KR20220170335A - System and method for producing wet-laid recycled non-woven fabric - Google Patents

Abstract

According to the present invention, a system of manufacturing a wet recycled nonwoven fabric is provided which comprises: a first dispersing device dispersing waste nonwoven fabric pieces by applying physical shock to the waste nonwoven fabric pieces in the water; a second dispersing device dispersing the waste nonwoven fabric pieces in a first waste nonwoven fabric mixed solution discharged from the first dispersing device using a stirrer; a web manufacturing device manufacturing a nonwoven web by putting a mixed raw material solution formed by adding a fixer to a second waste nonwoven fabric mixed solution discharged from the second dispersing device into water through a filter and then draining the water inside; a drain unit discharging water from the web manufacturing device; and a water recycling unit recycling wastewater discharged from the web manufacturing device by the drain unit. The water recycling unit processes and supplies the wastewater as water to one or more of the first dispersing device, the second dispersing device, and the web manufacturing device. Accordingly, water can be used efficiently in a system of manufacturing a wet nonwoven fabric.

Description

Wet recycling nonwoven fabric manufacturing system and method {SYSTEM AND METHOD FOR PRODUCING WET-LAID RECYCLED NON-WOVEN FABRIC}

The present invention relates to a nonwoven fabric manufacturing technology, and more particularly, to a wet recycled nonwoven fabric manufacturing technology.

Non-woven fabric is made by arranging fibers in parallel or irregular directions to form a web and then fixing them to form a felt without going through a weaving process. The nonwoven fabric manufacturing process is largely divided into a dry method and a wet method according to the web formation method. The dry method is a method in which a web is formed in the air, and the wet method is a method in which fibers are dispersed in water to form a web. A large amount of water is used in the production of wet-laid non-woven fabrics, but in the conventional wet-laid non-woven fabric manufacturing method, a technology for efficiently recycling the water used in the production of wet-laid non-woven fabrics has not been disclosed.

Republic of Korea Patent No. 10-1694109 (2017.01.06.)

An object of the present invention is to provide a system and method for efficiently recycling water in a system for wet manufacturing recycled nonwoven fabric using waste nonwoven fabric.

In order to achieve the above object of the present invention, according to an aspect of the present invention, a first dispersing device for dispersing the waste nonwoven fabric pieces by applying a physical impact to the waste nonwoven fabric pieces in water; a second dispersing device for dispersing the waste nonwoven fabric pieces in the mixed solution of the first waste nonwoven fabric discharged from the first dispersing device using an agitator; A web manufacturing device for manufacturing a nonwoven web by injecting a mixed raw material solution formed by adding a fixer to the second waste nonwoven fabric mixture discharged from the second dispersing device into water over a sieve and then draining the water therein; Drainage unit for discharging water from the web manufacturing apparatus; And a water recycling unit that recycles wastewater discharged from the web manufacturing apparatus by the drain unit, wherein the water recycling unit treats the wastewater and is one of the first dispersing device, the second dispersing device, and the web manufacturing apparatus. In the above, a wet recycled nonwoven fabric manufacturing system for supplying water is provided.

In order to achieve the above object of the present invention, according to another aspect of the present invention, a housing providing an inner space, and a strainer installed horizontally in the inner space to divide the inner space into an upper space and a lower space A water supply step of supplying water to the inner space of the web manufacturing apparatus to form a water level of the water in the inner space higher than the sieve; a raw material input step of injecting a mixed raw material solution formed by adding waste nonwoven fabric pieces and a fixer to water into the upper space; A drain step of draining water from the lower space to form a recycled nonwoven fabric laminate on the strainer and a vacuum dehydration step of dehydrating the recycled nonwoven fabric laminate by discharging gas from the lower space so that a vacuum is formed in the lower space And, the water supplying step is performed by supplying the water drained in the draining step to the inner space after purifying, there is provided a wet recycled nonwoven fabric manufacturing method.

According to the present invention, all of the objects of the present invention described above can be achieved. Specifically, since the wastewater discharged from the web manufacturing device is purified by the water recycling unit and then supplied to the first dispersing device, the second dispersing device, and the web manufacturing device, water can be efficiently used in the wet-laid nonwoven fabric manufacturing system.

