fine dust By planting moss with excellent air purification ability by decomposing CO ₂ and production of fresh oxygen by absorption capacity and photosynthesis, special powder with ingredients that can promote the dispersion and decomposition of pollutants such as fine dust collected under the moss Using the coated carbonized cork panel as a carrier, it creates a stable growth environment for moss along with the antibacterial function of the carbonized cork itself, and its main function is to reduce fine dust and naturally purify indoor air, while enhancing the user's emotional stability. It relates to a method for manufacturing an indoor fine dust reduction and air purification system using a bio moss bench.

Recently, a lot of fine dust harmful to the human body has been generated due to air pollution, which has emerged as an environmental problem, and various attempts have been made to solve air quality problems caused by yellow dust, fine dust, volatile organic compounds (VOCs), and heavy metals.

Registered Patent No. 10-2227576 is a planting system for growing air-purifying plants such as moss. Specifically, it is provided with a moss planting bed on which moss is cultivated indoors, and a moss culture holder for mounting a plurality of them, so that the moss is cultivated. Not only can it be planted, but it can greatly reduce fine dust by carbon assimilation of cultivated moss, create a natural atmosphere by discharging natural air, and prevent leakage to the outside while protecting moss. It can not only prevent moss from dying, but also create a perfect growth environment for moss while forming the circulation of moss. Since there is no leakage to the outside while water is stored, it can be used conveniently while supplying water safely indoors. It can not only remove fine dust and heavy metals, but also improve antibacterial and air purification through moss, prevent moss from dying, and reduce fine dust that can significantly improve the growth environment of moss. Contents It is about moss planting and natural air purification system.

Registration No. 10-2014045 can greatly reduce fine dust by dissolving fine dust in water while mixing fine dust with water. It can prevent dying of plants, supplies moisture and active oxygen to air purifying plants to purify the sprayed water, and promotes the growth of air purifying plants to purify the air. It can be used, and air purifying plants such as moss can easily grow along the spring, and it can be safely protected from external physical impact by being seated inside it, and active air is supplied to the air purifying plant to protect it from moss and moss. It can antibacterially and purify the same air purifying plant, and the mounting system can be easily moved with little force and installed anywhere, and it is convenient because it does not require wiring work to supply separate power when connected to a solar cell. It relates to a mounting system for four-season air-purifying plants that can be used conveniently and can reduce fine dust.

Prior Patent No. 10-2227576 and No. 10-2014045 both relate to an air purifying system including a panel made by attaching moss to non-woven fabric, but when made by attaching moss to non-woven fabric, there is a problem with moss flowing down and wire mesh There is a problem that it is difficult to maintain the shape unless additional accessories are combined together, and there is a concern that environmental pollution may occur due to the material of the non-woven fabric.

Korea Patent Registration No. 10-2227576 (2021.03.08) Korean Registered Patent Publication No. 10-2014045 (2019.08.19)

The present invention is a method for manufacturing an indoor fine dust reduction and air purification system using a bio moss bench installed indoors, which is formed in a bench type to allow sitting, to reduce indoor fine dust and to purify the air. will be.

In addition, the present invention relates to a system using a moss panel having a structure in which moss can stably attach to and grow on a board even without a separate support and protection wire net by planting moss on a carbonized cork panel designed with grooves formed thereon.

A carbonized cork panel is used as a carrier to help stable moss vegetation, reduce pollutants such as fine dust absorption through moss, and supply natural air such as fresh oxygen generated by photosynthesis through convection rather than forcedly driven by a motor. It is to provide an air purification fine dust reduction system by a vertical moss panel including a vertical carbonized cork moss panel capable of simultaneously purifying the air and suppressing carbon generation by supplying in a natural way.

In addition, the vertical carbonized cork moss panel of the present invention has a high ability to decompose CO2 and reduce fine dust, and is capable of stable vegetation of moss, which has a superior oxygen generation ability by photosynthesis compared to other plants, and at the same time, it is effective in air purification by removing these pollutants. As a semi-permanent non-structured vertical carbonized cork moss panel with effective effects, it is intended to present an effective structure for air purification and fine dust reduction.

