KR102420613B1 - Assembly type water purification system - Google Patents

Abstract

The present invention aims to provide a prefabricated water treatment system. According to the present invention, the prefabricated water treatment system comprises: a filtering module (110) filtering water; a distribution module (130) distributing the water filtered through the filtering module (110) to a water culture facility; and an engagement unit detachably engaging the filtering module (110) with the distribution module (130). The filtering module (110) includes a filtering box body (112) having an inlet (113) through which water is introduced, and an outlet (114) through which water is discharged. The filtering box body (112) includes a built-in filter cartridge (120) for filtering the water introduced through the inlet (113) and supplying the water to the distribution module (130) through the outlet (114) of the filtering box body (112). The filter cartridge (120) includes: a filter frame (122); and a filter (125) detachably engaged with the filter frame (122). As the filter cartridge (120) is built in the filtering box body (112), the water filtered through the filter (125) is supplied to the distribution module (130) through the outlet (114) of the filtering box body (112). The present invention is able to be installed in water culture facilities, such as a pool in a playground or a park or a water park, just by a simple assembly process, allow the efficient filtering of water in various water culture facilities, lower the cost for replacement to reduce the maintenance cost, and address difficulties in operation.

Description

Assembly type water purification system

The present invention relates to an assembled water treatment system, and more particularly, to an assembled water treatment system that enables efficient filtration in various hydroponic facilities only by simple assembly.

In general, various play facilities are installed in playgrounds, parks, and school grounds where infants and children play. For example, in a children's playground where children can play, various play facilities such as swings, slides, and seesaws are provided.

On the other hand, recently, by transforming play facilities, play facilities are being developed so that children can develop physical strength and perceptual abilities in a variety of ways while having more curiosity. A lot of structures have been developed and installed to make them more interesting while playing in the water. In addition, these pool play facilities are gradually becoming larger, and there is a trend of developing into a water park (water amusement park) that can be enjoyed by anyone of any age or gender.

In addition to the water supply post that supplies water, various sculptures are installed in the water play facility. In particular, in amusement facilities, posts are often installed in a vertical direction to make a play structure with the same structure as a general play sculpture in a playground. It's interesting and fun to play.

Pools, park pools, water parks, etc. of these children's play facilities can be called hydroponic facilities.

However, although the installation of a filtration device for the existing hydroponic facilities and the installation of a filtration device for a new water park is inevitable, the efficiency of the filter is reduced due to contaminants and the maintenance cost increases due to the high replacement cost, making it difficult to operate There is this.

Korean Patent Registration No. 10-1334693 (Registered on November 25, 2013) Korean Patent Registration No. 10-2109693 (Registered on May 06, 2020) Korean Patent Publication No. 10-2021-0109322 (published on September 06, 2021) Korea Patent No. 10-1894277 (registered on August 28, 2018)

The present invention has been developed to solve the problems described above, and an object of the present invention is to be installed in a hydroponic facility such as a playground, a park pool, or a water park with simple assembly so that efficient filtration in various hydroponic facilities is made. It is intended to provide a prefabricated water treatment system.

According to the present invention for solving the above problems, the filtration module 110 for filtering water; a distribution module 130 for distributing the water filtered by the filtration module 110 to a hydroponic facility; and a coupling unit for allowing the distribution module 130 to be detachably coupled to the filtration module 110, wherein the filtration module 110 includes an inlet 113 through which water is introduced and an outlet for discharging water. A filtration box body 112 having a 114; is provided, and the filter box body 112 filters the water entering the inlet 113 to provide the outlet 114 of the filtration box body 112. A filter cartridge 120 through which water is supplied to the distribution module 130; provided with an assembled water treatment system characterized in that it is built-in.

The filter cartridge 120 includes a filter frame 122; It includes a filter 125 detachably coupled to the filter frame 122, wherein the filter cartridge 120 is built in the filtration box body 112 and the water filtered through the filter 125 is the It is characterized in that it is configured to be supplied to the distribution module 130 through the outlet 114 of the filtration box body 112 .

A plurality of filters 125 are erected and coupled to the filter frame 122 , and the inlet 113 formed in the filter box 112 is the innermost core between the two core filters 125CFL facing each other. Water entering the filtering space and filtered through the two core filters 125CFL is sequentially filtered through the other side filters 125SFL, so that the water entering the inlet 113 of the filtration box 112 is transferred to the core filter. It is characterized in that it is configured to be supplied to the distribution module 130 through the outlet 114 of the filtration box body 112 after being filtered several times by the (125CFL) and the side filter (125SFL).