1 is a schematic diagram schematically showing the configuration of a wet recycled nonwoven fabric manufacturing system according to an embodiment of the present invention.
2 is a longitudinal cross-sectional view of the web manufacturing apparatus of the wet recycled nonwoven fabric manufacturing system shown in FIG.
FIG. 3 is a flow chart illustrating a wet recycled nonwoven fabric manufacturing method using the wet recycled nonwoven fabric manufacturing system shown in FIG. 1 .
Figure 4 shows the state of the web manufacturing apparatus after the water supply step is performed in the wet recycled nonwoven fabric manufacturing method shown in Figure 3.
Figure 5 shows the state of the web manufacturing apparatus after the raw material input step is performed in the wet recycled nonwoven fabric manufacturing method shown in Figure 3.
Figure 6 shows the state of the web manufacturing apparatus after the drainage step is performed in the wet recycled nonwoven fabric manufacturing method shown in Figure 3.

Hereinafter, the configuration and operation of an embodiment of the present invention will be described in detail with reference to the drawings.

1 shows a schematic configuration of a wet recycled nonwoven fabric manufacturing system according to an embodiment of the present invention as a schematic diagram. Referring to FIG. 1, a wet recycled nonwoven fabric manufacturing system 100 according to an embodiment of the present invention is a system for manufacturing a nonwoven fabric by a wet method using waste nonwoven fabric, by applying a physical impact to waste nonwoven fabric pieces in water. A first dispersing device 110 for dispersing the nonwoven fabric pieces, a second dispersing device 120 for further dispersing the waste nonwoven fabric pieces in the first waste nonwoven fabric mixture discharged from the first dispersing device 110, and a second dispersing device A web for manufacturing a nonwoven web using a fixative adding unit 130 for adding a fixer to the second waste nonwoven fabric mixture discharged from the device 120 and a mixed raw material solution formed by adding a fixer to the second dispersed waste nonwoven fabric mixture The manufacturing apparatus 140, the drainage part 150 for draining the water from the web manufacturing apparatus 140, the exhaust part 160 for exhausting the gas from the web manufacturing apparatus 140, and the nonwoven fabric to be wet-processed. It includes a water supply unit 170 for supplying necessary water.

The first dispersing device 110 disperses the waste nonwoven fabric pieces in water by applying a physical impact to the waste nonwoven fabric pieces. In this embodiment, the dispersion performed in the first dispersion device 110 is referred to as preliminary dispersion. A first dispersing space 111 in which preliminary dispersing is performed is formed inside the first dispersing device 110 . Water and waste nonwoven fabric pieces are accommodated in the first dispersion space 111 . The first dispersing device 110 includes a hitting unit 115 that applies a physical impact to the waste nonwoven fabric pieces in the first dispersing space 111 . In this embodiment, the striking means 115 will be described as being a rotating blade located in the lower part of the first dispersion space 111 . That is, in a state where the water and the waste nonwoven fabric pieces are accommodated in the first dispersion space 111, the rotary blade 115 rotates in the first dispersion space 111 to apply an impact to the waste nonwoven fabric pieces, so that the entangled waste nonwoven fabric pieces Dissolves and disperses in water. The waste nonwoven fabric pieces supplied to the first dispersion space 111 are obtained by pulverizing nonwoven fabric scrap or nonwoven waste generated in the process of manufacturing a nonwoven fabric product using a grinder, and preferably have the same properties. The first dispersing device 110 receives water from the water supply unit 170 . The mixed liquid of the first waste nonwoven fabric discharged from the first dispersing device 110 is transferred to the second dispersing device 120 through the first transfer line 117 . Although not shown, the mixed liquid of the first waste nonwoven fabric discharged from the first dispersing device 110 may be re-supplied to the first dispersing device 110 so that the dispersion by the first dispersing device 110 may be repeated.

The second dispersing device 120 further disperses the waste nonwoven fabric pieces in the first mixed solution of waste nonwoven fabrics discharged from the first dispersing device 110 . In this embodiment, the dispersion performed in the second dispersion device 120 is referred to as present dispersion. A second dispersion space 121 in which the dispersion is performed is formed inside the second dispersion device 120 . The mixed solution of the first waste nonwoven fabric transported from the first dispersion device 110 through the first transfer line 117 is introduced into the second dispersion space 121 . The second dispersing device 120 includes a stirrer 125 for this dispersing. In addition, a dispersing agent is introduced into the waste nonwoven fabric mixture contained in the second dispersion space 121 for this dispersion. That is, the second dispersing device 120 performs main dispersing of the waste nonwoven fabric mixed solution accommodated in the second dispersing space 121 by using the stirrer 125 and the dispersant. The second dispersing device 120 receives water from the water supply unit 170 as needed. The second waste nonwoven fabric mixed solution discharged from the second dispersing device 120 is transferred to the web manufacturing device 140 through the second transfer line 127. The second mixed liquid of waste nonwoven fabric discharged from the second dispersing device 120 is re-supplied to the second dispersing device 120 through the feedback line 128 as needed, so that the dispersion by the second dispersing device 120 is repeated. can To this end, a mixture solution flow control valve 129 such as a three-way valve is installed at a point where the second transfer line 127 and the feedback line 128 are connected.