In order to solve the above problem, the present invention is a design carbonized cork panel 100 of a predetermined size in which moss is planted and a design formed to have a predetermined accommodation space to accommodate the design carbonized cork panel 100 A carbonized cork panel protection frame 200 and a water supply pipe 300 formed in the form of a pipe with a predetermined length to supply water to one side of the design carbonized cork panel 100 by receiving water from the water tank 600 ,
A spray nozzle 400 connected to the end of the water supply pipe 300 and spraying water to one side of the design carbonized cork panel 100, and a design carbonized cork panel located on one side of the design carbonized cork panel 100 A moss growth lighting 500 for irradiating light so as to promote the growth of moss planted in 100, a water tank 600 formed to have a predetermined space so that water can be contained, and the water The operation of the circulation pump 700 connected to the tank 600 through a pipe and moving the water contained in the water tank 600, the lighting for moss growth 500, the circulation pump 700, and the timer 1000 A controller 800 for controlling, a power supply unit 900 for supplying power to the controller 800, connected to the controller 800, but controlling the operation time of the moss growth lighting 500 and the circulation pump 700 A timer 1000 for doing this, and a water collection tank located at the bottom of the design carbonized cork panel 100 at a predetermined interval, but allowing the water sprayed from the spray nozzle 400 to the design carbonized cork panel 100 to flow down and be accommodated. 1100, and a filter unit formed such that one side is connected to the water recovery tank 1100 and the other side is connected to the water tank 600 to purify the water received from the water recovery tank 1100 and deliver it to the water tank 600 ( 1200), a board frame portion 1300 in which the design carbonized cork panel 100 is accommodated to form an appearance, and a bench portion 1400 located on one side of the lower portion of the board frame portion 1300 but allowing people to sit on it. In the method of manufacturing an indoor fine dust reduction and air purification system using a bio moss bench including a carbonized cork moss panel capable of water purification, pollutant decomposition, antifouling performance and CO2 reduction, characterized in that it comprises, design carbonization The design carbonized cork panel preparation step of preparing the cork panel 100; The step of combining the design carbonized cork panel 100 with the design carbonized cork panel protection frame 200, wherein the design carbonized cork panel preparation step is not processed. A first carbonized cork panel preparation step (S11) of preparing an untreated carbonized cork panel 10; The first step of 3D milling (S12) to manufacture the designed design carbonized cork panel 100 by milling the upper part of the carbonized cork panel 10 prepared in the first carbonized cork panel preparation step (S11) according to the 3D designed shape in advance ); A first adhesive application step (S13) of applying adhesive to the upper surface of the design carbonized cork panel 100 manufactured through the first step of 3D milling (S12); Special powder on the surface of the moss panel onto which the adhesive is sprayed A first special powder application step (S14) of applying; After the first special powder application step (S14), dry moss 60 is applied to the upper surface of the design carbonized cork panel 100 to which the special powder is applied. A first dry moss coating step (S15) of manufacturing a panel; A first moss vegetation step (S16) of vegetating the moss panel prepared through the first dry moss coating step (S15) for a predetermined time; The carbonized cork panel 10 in the first carbonized cork panel preparation step (S11) has a density of 100 kg/m3 or more, and is characterized in that it includes a water pipe formed in a wave pattern forming mountains and valleys, and the first step of 3D milling The design carbonized cork panel panel 100 of (S12) is characterized in that a groove of a predetermined length is formed, and the first adhesive application step (S13) applies an adhesive to the groove portion formed in the design carbonized cork panel panel 100. It is characterized by spraying, and the first special powder application step (S14) is characterized in that the special powder is applied to the groove portion formed in the design carbonized cork panel panel 100, and the first special powder application step ( The special powder of S14) includes titanium dioxide, illite, and tourmaline, but the titanium dioxide is formed in a size of 100 nm so as to be supported in the pores of illite, illite is yellow illite, and tourmaline is anatase Characterized in that it is formed in a mold, the special powder of the first special powder application step (S14) is composed of 5 to 10% by weight of titanium dioxide, 60 to 80% by weight of illite, and 10 to 35% by weight of tourmaline Characterized in that, the special powder of the first special powder application step (S14) is i) illite 60 ~80% by weight Prepare 5-10% by weight of titanium dioxide and 10-35% by weight of tourmaline, ii) first mix the titanium dioxide and illite prepared in step i) for about 1 to 3 minutes to obtain a primary mixture and iii) mixing the primary mixture with a mixing machine for 1 to 3 minutes after step ii) to produce a special powder, characterized in that the first dry moss coating step (S15) is a design carbonized cork panel manufactured by applying dry moss to the groove part formed in the design carbonized cork panel panel 100, characterized in that carbonized cork moss capable of water purification, pollutant decomposition, antifouling performance and CO2 reduction Provided is a method for manufacturing an indoor fine dust reduction and air purification system using a bio moss bench including a panel.

The present invention is an indoor fine dust reduction and air purification system using a bio moss bench installed indoors, which is formed in a bench shape to allow sitting, and has an effect of reducing indoor fine dust and purifying the air.

An object of the present invention is to use a carbonized cork panel as a carrier to help stable moss vegetation with the antibacterial function of carbonized cork itself, to reduce pollutants such as fine dust absorption through moss, and to provide natural products such as fresh oxygen generated by photosynthesis. Air purification by a vertical moss panel including a vertical carbonized cork moss panel capable of simultaneously purifying the air and suppressing carbon generation by supplying air in a natural way by convection rather than by supplying forcedly driven air by a motor It has the effect of providing a fine dust reduction system.

In addition, the vertical carbonized cork moss panel of the present invention has a high CO ₂ decomposition and fine dust reduction ability, and a superior oxygen generation ability by photosynthesis compared to other plants, enabling stable vegetation of moss and at the same time removing such pollutants from the air. It is a semi-permanent non-structural vertical carbonized cork moss panel that is effective for purification and is effective for air purification and fine dust reduction.