In the filter cartridge 120 , the flow hole 128FH passing through the upper and lower surfaces communicates with the distribution chamber 136 inside the distribution module 130 . A coupling support frame 128CS that is detachably coupled to the lower end and supports and supports the filter frame 122 from below, and a pair of cores extending in the vertical direction of the filter frame 122 to face each other A set of core filter coupling support pieces composed of a filter coupling support piece 123 and a pair of side filters extending in the vertical direction of the filter frame 122 at an outer position of the pair of filter coupling support pieces set A side filter (125SFL) coupling support piece set comprising a (125SFL) coupling support piece 124, and a pair of the core filter coupling support pieces 123 of the core filter coupling support piece set, the periphery is coupled to the filter box A pair of side-by-side core filters 125CFL forming a core filtering chamber 125CCH communicating with the inlet 113 of the filtering box body 112 inside the sieve 112, and the side filter 125SFL coupling support A periphery is coupled to the pair of side filter (125SFL) coupling support pieces 124 of a piece set to form a side filtering chamber 126SCH between the filter box body 112 and the filter box body 112 . A pair of side-by-side side filters (125SFL) forming a discharge chamber (127DCH) are included between the inner surface and the discharge chamber (112) formed between the side filter (125SFL) and the filter box body (112) 127DCH) is in communication with the distribution chamber 136 formed inside the distribution box body 132 of the distribution module 130, and the filtration module 110 is the water introduced into the inlet 113 of the filter box body 112. enters the core filtering chamber 125CCH between the pair of opposing core filters 125CFL and passes through the pair of opposing core filters 125CFL. In the filtered state, water entering the side filtering chamber 126SCH and entering the side filtering chamber 126SCH is filtered while passing through a pair of side-by-side side filters 125SFL, and the side filter 125SFL. The water that has passed through enters the discharge chamber 127DCH and is configured to be supplied to the distribution chamber 136 formed in the distribution box body 132 of the distribution module 130 .

The distribution module 130 includes a distribution box body 132 having a space therein; at least two or more distribution chambers 136 partitioned by a diaphragm 134 in the interior of the distribution box body 132; It is characterized in that the connector is communicated.

The distribution box body 132 is provided with a distribution hole 135 communicating with the distribution chamber 136 , a flange is provided around the distribution hole 135 , and a pipe side flange is provided on the distribution connection pipe. It is characterized in that the distribution chamber 136 of the distribution module 130 is connected to a hydroponic facility by connecting the flange and the pipe side flange with a bolt 128BT and a nut through the distribution connection pipe.

The coupling unit is detachably attached to the lower end of the filtration box body 112 of the filtration module 110 so that the flow hole 128FH penetrated through the upper and lower surfaces communicates with the distribution chamber 136 inside the distribution module 130 . A locking having a coupling support frame 128CS that is operably coupled and supports and supports the filter frame 122 from below, and a pair of locking bar insertion holes provided on the lower surface of the coupling support frame 128CS and facing each other. Channel 128LCH, a separation operation lever insertion hole formed in the locking channel 128LCH and disposed in a direction perpendicular to the locking bar insertion hole, and the distribution box body 132 of the distribution module 130 before and after The lower end of the filtration box body 112 of the filtration module 110 is inserted into the locking channel 128LCH through the locking bar insertion hole of the locking channel 128LCH. A pair of locking bars 128LB supporting the distribution box body 132 of the distribution module 130 to be coupled thereto, and the pair of locking bars 128LB and the distribution box body 132 are connected between the A locking elastic body 128EL that pushes the pair of locking bars 128LB to be inserted into the locking channel 128LCH, and is coupled to the distribution box body 132 so as to be reversible and a front end portion is the locking channel 128LCH. A separation operation lever 128DL coupled to the separation operation lever insertion hole formed in the separation operation lever 128DL and a pair of locking bars provided at the periphery of the distal end of the separation operation lever 128DL to pull the separation operation lever 128DL (128LB) to the outside of the locking channel (128LCH) by pushing the locking channel (128LCH) a pair of locking bars (128LB) to release the locking state coupled to that comprising a detachable piece (128DP) characterized.

An end filter 142 is further provided inside the distribution box body 132 of the distribution module 130, and the end filter 142 for water entering through the flow hole 128FH of the coupling support frame 128CS. ) is finally configured to filter.