The fixative adding unit 130 supplies the fixative to the second transfer line 127 and adds the fixative to the second waste nonwoven fabric mixture flowing through the second transfer line 127 . The waste nonwoven fabric pieces included in the second waste nonwoven fabric mixture may be structurally aggregated and fixed to each other by the fixative added to the second waste nonwoven fabric mixture flowing through the second transfer line 127 . The fixative may be a commonly used one such as polyvinyl acetate resin or sodium thiosulfate. The fixative adding unit 130 connects the fixative storage tank 131 in which the fixative is stored, the fixative storage tank 131 and the second transfer line 127, and transfers the fixative stored in the fixer storage tank 131 to the second A fixer supply pipe 135 supplying the transfer line 127 is provided. Although not shown, the fixative addition unit 130 includes a pump and a fixer supply pipe 135 for supplying the fixer stored in the fixer storage tank 131 to the second transfer line 127 through the fixer supply pipe 135. ) It is further provided with an on-off valve that opens and closes. In this embodiment, a fixer added to the second waste nonwoven fabric mixture flowing through the second transfer line 127 is referred to as a mixed raw material solution.

The web manufacturing apparatus 140 manufactures a nonwoven web by using a mixed raw material solution formed by adding a fixer to the second waste nonwoven fabric mixed solution. 2 shows the configuration of the web manufacturing apparatus 140. Referring to FIG. 2, the web manufacturing apparatus 140 includes a housing 141, a sieve 145 installed inside the housing 141, and a plurality of gas spray dispersers 147 installed in the housing 141. And, a plurality of ultrasonic dispersers 149 installed in the housing 141, and a plurality of water injectors 1424 and 1426 installed in the housing 141 to spray water to the sieve 145 at high pressure.

The housing 141 includes a floor 142 , a ceiling 143 , and a side wall 144 connecting the floor 142 and the ceiling 143 .

A drain port 1421 for drainage and an exhaust port 1423 through which air is discharged to form a vacuum are formed on the bottom 142 . A drain pipe 153 through which drained water flows is connected to the drain hole 1421 . An exhaust pipe 161 through which exhaust gas flows is connected to the exhaust port 1423 . An exhaust opening/closing valve 1425 for opening and closing the exhaust opening 1423 is installed in the exhaust opening 1423 . The exhaust port opening/closing valve 1425 is for preventing drainage through the exhaust port 1423, and operates to open the exhaust port 1423 only during exhaust operation. A relief valve that opens may be used.

A raw material supply port 1431 for supplying mixed raw materials to the inside of the housing 141 and a water supply port 1433 for supplying water to the inside of the housing 141 are formed on the ceiling 143 . The mixed raw material transported through the second transfer line 127 is supplied into the housing 141 through the raw material supply port 1432 . Water supplied from the water supply unit 170 flows into the housing 141 through the water supply port 1433 .

The sidewall 144 includes an upper sidewall 1441 that is detachably coupled vertically and a lower sidewall 1442 that is integrally formed with the bottom 142 . In this embodiment, the upper sidewall 1441 is integrally formed with the ceiling 143 to form the upper housing 146, and the lower sidewall 1442 is integrally formed with the floor 142 to form the lower housing 148. Explain. A strainer 145 is installed between the upper side wall 1441 and the lower side wall 1442 . The inner space of the housing 141 is separated into an upper space 1411 and a lower space 1412 by a strainer 145 . That is, the inner space of the upper housing 146 becomes the upper space 1411 and the inner space of the lower housing 148 becomes the lower space 1412 . In this embodiment, the exhaust port 1423 is described as being formed on the floor 142, but it may be formed on the lower sidewall 1442 to communicate with the lower space 1412. Although the water supply port 1433 is described as being formed in the ceiling 143 in this embodiment, it may be formed in the upper side wall 1441 to communicate with the upper space 1411 otherwise.

The strainer 145 is installed to be horizontally disposed inside the housing 141. Specifically, the strainer 145 is detachably coupled between the upper side wall 1431 and the lower side wall 1432 . The strainer 145 passes water, which is a component other than the pieces of waste nonwoven fabric, from the mixed raw material solution in the upper space 1411 to the lower space 1412. Water is drained down by the strainer 145, and a recycled nonwoven fabric laminate formed by stacking waste nonwoven fabric pieces on top remains. Although not shown, the strainer 145 may be structurally supported by a support structure.