1 is a view of an indoor fine dust reduction and air purification system using a bio moss bench of the present invention.
2 is a view showing the back of the indoor fine dust reduction and air purification system using the biomoss bench of the present invention.
3 is a view showing in detail the configuration of an indoor fine dust reduction and air purification system using a bio moss bench of the present invention.
Figure 4 is a partial enlarged view of the moss panel of Example 1 used in the present invention.
Figure 5 is a flow chart related to the moss panel manufacturing method of Example 1 of the present invention.
6 is a photograph of the first carbonized cork panel preparation step (S11) of the moss panel manufacturing method of Example 1.
7 and 8 are photographs of the first step of 3D milling (S12) of the moss panel manufacturing method of Example 1.
9 is a photograph of a milled moss panel completed through the first 3D milling step (S12) of the method for manufacturing a moss panel in Example 1.
10 is a photograph of the first adhesive application step (S13) of the moss panel manufacturing method of Example 1.
11 to 13 are photographs of the special powder material used in the first special powder application step (S14) of the moss panel manufacturing method of Example 1.
14 is a photograph of the first special powder application step (S14) of the moss panel manufacturing method of Example 1.
15 is a view showing the state in which the special powder is applied through the first special powder application step (S14) of the moss panel manufacturing method of Example 1.
16 is a photograph of the first dry moss coating step (S15) of the moss panel manufacturing method of Example 1.
17 is a photograph of the first moss vegetation step (S16) of the moss panel manufacturing method of Example 1.
18 is a partially enlarged view of the moss panel of Example 2 used in the present invention.
19 is a flowchart of a method for manufacturing a moss panel according to Example 2 of the present invention.
20 is a photograph of the second step of 3D milling (S22) of the moss panel manufacturing method of Example 2.
21 is a simplified schematic diagram of the moss panel of Example 2.
22 is a photograph of the milled moss panel completed through the second special powder application step (S23) of the moss panel manufacturing method of Example 2.
23 is a photograph of the second adhesive spraying step (S24) of the moss panel manufacturing method of Example 2.
24 is a photograph of the second vegetation moss planting step (S25) of the moss panel manufacturing method of Example 2.
25 is a photograph of the second vegetation moss panel maintenance step (S26) of the moss panel manufacturing method of Example 2.
26 is a view showing the operation of the injection nozzle of the indoor fine dust reduction and air purification system using the biomoss bench of the present invention.
27 is a view showing the operation of the lighting unit for moss growth of the indoor fine dust reduction and air purification system using the bio moss bench of the present invention.
28 is a view showing a person sitting on the bench of the indoor fine dust reduction and air purification system using the biomoss bench of the present invention.

The terms or words used in this specification and claims should not be construed as being limited to ordinary or dictionary meanings, and the inventors can properly define the concept of terms in order to explain their invention in the best way. Based on the principle, it should be interpreted as a meaning and concept consistent with the technical idea 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 a patent related to Application No. 10-2021-0135036 (a carbonized cork moss panel manufacturing method capable of water purification, pollutant decomposition, antifouling performance and CO2 reduction), and the characteristics of the water pipe 110, which is the core content, are shared. It is to apply for a related patent in the state of being.

1 is a view of an indoor fine dust reduction and air purification system using a bio moss bench of the present invention.

2 is a view showing the back of the indoor fine dust reduction and air purification system using the biomoss bench of the present invention.

The present invention relates to an indoor fine dust reduction and air purification system using a bio moss bench including a carbonized cork moss panel capable of water purification, pollutant decomposition, antifouling performance and CO ₂ reduction, and specifically, fine dust absorption ability and Carbonization by planting moss with excellent air purification ability by decomposing CO ₂ through photosynthesis and production of fresh oxygen, and applying special powder with ingredients that can accelerate the dispersion and decomposition of pollutants such as fine dust collected under the moss A bio moss bench with a cork panel as a carrier, creating a stable growth environment for moss along with the antibacterial function of carbonized cork itself, enhancing the user's emotional stability, reducing fine dust, and naturally purifying indoor air. It relates to an indoor fine dust reduction and air purification system using

3 is a view specifically showing the configuration of an indoor fine dust reduction and air purification system using a bio moss bench of the present invention, the configuration of the present invention is a design carbonized cork panel 100, a design carbonized cork panel protection frame 200 , water supply pipe 300, spray nozzle 400, lighting for moss growth 500, water tank 600, circulation pump 700, controller 800, power unit 900, timer 1000, water recovery tank 1100, a filter unit 1200, a board frame unit 1300, a bench unit 1400, and an electronic display unit 1500.

A detailed description of each component is as follows.

The design carbonized cork panel 100 is a board of a predetermined size in which moss is planted.

The design carbonized cork panel 100 may be composed of two types, and each of the two types includes a wave water pipe 110 or a square wave water pipe 120.

As a first type, the design carbonized cork panel 100 includes a water wave pipe 110, and the wave water pipe 110 is formed in a wave shape forming peaks and valleys as shown in FIG.

The wave water pipe 110 has been recognized as a key technology in Patent Application No. 10-2021-0135036 (a carbonized cork moss panel manufacturing method capable of water purification, decomposition of contaminants, antifouling performance and CO2 reduction), and its contents yes share it

Another type is that the design carbonized cork panel 100 includes a square wave water pipe 120, and the square wave water pipe 120 is formed in a square wave shape forming hills and valleys. Although the shape shown in FIG. 18 is close to a wave shape, it is preferable to form a square wave shape as shown in the schematic diagram of FIG. 21 .

As such, the design carbonized cork panel 100 can be formed in two types. The first type is a type in which a water pipe 110 is formed and dry moss is planted on the design carbonized cork panel 100 as shown in FIG. (Example 1).

The carbonized cork moss panel of the present invention is a panel that vegetates moss by applying a special powder to the designed carbonized cork panel and then applying moss _spores . and disperses and decomposes the collected pollutants, CO ₂ and polluted water through oxygen catalyst, photocatalyst and tourmaline, helps moss vegetation through the carbonized cork at the bottom, and increases the dispersion of the catalyst as a shade, as well as wave pattern It is a non-structural panel that can control humidity by circulating water from which pollutants are removed through furnace water pipes.