A plurality of gas dispensing dispersers 147 are installed on the upper sidewall 1431 to inject gas into the upper space 1411 . The dispersed state of the mixed raw material liquid in the upper space 1411 can be continuously maintained by the gas injected into the upper space 1411 by the plurality of gas spray dispersers 147 . A plurality of gas spray dispersers 147 may be disposed along the circumferential direction and the height direction of the upper space 1411 . In this embodiment, the plurality of gas dispensing dispersers 147 will be described as dispensing the gas supplied from the exhaust unit 160 .

A plurality of ultrasonic diffusers 149 are installed on the upper side wall 1431 to generate and radiate ultrasonic waves to the upper space 1411 . The dispersed state of the mixed raw material liquid in the upper space 1411 can be continuously maintained by ultrasonic waves emitted to the upper space 1411 by the plurality of ultrasonic dispersers 149 . A plurality of ultrasonic diffusers 149 may be disposed along the circumferential direction and the height direction of the upper space 1411 .

A plurality of water injectors 1424 and 1426 are installed in the housing 141 to inject water into the sieve 145 at high pressure. A plurality of water injectors 1424 and 1426 are sprayed from below the sieve 145 to the sieve 145 to wash the sieve 145. Water injected at high pressure from the water injectors 1424 and 1426 removes substances stuck in the sieve 145 to prevent the sieve 145 from being clogged. In this embodiment, it is described that the plurality of water injectors 1424 and 1426 are installed on the bottom 142 of the lower housing 148, but they may be installed on the lower sidewall 1442 of the lower housing 148. The plurality of water injectors 1424 and 1426 receive water from the water supply unit 170 .

Drainage unit 150 drains the water from the web manufacturing device 140. Drainage unit 150 is provided with a drain pipe 153 extending from the web manufacturing apparatus 140 and a drain pump 155 forming a drainage pressure so that water is drained from the web manufacturing apparatus 140 through the drain pipe 153 do.

The drain pipe 153 is formed to extend from the drain 1421 of the web manufacturing apparatus 140 to the outside of the web manufacturing apparatus 140. Water drained from the web manufacturing apparatus 140 flows through the drain pipe 153. The water drained through the drain pipe 153 is recycled by the water supply unit 170 . The drain pipe 153 includes a U-shaped pipe portion 154 positioned adjacent to the drain port 1421 . The sealing performance of the lower space 1412 inside the web manufacturing apparatus 140 is improved by the water remaining in the U-tube portion 154. The U-pipe part 154 is located upstream of the drainage pump 155.

The drain pump 155 is installed on the drain pipe 153 to form a drain pressure so that water is drained from the web manufacturing apparatus 140 through the drain pipe 153. The drain pump 155 is located downstream of the U-shaped pipe part 154 of the drain pipe 153.

The exhaust unit 160 discharges the air in the lower space 1412 to the outside so that a vacuum is formed in the lower space 1412 of the web manufacturing apparatus 140. The exhaust unit 160 is provided with an exhaust pipe 161 extending from the web manufacturing device 140 and an exhaust pump 163 forming an exhaust pressure so that gas is exhausted from the web manufacturing device 140 through the exhaust pipe 161. do.

The exhaust pipe 161 is formed to extend to the outside of the web manufacturing apparatus 140 from the exhaust outlet 1423 in which the exhaust opening/closing valve 1425 of the web manufacturing apparatus 140 is installed. Gas exhausted from the web manufacturing apparatus 140 flows through the exhaust pipe 161 . Gas is discharged from the lower space 1412 of the web manufacturing apparatus 140 through the exhaust pipe 161 to form a vacuum in the lower space 1412.

The exhaust pump 163 is installed on the exhaust pipe 161 to form exhaust pressure so that gas is discharged from the lower space 1412 of the web manufacturing apparatus 140 through the exhaust pipe 161 .

The exhaust unit 160 is a structure for supplying gas to the plurality of gas dispensing dispersers 147, and includes a gas supply pipe 164 connected to the exhaust pipe 161, the exhaust pipe 161 and the plurality of gas dispensing dispersers 147. ) It is further provided with a connection pipe 165 connecting them.

The gas supply pipe 164 is connected to a point upstream of the exhaust pump 163 in the exhaust pipe 161 . External air may flow into the exhaust pipe 161 through the gas supply pipe 164 . A first gas flow control valve 166 such as a three-way valve is installed at a point where the gas supply pipe 164 and the exhaust pipe 161 are connected. Depending on the state of the first gas flow control valve 166, the section between the first gas flow control valve 166 and the exhaust pump 163 in the exhaust pipe 161 is a flow control valve 166 in the exhaust pipe 161 It may be selectively communicated with any one of the upstream section and the gas supply pipe 164.