5 is a flow chart of a method for manufacturing a design carbonized cork panel 100 according to Example 1 of the present invention. The first carbonized cork panel preparation step (S11) and the first 3D milling step (S12) of the method for manufacturing a moss panel according to Example 1 , The first adhesive application step (S13), the first special powder application step (S14), the first dry moss application step (S15), and the first moss vegetation step (S16).

Each step is described in detail as follows.

S11) First carbonized cork panel preparation step

The first carbonized cork panel preparation step (S11) is a step of preparing an unprocessed carbonized cork panel 10.

6 is a photograph of the first carbonized cork panel preparation step (S11) of the carbonized cork moss panel manufacturing method of the present invention, the carbonized cork panel 10 prepared in the present invention has a density of 100 kg / m ³ or more carbonized cork panel It is preferable to prepare (10), and if the density is lower than the above, a problem of poor durability occurs during the milling operation.

In addition, the carbonized cork of the present invention does not react to formaldehyde and explosives as a carrier of moss vegetation, and does not emit basic toxic emissions, and preferably includes a porous material capable of moss vegetation and a water pipe for continuous circulation.

S12) 1st step of 3D milling

The first step of 3D milling (S12) is a design carbonized cork panel 100 designed by milling the upper part of the carbonized cork panel 10 prepared in the first carbonized cork panel preparation step (S11) according to the 3D designed shape in advance It is a step of manufacturing.

7 is a diagram showing a design drawing 20 designed in a pre-processed panel shape using a 3D program to process the carbonized cork panel 10 into a predetermined shape,

The designed design carbonized cork panel 100 can be manufactured by performing a 3D milling operation as shown in FIG. 9(b) using the 3D milling machine 30 of FIG. 8(a).

9 is a photograph of the designed design carbonized cork panel 100 for which the milling operation has been completed through the first 3D milling step (S12) of the moss panel manufacturing method of the present invention.

9 (a), (b), (c), the shape of the design carbonized cork panel 100 can be formed in various shapes according to the design shape of the panel shape.

Preferably, the design carbonized cork panel 100 has grooves of a predetermined length so that moss spores can be planted so that moss spores can be planted.

S13) First adhesive application step

The first adhesive application step (S13) is a step of applying an adhesive to the upper surface of the design carbonized cork panel 100 manufactured through the first 3D milling step (S12).

10 is a photograph of the adhesive application step (S13) of the carbonized cork moss panel manufacturing method of the present invention, in which the adhesive is sprayed on the groove portion formed in the design carbonized cork panel 100, which is the portion to which moss spores are applied, as shown in the drawing. is a picture showing

The adhesive is applied to help the rooting of powder for antifouling performance and moss spores, and various adhesives such as woodworking adhesives, EVA adhesives, and UV curing agents can be applied, but adhesives containing volatile organic compounds that inhibit moss vegetation It is preferable to exclude

S14) First special powder application step

The first special powder application step (S14) is a step of applying special powder to the surface of the moss panel on which the adhesive is sprayed after the first adhesive application step (S13).

Preferably, special powder is applied to the groove portion formed in the design carbonized cork panel 100.

11 to 14 are pictures of the material of the special powder used in the special powder application step (S4) of the present invention, Figure 11 is a picture of illite (yellow), Figure 12 is a picture of tourmaline, Figure 13 is a picture of titanium dioxide.

The special powder used in the special powder application step (S4) is composed of titanium dioxide, illite, and tourmaline. Preferably, titanium dioxide has a size of 100 nm that can be supported in the pores of illite (FIG. 13 ( b) Reference), in the case of illite, yellow illite having a higher zeta potential than white illite is preferred (refer to FIG. 11), and in the case of tourmaline, anatase type having high photocatalytic reactivity is preferred (Fig. 12(b) reference).

The composition ratio of the special powder is preferably composed of 60 to 80% by weight of illite, 5 to 10% by weight of titanium dioxide, and 10 to 35% by weight of tourmaline. It has the effect of adsorbing contaminants by increasing the surface area while effectively reducing the amount of titanium dioxide used.

A method of manufacturing the special powder is as follows.

i) Prepare illite 60-80 wt%, titanium dioxide 5-10 wt%, and tourmaline 10-35 wt%.

ii) A first mixture is prepared by first mixing titanium dioxide and illite prepared in step i) for about 1 to 3 minutes.

iii) After step ii), special powder is prepared by mixing tourmaline with the primary mixture for 1 to 3 minutes using a mixing machine.

14 is a photograph showing the state of manufacturing the special powder used in the first special powder application step (S14) of the present invention.

The special powder prepared as described above is a powder with antifouling and purification functions, and is responsible for adsorption of contaminants and maximization of the surface reaction of the photocatalyst through illite among the components of the special powder. As a photocatalytic material, titanium is responsible for decomposition of contaminants through radical hydroxide reaction and superoxide ion.

In addition, tourmaline, which is added and mixed after addition, has the characteristics of continuously adsorbing, dispersing, decomposing, and releasing pollutants through the dispersion and circulation of pollutants through zeta potential and electrical charging with illite.

15 shows the special powder 50 settled in the micropores of the design carbonized cork panel 100 when the special powder 50 is applied to the design carbonized cork panel 100 through the first special powder application step (S14). Referring to the drawing showing the appearance, it can be schematically confirmed that the special powder has settled into the micropores of the design carbonized cork panel 100.

S15) First dry moss coating step

In the first dry moss application step (S15), after the first special powder application step (S14), the dry moss 60 is applied to the upper surface of the design carbonized cork panel 100 to which the special powder is applied to manufacture a moss panel. It is a step to

16 is a photograph of the first dry moss spraying step (S15) of the carbonized cork moss panel manufacturing method of the present invention.

The first special powder application step (S14) and the first dry moss application step (S15) may be performed sequentially, but the application of the special powder and the application of dry moss may be performed at the same time. proceed selectively.

S16) 1st moss vegetation stage

The first moss vegetation step (S16) is a step of vegetating the moss panel manufactured through the first dry moss coating step (S15) for a predetermined time.

17 is a photograph of the first moss vegetation step (S16) of the carbonized cork moss panel manufacturing method of the present invention. it is desirable

Figure 4 is a schematic view of the appearance of the moss panel attached to the wall surface (1), the moss panel of the present invention collects CO ₂ through the uppermost layer of the moss (a portion marked a) and the design carbonized cork panel at the bottom ( 100) it is possible to stabilize the vegetation of the moss (400a). In addition, it is possible to help moss vegetation with fertilizer through illite, which is the main material of the special powder 50, and in the case of tourmaline, it has a photocatalyst capable of decomposing pollutants and a function of dispersing and circulating pollutants.

In other words, moss is a living organism that captures CO ₂ and generates oxygen. As a safe vegetation, stable moss settlement and vegetation can be maintained through a water pipe that can continuously move moisture and maintain air gaps through porous carbonized cork with high moisture storage capacity, The composition of the special powder has ingredients that help moss vegetation. In the case of illite, it is responsible for adsorbing external contaminants and maximizing the surface reaction of photocatalyst. It has a function of decomposing materials, and tourmaline has the advantage of being able to continuously adsorb, disperse, decompose, and release pollutants through the dispersion and circulation of pollutants.

18 is a partially enlarged view of the design carbonized cork panel planted with moss of Example 2 used in the present invention.

The design carbonized cork panel 100 according to Example 2 is configured by forming a square wave water pipe 120, and the square wave water pipe 120 is formed in a square wave shape forming peaks and valleys.

19 is a flow chart of a method for manufacturing a vertical carbonized cork moss panel according to the present invention. The method for manufacturing a vertical carbonized cork moss block according to Example 2 includes a second moss culturing step (S20) and a second carbonized cork panel preparation step (S21). , 2nd step of 3D milling (S22), 2nd special powder application step (S23), 2nd adhesive application step (S24), 2nd cultured moss planting step (S25), 2nd planted moss panel maintenance step (S26) proceeds, including

S20) Second moss culture step

The second moss culturing step (S20) is a step of culturing live moss to produce cultured moss.

S21) Second carbonized cork panel preparation step

The second carbonized cork panel preparation step (S21) is a step of preparing an unprocessed carbonized cork panel 10.

The second carbonized cork panel preparation step (S21) is the same as the first carbonized cork panel preparation step (S11) of Example 1, and the prepared carbonized cork panel 10 has a density of 100 kg / m ³ or more Carbonized cork panel (10 ) It is preferable to prepare, and if the density is lower than the above, a problem of poor durability occurs during milling.

In addition, the carbonized cork of the present invention does not react to formaldehyde and explosives as a carrier of moss vegetation, and does not emit basic toxic emissions, and preferably includes a porous material capable of moss vegetation and a water pipe for continuous circulation.

S22) 2nd step of 3D milling

The second step of 3D milling (S22) manufactures the design carbonized cork panel 100 by milling the upper part of the carbonized cork panel 10 prepared in the second carbonized cork panel preparation step (S21) according to the 3D designed shape in advance It is a step to

After designing the carbonized cork panel 10 in a pre-processed panel shape using a 3D program to process it into a predetermined shape, using the 3D milling machine 30 of FIG. Likewise, the design carbonized cork panel 100 may be manufactured by performing the 3D milling operation.

20 is a photograph of a design carbonized cork panel 100 for which the milling operation has been completed through the second 3D milling step (S22) of the carbonized cork moss panel manufacturing method of the present invention.

As shown in FIG. 20, the shape of the design carbonized cork panel 100 may be formed in various shapes according to the design shape of the panel shape.

21 is a simplified schematic view of a design carbonized cork panel attached to a wall at right angles, after which the milling operation has been completed through the second 3D milling step (S22).

Referring to this, the design carbonized cork panel 100 is formed of a square wave-shaped water pipe 120 forming a peak and a valley. In this way, the square wave shape of the square wave water pipe 120 is formed, so that when the design carbonized cork panel 100 is installed on the wall, the amount of water flowing down due to gravity is stagnant and the moisture can be retained in the valley. there is.

S23) Second special powder application step

The second special powder application step (S23) is a step of applying special powder to the surface of the design carbonized cork panel 100.

Preferably, special powder is applied to a portion of the square wave water pipe 120 formed on the design carbonized cork panel 100.

The special powder used in the second special powder application step (S23) is the same material as in the first special powder application step (S14) of Example 1, and the special powder used in the second special powder application step (S23) is discretized. It is composed of titanium, illite, and tourmaline.

The composition ratio of the special powder is preferably composed of 70 to 80% by weight of illite, 10 to 15% by weight of titanium dioxide, and 10 to 15% by weight of tourmaline. Increase the surface area by configuring illite in the above range This has the effect of effectively reducing the amount of expensive titanium dioxide used while increasing the surface area to adsorb contaminants.