The connection pipe 165 connects the exhaust pipe 161 and the plurality of gas dispensing dispersers 147 . The gas flowing through the exhaust pipe 161 is supplied to each of the plurality of gas dispersion devices 147 through the connection pipe 165 . A second gas flow control valve 167 such as a three-way valve is installed at a point where the connection pipe 165 and the exhaust pipe 161 are connected. Depending on the state of the second gas flow control valve 167, the section between the exhaust pump 163 and the second gas flow control valve 167 in the exhaust pipe 161 is the second gas flow control valve in the exhaust pipe 161. It may be selectively communicated with any one of the downstream section of 167 and the connection pipe 166.

A section between the first gas flow control valve 166 and the exhaust pump 163 communicates with a section upstream of the flow control valve 166 in the exhaust pipe 161 by the first gas flow control valve 166, and a second The section between the exhaust pump 163 and the second gas flow control valve 167 in the exhaust pipe 161 by the gas flow control valve 167 is the downstream section of the second gas flow control valve 167 in the exhaust pipe 161 In a state of communication with, when the exhaust pump 163 operates, the gas in the lower space 1412 of the web manufacturing apparatus 140 is exhausted through the exhaust pipe 161 to form a vacuum in the lower space 1412. A section between the first gas flow control valve 166 and the exhaust pump 163 is communicated with the gas supply pipe 164 by the first gas flow control valve 166, and by the second gas flow control valve 167 When the exhaust pump 163 operates in a state in which the section between the exhaust pump 163 and the second gas flow control valve 167 communicates with the connection pipe 165 in the exhaust pipe 161, the gas supply pipe 164 passes through the exhaust pipe 161. Introduced external air is supplied to each of the plurality of gas dispensing dispersers 147 through the connection pipe 165 .

The water supply unit 170 supplies water necessary for wet manufacturing of the nonwoven fabric to the first dispersing device 110, the second dispersing device 120, and the web manufacturing device 140. The water supply unit 170 includes a city water supply unit 180 that supplies city water as water, and a water recycling unit 190 that recycles and supplies wastewater drained from the web manufacturing apparatus 140 by the drainage unit 150 as water. .

The city water supply unit 180 supplies the city water tank 181 in which city water is stored, and the city water stored in the city water tank 181 to the first dispersing device 110, the second dispersing device 120 and the web manufacturing device 140 A city water supply line 184 is provided.

The water tank 181 stores water for supplying to the first dispersing device 110, the second dispersing device 120, and the web manufacturing device 140. City water stored in the city water tank 181 is supplied to the first dispersion device 110, the second dispersion device 120 and the web manufacturing device 140 through the city water supply line 184 as needed.

The city water supply line 184 includes a city water supply main line 185 extending from the city water tank 181 and first, second, and third city water supply branch lines 186a and 186b branching off from the city water supply main line 185. , 186c). A city water supply pump 1851 is installed in the city water supply main line 185 . City water is supplied to the first dispersion device 110 through the first city water supply branch line 186a branched from the city water supply main line 185 . City water is supplied to the second dispersion device 120 through the second city water supply branch line 186b branched from the city water supply main line 185 . City water is supplied to the web manufacturing apparatus 140 through the third city water supply branch line 186c branched from the city water supply main line 185 .

The water recycling unit 190 is processed by the wastewater processing unit 191 and the wastewater processing unit 191 for recycling the wastewater drained by the drainage unit 150 from the web manufacturing apparatus 140, thereby enabling recycling. A first recycling water supply line 192 for supplying the water to the web manufacturing apparatus 140 for manufacturing a nonwoven web, and a first dispersing device for treating water treated by a wastewater treatment unit 191 to be recycled 110 and the second recycled water supply line 195 supplied to the second dispersing device 120, and the water treated by the wastewater treatment unit 191 to be recycled is installed in the web manufacturing device 140 A third recycled water supply line 199 supplied to a plurality of water sprayers 1424 and 1426 for cleaning the strainer 145 is provided.