A method of manufacturing the special powder is as follows.

i) 70 to 80% by weight of illite, 10 to 15% by weight of titanium dioxide, and 10 to 15% by weight of tourmaline are prepared.

ii) A first mixture is prepared by first mixing titanium dioxide and illite prepared in step i) for about 1 to 3 minutes.

iii) After step ii), special powder is prepared by mixing tourmaline with the primary mixture for 1 to 3 minutes using a mixing machine.

The special powder prepared as described above is a powder with antifouling and purification functions, and is responsible for adsorption of contaminants and maximization of the surface reaction of the photocatalyst through illite among the components of the special powder. As a photocatalytic material, titanium is responsible for decomposition of contaminants through radical hydroxide reaction and superoxide ion.

In addition, tourmaline, which is added and mixed after addition, has the characteristics of continuously adsorbing, dispersing, decomposing, and releasing pollutants through the dispersion and circulation of pollutants through zeta potential and electrical charging with illite.

S24) Second adhesive application step

The second adhesive application step (S24) is a step of applying adhesive to the upper surface of the design carbonized cork panel 100.

Preferably, after the second special powder application step (S23), the adhesive is applied to the portion of the first square wave water pipe 120 formed on the carbonized cork panel 100 of the first design.

23 is a photograph of the second adhesive application step (S24), in which the adhesive is applied to the upper part where the special powder is applied to the groove part formed in the first design carbonized cork panel 100, which is the part where the cultured moss will be planted, as shown in the figure. This is a picture of what it looks like.

The adhesive is applied to help the adhesion of special powder, securing appropriate air gaps for moisture retention, and stable engraftment of planted moss. It is preferable to exclude adhesives containing volatile organic compounds and the like.

S25) Second cultured moss planting step

The second cultured moss planting step (S25) is a step of manufacturing a vegetation moss panel by planting the cultured moss cultured through the second moss culture step (S20) on the upper surface of the design carbonized cork panel 100 to which the adhesive is applied. am.

24, as shown in the photo of the second cultured moss planting step (S25) of the carbonized cork moss panel manufacturing method of the present invention, it is preferable to plant cultured moss mainly in the square wave water pipe 120 formed in the design carbonized cork panel 100. do.

That is, the second cultured moss planting step (S25) is to cut the cultured moss to a predetermined size and plant the cultured moss along the inside of the square wave water pipe 120 formed in the design carbonized cork panel 100.

S26) Second planted moss panel maintenance step

The second planted moss panel maintenance step (S26) is a step of maintaining the vegetation moss panel manufactured through the second cultured moss planting step (S25) for a predetermined time.

25 is a photograph of the second planted moss panel maintenance step (S26) of the carbonized cork moss panel manufacturing method of the present invention, the second planted moss panel maintenance step (S26) It is desirable to raise about 3-6 months.

Figure 18 is a schematic view of the appearance of the moss panel attached to the wall surface (1), the vertical carbonized cork moss panel of the present invention collects CO2 through the uppermost layer of the moss (the part indicated by a) and carbonizes the design at the bottom Vegetation of cultured moss 70 planted through the cork panel 100 can be stabilized. In addition, it is possible to help moss vegetation by maximizing the surface reaction of the photocatalyst through illite, which is the main material of the special powder 50, and in the case of tourmaline, it has a photocatalyst capable of decomposing pollutants and a function of dispersing and circulating pollutants.

That is, the cultured moss 70 is a moss in culture, and the moss has excellent ability to absorb fine dust and decompose CO ₂ and generate oxygen by photosynthesis, and most of the nutrients other than water are inhaled from the outside air, so a separate artificial nutrient supply is required. As an organism that does not have a high moisture storage capacity, it is possible to maintain stable moss settlement and vegetation through a water pipe that can continuously move moisture and maintain appropriate air gaps by using porous carbonized cork. In the case of illite, it is responsible for adsorbing external contaminants and maximizing the surface reaction of photocatalyst. Titanium dioxide supported on illite has the function of decomposing contaminants as a photocatalyst, There is an advantage in that continuous circulation of adsorption, dispersion, decomposition, and release of pollutants is possible through dispersion and circulation of pollutants.

In addition, the design carbonized cork panel 100 of the present invention has a water pipe in the form of a wave, so that when water is supplied to the fog 2 installed on the wall surface 1, the amount of water flowing down due to gravity is stagnant, so that the water is stored in the design carbonized cork It is characterized in that it can be held in the valley of the panel 100. If the surface of the design carbonized cork panel 100 is formed in a straight line, a problem occurs in that moisture does not stay due to gravity and flows down immediately.

This is a very important part in the growth of moss. Unlike other plants that suck up moisture with their roots, moss has only a fixing function as shown in FIG. It has a characteristic that

In addition, the cultured moss of FIG. 18 is as if one cultured moss is planted on the square wave-shaped design carbonized cork panel 100, but this is preferably in the form of a lump of cultured moss, and is shown in only one form to help explain the invention. will be.

Reflecting these characteristics of moss, the design carbonized cork panel 100 of the present invention has a wavy shape rather than a straight shape and supplies moisture stored in the bone to the moss as shown by the arrow in FIG. It can promote growth, and it is characterized by being formed in a shape where more moisture can stay than in a straight line.