The wastewater treatment unit 191 processes the wastewater drained from the web manufacturing apparatus 140 by the drainage unit 150 to be recycled. The wastewater treatment unit 191 includes a plurality of sedimentation tanks 191a, 191b, and 191c connected in series. Although three precipitation tanks 191a, 191b, and 191c are shown in the drawing, two or less or four or more precipitation tanks may be used, which also fall within the scope of the present invention. In this embodiment, water purified to the highest level in the settling tank 191c located at the most downstream is supplied to the web manufacturing apparatus 140 for manufacturing a nonwoven web through the first recycled water supply line 192, and in the middle Water purified to an intermediate level in the settling tank 191b is supplied to the first dispersing device 110 and the second dispersing device 120 through the second recycled water supply line 195, and the settling tank located at the most upstream level. The water purified to the lowest level in (191a) is a plurality of water injectors (1424, 1426) for cleaning the sieve 145 installed in the web manufacturing apparatus 140 through the third recycled water supply line 199. are supplied

Through the first recycled water supply line 192, the water treated by the wastewater treatment unit 191 and made recyclable is a water supply port to the web manufacturing apparatus 140 for manufacturing a nonwoven web (1433 in FIG. 2) supplied through A first recycled water supplying pump 193 is installed in the first recycled water supply line 192 . A third city water supply branch line 186c is connected to the first recycled water supply line 192 . A third water flow control valve 198c such as a three-way valve is installed at the point where the first recycled water supply line 192 and the third municipal water supply branch line 186c are connected, so that either recycled water or municipal water is selectively supplied. It can be supplied to the web manufacturing apparatus 140.

Through the second recycled water supply line 195 , water treated by the wastewater treatment unit 191 and made recyclable is supplied to the first dispersing device 110 and the second dispersing device 120 . The second recycled water supply line 195 includes a recycled water supply main line 196 and first and second recycled water supply branch lines 197a and 197b branching from the recycled water supply main line 196 . A second recycled water supply pump 1971 is installed in the recycled water main line 196 . Recycled water is supplied to the first dispersing device 110 through a first recycled water supply branch line 197a branched off from the recycled water supply main line 196 . Recycled water is supplied to the second dispersing device 120 through a second recycled water supply branch line 197b branched off from the recycled water supply main line 196 . A first city water supply branch line 186a is connected to the first recycled water supply branch line 197a. At the point where the first recycled water supply branch line 197a and the first city water supply branch line 186a are connected, a first water flow control valve 198a such as a three-way valve is installed so that either recycled water or city water is selectively selected. It can be supplied to the first dispersing device 110 as. A second city water supply branch line 186b is connected to the second recycled water supply branch line 197b. A second water flow control valve 198b such as a three-way valve is installed at the point where the second recycled water supply branch line 197b and the second city water supply branch line 186b are connected so that either recycled water or city water is selectively selected. It can be supplied to the second dispersing device 120 as.

A plurality of water jets ( 1424, 1426). A third recycled water supplying pump 1991 is installed in the third recycled water supply line 199 .

In this embodiment, it is described that the water recycling unit 190 supplies recycled water to all of the first dispersing device 110, the second dispersing device 120, and the web manufacturing device 140, but the present invention is not limited thereto. don't The water recycling unit 190 may be configured to supply recycled water to one or two selected from the first dispersing device 110, the second dispersing device 120 and the web manufacturing device 140, which is also of the present invention. that falls within the scope

In FIG. 3, a method for manufacturing a recycled nonwoven fabric using the wet recycled nonwoven fabric manufacturing system 100 shown in FIG. 1 is shown as a flow chart. The description of the recycled nonwoven fabric manufacturing method shown in FIG. 3 includes a description of the operation of the wet recycled nonwoven fabric manufacturing system 100 shown in FIG. Referring to FIG. 3, in the method for manufacturing recycled nonwoven fabric according to an embodiment of the present invention, a first waste nonwoven fabric prepared through a preliminary dispersion step (S10) of dispersing waste nonwoven fabric pieces in water, and a preliminary dispersion step (S10). The present dispersion step of additionally dispersing the waste nonwoven fabric pieces in the mixed solution (S20), and the fixative addition step of preparing a mixed raw material solution by adding a fixer to the second waste nonwoven fabric mixture prepared through the present dispersion step (S20) (S30). ), a water supply step of supplying water to the web manufacturing apparatus 140 to fill the water (S40), a raw material input step of introducing the mixed raw material solution into the water-filled web manufacturing apparatus 140 (S50), and web manufacturing Web manufacturing device 140 during a drainage step (S60) in which water is drained from the device 140 and a recycled nonwoven fabric laminate is formed on the sieve 145, and the raw material input step (S50) and the drainage step (S60) are performed After the additional dispersing step (S70) of dispersing the waste nonwoven fabric pieces included in the mixed raw material solution and the draining step (S60) are performed, a vacuum is formed inside the web manufacturing device 140 to dehydrate the recycled nonwoven fabric laminate and a vacuum dehydration step (S80).