In other words, in order to effectively collect moisture, it is a key aspect of the present invention that the air moisture can be collected intensively toward the moss by intentionally creating a wavy shape so that the air moisture is collected toward the head of the moss in order to effectively collect moisture. characteristic. Since the height of the moss is not high, it has the advantage that the moisture remaining in the bone part can be absorbed directly into the body of the moss.

In addition, in the present invention, contaminants can be removed through moss and humidity can be controlled by circulating water through a water pipe having a wavy pattern formed on carbonized cork. In addition, since the water pipe is formed in a wavy shape, there is an effect of allowing a large amount of water to circulate in the carbonized cork.

The design carbonized cork panel protection frame 200 is formed to have a predetermined accommodation space to accommodate the design carbonized cork panel 100. That is, the design carbonized cork panel protection frame 200 is formed to surround a portion except for the front surface of the design carbonized cork panel 100 .

The water supply pipe 300 receives water from the water tank 600 and supplies the water to one side of the design carbonized cork panel 100 and is formed in a pipe shape with a predetermined length.

One side of the water supply pipe 300 is formed by being connected to the water tank 600 and the circulation pump 700, and the other side is formed extending along the rear surface of the design carbonized cork panel 100 to the upper end, and the design carbonized cork panel 100 ) Branched in one direction of the water supply pipe 300 is formed. In addition, the branching point of the water supply pipe 300 may be branched into multiple branches depending on the length and size of the design carbonized cork panel 100.

The spray nozzle 400 is connected to the end of the water supply pipe 300 and is for spraying water to one side of the design carbonized cork panel 100. That is, the spray nozzle 400 is formed at the end of the water supply pipe 300 branched into two branches as shown in FIG. 3, which is located at the end of the water supply pipe 300.

26 is a view showing the operation of the spray nozzle of the indoor fine dust reduction and air purification system using the bio moss bench of the present invention. The water supplied through the water supply pipe 300 is sprayed by the spray nozzle 400 Water is sprayed into the design carbonized cork panel (100).

In this way, the spray nozzle 400 is formed as the first spray nozzle 410 on the top of the design carbonized cork panel 100 and formed as the second spray nozzle 420 on one side of the design carbonized cork panel 100, thereby design carbonization. It serves to help the growth of the planted moss by evenly watering the cork panel 100.

The lighting for moss growth 500 is located on one side of the design carbonized cork panel 100 to irradiate light so as to promote the growth of moss planted on the design carbonized cork panel 100.

Preferably, the moss growth lights 500 are formed on one side of the upper and lower ends of the design carbonized cork panel 100, respectively, and the moss growth lights 500 located at the top control the moss planted on the design carbonized cork panel 100. The lighting 500 for moss growth located at the bottom radiates light from the lower part of the design carbonized cork panel 100 to spread light evenly over the entire area of the moss planted on the design carbonized cork panel 100. let this be investigated.

If necessary, the location is not limited, such as the lighting 500 for growing moss may be located in the center of the design carbonized cork panel 100.

The moss growth lighting 500 is a necessary configuration because the indoor fine dust reduction and air purification system using the bio moss bench of the present invention is installed indoors, and can artificially replace natural light for moss by not receiving external light. It is intended to irradiate the light that is there.

The water tank 600 is formed to have a predetermined space to contain water.

The circulation pump 700 is connected to the water tank 600 through a pipe and allows the water contained in the water tank 600 to move.

The controller 800 controls the operation of the lighting for moss growth 500, the circulation pump 700, and the timer 1000.

That is, the controller 800 controls the ON / OFF operation of the moss growth lighting 500,

Control the ON/OFF operation of the circulation pump 700

The operation of the timer 1000 can be controlled.

The power supply unit 900 is for supplying power to the controller 800 .

The timer 1000 is connected to the controller 800 and is for controlling the operation time of the lighting for moss growth 500 and the circulation pump 700.

The time may be set in the timer 1000 in advance or set by changing the time. Depending on the set time, the moss growth lighting 500 operates ON/OFF or the circulation pump 700 operates to supply water to the water supply pipe ( 300 through the spray nozzle 400 can be sprayed with water.

The water collection tank 1100 is located at the lower end of the design carbonized cork panel 100 at a predetermined interval, but is to allow water sprayed from the spray nozzle 400 to the design carbonized cork panel 100 to flow down and be accommodated.

The filter unit 1200 is formed such that one side is connected to the water recovery tank 1100 and the other side is connected to the water tank 600 so as to purify the water received from the water recovery tank 1100 and deliver it to the water tank 600.

Preferably, the filter unit 1200 and the water collection tank 1100 are connected through a water supply pipe 300, and the filter unit 1200 and the water tank 600 are connected through a water supply pipe 300.

That is, this is to recycle the water by sending purified water after filtering foreign matter through the filter unit 1200 to the water tank 600 again.

The board frame portion 1300 is to form the appearance by receiving the design carbonized cork panel 100.

The bench part 1400 is located on one side of the lower part of the board frame part 1300, but is intended to allow a person to sit.

The bench unit 1400 may be formed by being supported on the ground, and may include a water tank 600, a circulation pump 700, a controller 800, a timer 1000, a water recovery tank 1100, a filter unit 1200, and the like. to achieve an inclusive appearance.

The electric display board unit 1500 is located on the side of the board frame unit 1500.

Through this, the present invention is an indoor fine dust reduction and air purification system using a bio moss bench installed indoors, which is formed in a bench shape to allow sitting, to reduce indoor fine dust and to purify the air. .

The embodiments described in this specification and the configurations shown in the drawings as described above are merely the most preferred embodiments of the present invention and do not represent all of the technical spirit of the present invention, so various equivalents and modifications that can replace them It should be understood that there may be examples.

100 Moss Board
110 water pipe
120 square water pipe
200 Design Carbonized Cork Panel Protection Frame
300 water supply pipe
400 spray nozzle
500 Moss Grow Lights
600 water tank
700 circulation pump
800 controller
900 power supply
1000 timer
1100 water recovery tank
1200 filter unit
1300 board frame part
1400 Bench Division
1500 Electronic sign board

Claims (5)

A design carbonized cork panel 100 of a predetermined size in which moss is planted, a design carbonized cork panel protection frame 200 formed to have a predetermined accommodation space to accommodate the design carbonized cork panel 100, and a water tank It is for supplying water to one side of the design carbonized cork panel 100 by receiving water from 600, and is connected to the water supply pipe 300 formed in the form of a pipe of a predetermined length and the end of the water supply pipe 300 A spray nozzle 400 for spraying water to one side of the design carbonized cork panel 100 and located on one side of the design carbonized cork panel 100 to promote the growth of moss planted on the design carbonized cork panel 100 A moss growth lighting 500 for irradiating light so that water can be contained, a water tank 600 formed to have a predetermined space so that water can be contained, and connected to the water tank 600 through a pipe. A controller 800 that controls the operation of the circulation pump 700 for moving the water contained in the tank 600, the lighting for moss growth 500, the circulation pump 700, and the timer 1000, and the controller 800 ), a power supply unit 900 for supplying power, a timer 1000 connected to the controller 800 and controlling the operating time of the moss growth lighting 500 and the circulation pump 700, and a design carbonized cork A water collection tank 1100 located at the lower end of the panel 100 at a predetermined interval but allowing water sprayed from the injection nozzle 400 to the design carbonized cork panel 100 to flow down and be accommodated, and the water collection tank 1100 A filter unit 1200 having one side connected to the water recovery tank 1100 and the other side connected to the water tank 600 to purify the water received from the water tank 600 and transfer it to the water tank 600, and the design carbonized cork panel 100 It is accommodated and forms a board frame portion 1300, and a bench portion 1400 located on one side of the lower portion of the board frame portion 1300 for a person to sit on, characterized in that it includes water purification and pollution A bi-containing carbonized cork moss panel capable of material decomposition, antifouling performance and CO2 reduction In the method of manufacturing an indoor fine dust reduction and air purification system using a cucumber bench,


A design carbonized cork panel preparation step of preparing a design carbonized cork panel 100;
A step of combining the design carbonized cork panel 100 with the design carbonized cork panel protection frame 200,

The design carbonized cork panel preparation step is
A first carbonized cork panel preparation step (S11) of preparing an unprocessed carbonized cork panel 10;
The first 3D milling step of manufacturing the designed design carbonized cork panel 100 by milling the upper part of the carbonized cork panel 10 prepared in the first carbonized cork panel preparation step (S11) according to the 3D designed shape in advance ( S12);
A first adhesive application step (S13) of applying an adhesive to the upper surface of the design carbonized cork panel 100 manufactured through the first 3D milling step (S12);
A first special powder application step (S14) of applying special powder to the surface of the moss panel on which the adhesive is sprayed;
After the first special powder application step (S14), a first dry moss application step (S15) of manufacturing a moss panel by applying dry moss 60 to the upper surface of the design carbonized cork panel 100 to which the special powder is applied ;
A first moss vegetation step (S16) of vegetating the moss panel prepared in the first dry moss application step (S15) for a predetermined time; including,
The carbonized cork panel 10 in the first carbonized cork panel preparation step (S11) has a density of 100 kg/m ³ or more and includes a water pipe formed in a wave pattern forming mountains and valleys,
The design carbonized cork panel 100 in the first step of 3D milling (S12) is characterized in that a groove of a predetermined length is formed,
The first adhesive application step (S13) is characterized in that the adhesive is sprayed on the groove portion formed in the design carbonized cork panel 100,
The first special powder application step (S14) is characterized in that the special powder is applied to the groove portion formed in the design carbonized cork panel 100,
The special powder of the first special powder application step (S14) includes titanium dioxide, illite, and tourmaline,
The titanium dioxide is formed in a size of 100 nm so as to be supported in the pores of the illite, the illite is yellow illite, and the tourmaline is formed in the form of anatase,

The special powder in the first special powder application step (S14) is characterized by comprising 5 to 10% by weight of titanium dioxide, 60 to 80% by weight of illite, and 10 to 35% by weight of tourmaline,
The special powder of the first special powder application step (S14) is
i) preparing illite 60-80 wt% titanium dioxide 5-10 wt%, tourmaline 10-35 wt%,
ii) Prepare a first mixture by first mixing titanium dioxide and illite prepared in step i) for about 1 to 3 minutes,
iii) It is characterized in that it is manufactured through the step of preparing a special powder by mixing the first mixture and tourmaline for 1 to 3 minutes using a mixing machine after step ii),

The first dry moss application step (S15) is a design carbonized cork panel manufactured by applying dry moss to the groove portion formed in the design carbonized cork panel 100, characterized in that water purification, pollutant decomposition, antifouling performance and CO2 Manufacturing method of indoor fine dust reduction and air purification system using bio moss bench including carbonized cork moss panel capable of reduction.
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