In the preliminary dispersing step (S10), the waste nonwoven fabric pieces in a state of being entangled in water are dispersed by physical impact. The preliminary dispersing step is performed by the first dispersing device 110 . The first dispersing device 110 disperses the waste nonwoven fabric pieces in a tangled state in the water by hitting the waste nonwoven fabric pieces in the water with the rotary blade 115 to apply an impact. The preliminary dispersion step (S10) is sufficiently performed to prepare the first mixed solution of waste nonwoven fabric. The water used in the preliminary dispersion step (S10) is recycled water supplied from the water recycling unit 190, and may also include city water supplied from the city water supply unit 180, if necessary.

In this dispersing step (S20), the waste nonwoven fabric pieces are further dispersed in the first mixed solution of waste nonwoven fabric prepared through the preliminary dispersing step (S10). This dispersing step (S20) is performed by the second dispersing device 120. The second dispersing device 120 injects a dispersant into the mixed solution of the first waste nonwoven fabric and operates the agitator 125 to perform the main dispersion of the mixed solution of the first waste nonwoven fabric. This dispersing step (S20) is sufficiently performed to prepare the second waste nonwoven fabric mixture. The water used in this dispersing step (S20) is recycled water supplied from the water recycling unit 190, and may also include city water supplied from the city water supply unit 180, if necessary.

In the fixing agent addition step (S30), a mixed raw material solution is prepared by adding a fixer to the second waste nonwoven fabric mixture prepared in the dispersing step (S20). In the fixing agent addition step (S30), the fixing agent adding unit 130 is in the process of flowing the second waste nonwoven fabric mixture from the second dispersing device 120 to the web manufacturing device 140 through the second transfer line 127. It works and is done The fixative adding unit 130 supplies the fixative to the second transfer line 127 and adds the fixative to the second waste nonwoven fabric mixture flowing through the second transfer line 127 . The waste nonwoven fabric pieces included in the second mixed solution of waste nonwoven fabric may be structurally aggregated and bonded to each other by the fixative. The fixative may be a commonly used one such as polyvinyl acetate resin or sodium thiosulfate.

In the water supply step (S40), water is supplied to the web manufacturing apparatus 140 so that the inside of the web manufacturing apparatus 140 is filled with water (W) higher than the sieve 145 as shown in FIG. After the water supply step (S40) is performed, the raw material input step (S50) is performed. The water used in the water supply step (S40) is recycled water supplied from the water recycling unit 190, and may also include city water supplied from the city water supply unit 180, if necessary.

In the raw material input step (S50), the mixed raw material solution prepared through the fixer addition step (S30) is introduced into the web manufacturing apparatus 140 while the web manufacturing apparatus 140 is filled with water, as shown in FIG. 5 shows a state in which the mixed raw material solution (A) is introduced into the web manufacturing apparatus 140 through the raw material input step (S50). Referring to FIG. 5, the mixed raw material solution (A) is supplied to the upper space 1411 of the web manufacturing apparatus 140 through the water supply step (S40) and is present together with the filled water (W).

In the drainage step (S60), water is drained by gravity through the drain hole 1421 in the state of the web manufacturing apparatus 140 as shown in FIG. The draining step (S60) may be performed by the operation of an opening/closing valve (not shown) installed in the drain pipe 153. After the water of the web manufacturing apparatus 140 is completely gravity drained through the drainage step (S50), the web manufacturing apparatus 140, as shown in FIG. Water (B) remains. Even after the draining step (S60) is completed, water remains in the U-shaped pipe portion 154 of the drain pipe 153. The water drained from the web manufacturing apparatus 140 through the drainage step (S60) is supplied to the wastewater treatment unit 191 by the drainage unit 150 for recycling.

In the additional dispersion step (S70), the dispersion of the waste nonwoven fabric pieces included in the mixed raw material solution introduced into the web manufacturing apparatus 140 is performed. The additional dispersing step (S70) is performed together while the raw material inputting step (S50) and the draining step (S60) are performed, and is performed by operating a plurality of gas spray dispersers 147 and a plurality of ultrasonic dispersers 149. By performing the additional dispersion step (S70), the dispersion state of the waste nonwoven fabric pieces included in the mixed raw material solution injected into the web manufacturing apparatus 140 is stably maintained during the raw material input step (S50) and the drainage step (S60). It can be.

In the vacuum dewatering step (S80), after the draining step (S60) is performed, a vacuum is formed inside the web manufacturing apparatus 140 to dehydrate the recycled nonwoven fabric laminate (B). The vacuum dewatering step (S80) is performed by operating the exhaust pump 163. The lower space 1412 of the web manufacturing device 140 is sealed by the water remaining in the U-shaped pipe portion 154 of the recycled nonwoven fabric laminate B and the drain pipe 153 placed on the strainer 145, and the vacuum pump Air in the lower space 1412 is discharged to the outside through the exhaust pipe 161 by the operation of 163, so that the lower space 1412 forms a vacuum state. As a vacuum state is formed in the lower space 1412, moisture contained in the recycled nonwoven fabric laminate (B) is further removed.

100: Wet recycled non-woven fabric manufacturing system
110: first dispersion device
120: second dispersion device
130: fixative addition unit
140: web manufacturing device
150: drainage part
160: exhaust
170: water supply unit
180: city water supply unit
190: water recycling department
191: wastewater treatment unit
191a, 191b, 191c: sedimentation tank
1424, 1426: water sprayer

Claims (10)

a first dispersing device for dispersing the waste nonwoven fabric pieces by applying a physical impact to the waste nonwoven fabric pieces in water;
a second dispersing device for dispersing the waste nonwoven fabric pieces in the mixed solution of the first waste nonwoven fabric discharged from the first dispersing device using an agitator;
A web manufacturing device for manufacturing a nonwoven web by injecting a mixed raw material solution formed by adding a fixer to the second waste nonwoven fabric mixture discharged from the second dispersing device into water over a sieve and then draining the water therein;
Drainage unit for discharging water from the web manufacturing apparatus; and
It includes a water recycling unit for recycling wastewater discharged from the web manufacturing apparatus by the drainage unit,
The water recycling unit treats the wastewater and supplies it as water to at least one of the first dispersing device, the second dispersing device and the web manufacturing device,
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 1,
The water recycling unit comprising a wastewater treatment unit for treating wastewater drained from the web manufacturing apparatus,
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 2,
The wastewater treatment unit having a plurality of sedimentation tanks connected in series
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 2,
The water recycling unit treats the wastewater and supplies it as water for the first dispersing device, the second dispersing device, and the web manufacturing device,
The water supplied from the wastewater treatment unit to the web manufacturing device is water purified to a relatively higher level than the water supplied to the first dispersing device and the second dispersing device.
Wet Recycled Nonwoven Manufacturing System. The method of claim 4,
The water recycling unit supplies the first recycled water supply line for supplying the water treated in the wastewater treatment unit to the web manufacturing device, and the water treated in the wastewater treatment unit to the first dispersing device and the second dispersing device. 2 equipped with a recycled water supply line,
The second recycled water supply line is a recycled water supply main line extending from the wastewater treatment unit, and a first recycled water supply branched from the recycled water supply main line and connected to the first dispersing device and the second dispersing device, respectively. Having a branch line and a second recycled water supply branch line,
Wet Recycled Nonwoven Manufacturing System. The method of claim 5,
Further comprising a time water supply unit for supplying time water as water to the first dispersing device, the second dispersing device, and the web manufacturing device,
The city water supply unit includes a city water tank in which city water is stored, a city water supply main line extending from the city water tank, and branching off from the city water supply main line, the first recycled water supply branch line, the second recycled water supply branch line, and Having a first city water supply branch line, a second city water supply branch line, and a third city water supply branch line connected to the first recycled water supply line, respectively,
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 6,
A first water flow control valve installed at a connection point between the first recycled water supply branch line and the first city water supply branch line and operated to selectively supply either recycled water or city water to the first dispersing device;
A second water flow control valve installed at a connection point between the second recycled water supply branch line and the second city water supply branch line and operated to selectively supply either recycled water or city water to the second dispersing device;
A third water flow control valve installed at the connection point of the first recycled water supply line and the third water supply branch line and operating so that either recycled water or city water is selectively supplied to the web manufacturing apparatus Further comprising ,
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 1,
Further comprising a water sprayer installed in the web manufacturing apparatus to spray water to the sieve to clean the sieve,
The water sprayer receives water from the water recycling unit,
Wet Recycled Nonwoven Fabric Manufacturing System. The method of claim 9,
The water sprayer is disposed below the sieve to spray water upward toward the sieve.
Wet Recycled Nonwoven Fabric Manufacturing System. Water is supplied to the inner space of the web manufacturing apparatus having a housing providing an inner space and a sieve installed horizontally in the inner space to divide the inner space into an upper space and a lower space, thereby supplying water to the inner space. Water supply step of forming a water level higher than the sieve;
a raw material input step of injecting a mixed raw material solution formed by adding waste nonwoven fabric pieces and a fixer to water into the upper space;
A drainage step of draining water from the lower space to form a recycled nonwoven fabric laminate on the sieve; and
And a vacuum dehydration step of dehydrating the recycled nonwoven fabric laminate by discharging gas in the lower space so that a vacuum is formed in the lower space,
The water supply step is performed by purifying the water drained in the drain step and then supplying it to the inner space.
Method for manufacturing wet recycled nonwoven fabric.

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