The coupling unit is detachably coupled to the lower end of the filtration box body 112 of the filtration module 110 and is disposed under the coupling support frame 128CS and penetrates through the upper and lower surfaces of the auxiliary flow holes 128SFH. ) is the coupling support frame (128CS) and the flow hole and the auxiliary coupling support frame (128SCS) in communication with the distribution chamber 136 inside the distribution box body 132 of the distribution module 130, and the auxiliary coupling support frame (128SCS) provided on the lower surface of the auxiliary locking channel (128SLCH) having a pair of auxiliary locking bar insertion holes facing each other and the distribution box body 132 of the distribution module 130 is coupled so as to be able to move back and forth A pair of auxiliary locking bars (128SLB) disposed to face each other, and a pair of auxiliary locking bars (128SLB) provided at the front ends of the pair of auxiliary locking bars (128SLB) to stand up in a direction facing each other It is provided on a piece 128SLDP and a pair of the auxiliary locking detachable movable pieces 128SLDP and is inserted into the auxiliary locking channel 128SLCH through the auxiliary locking bar insertion hole of the auxiliary locking channel 128SLCH to be inserted into the filtration module A pair of auxiliary locking blocks (128SLCB) supporting the distribution box body 132 of the distribution module 130 to be coupled to the lower end of the filtering box body 112 of 110, and a pair of auxiliary locking bars ( 128SLB) and the distribution box body 132 to push the pair of auxiliary locking bars 128SLB to advance toward the auxiliary locking channel 128SLCH, so that the pair of auxiliary locking blocks 128SLCB is connected to the auxiliary locking channel 128SLCH. An auxiliary locking elastic body 128SEL which is pushed to be inserted into the locking channel 128SLCH, is rotatably coupled to the distribution box body 132, and the distal end is provided in the pair of auxiliary locking bars 128SLB. A separation pivot lever 128DCL disposed between a pair of the auxiliary locking blocks 128SLCB, and the It is provided at the front end of the separation rotation lever 128DCL and is in contact with the pair of auxiliary locking separation movable pieces 128SLDP provided on the pair of auxiliary locking bars 128SLB to rotate the separation rotation lever 128DCL. Accordingly, a pair of auxiliary locking blocks 128SLCB and a pair of auxiliary locking detachable movable pieces 128SLDP and a pair of auxiliary locking bars 128SLB are pushed out of the auxiliary locking channel 128SLCH to fall out of the auxiliary locking channel 128SLCH. A pair of auxiliary locking bars (128SLB) to the locking channel (128SLCH) is characterized in that it further comprises a rotation separation piece (128CDP) for releasing the coupled locking state.

An end filter 142 is further provided inside the distribution box body 132 of the distribution module 130, and the water entering through the auxiliary flow hole 128SFH of the auxiliary coupling support frame 128SCS is filtered through the end filter. (142) is finally configured to filter.

The prefabricated water treatment system of the present invention is installed in a hydroponic facility such as a playground, a park pool, or a water park only by simple assembly, so that efficient filtration is achieved in various hydroponic facilities.

In addition, the present invention is formed so that the filtration module for filtering water and the distribution module for distributing water can be assembled in a prefabricated manner, thereby increasing the filtration efficiency of water in the hydroponic facility and reducing the replacement cost while reducing the maintenance cost, It is effective in resolving difficult problems.

1 is a side view of an assembled water treatment system according to the present invention;
2 is a side view showing a distribution hole of a distribution module, which is a main part of the present invention;
3 is a plan view of a filter cartridge embedded in a filtration module of the assembled water treatment system shown in FIG. 1;
Figure 4 is a side view schematically showing the process of coupling the filter to the filter frame of the filter cartridge shown in Figure 3;
5 is a bottom view of the filtration module shown in FIG. 1;
6 is a plan view of the distribution module shown in FIG. 1;
7 is a side cross-sectional view showing the structure of an assembled water treatment system according to the present invention;
8 is a side cross-sectional view showing an exploded state of the filtration module and the distribution module, which are the main parts shown in FIG. 7;
9 is a plan view showing the structure of a coupling unit, which is a main part of an assembled water treatment system according to another embodiment of the present invention;
10 is a side cross-sectional view showing the structure of an assembled water treatment system according to another embodiment of the present invention;
11 is a plan view showing the operating state of the main part of the coupling unit when separating the distribution module from the filtration module of another embodiment of the present invention;
12 is a side cross-sectional view showing the operating state of the main part of the coupling unit when the distribution module is separated from the filtration module of another embodiment of the present invention;
13 is a side cross-sectional view showing a state in which the distribution module is separated by the operation of the coupling unit in the filtration module of another embodiment of the present invention;
14 is a plan view showing an auxiliary locking channel, an auxiliary locking bar, an auxiliary locking elastic body, and a separation rotation lever constituting a coupling unit, which is a main part of an assembled water treatment system according to another embodiment of the present invention;
15 is a side cross-sectional view showing an auxiliary locking channel, an auxiliary locking bar, an auxiliary locking elastic body, and a separation rotation lever constituting a coupling unit, which is a main part of an assembled water treatment system according to another embodiment of the present invention;
16 is a plan view showing the operation state of the auxiliary locking channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation rotation lever, which are main parts when the distribution module is separated from the filtration module of another embodiment of the present invention;
17 is a side cross-sectional view showing the operating state of the main part of the coupling unit, the auxiliary locking channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation rotation lever when separating the distribution module from the filtration module of another embodiment of the present invention;
18 is a side cross-sectional view showing a state in which the distribution module is separated by the operation of the coupling unit, the auxiliary locking channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation rotation lever in the filtration module according to another embodiment of the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. The objects, features and advantages of the present invention will be more readily understood by referring to the accompanying drawings and the following detailed description. In the drawings, the same reference numbers are used for the same parts. In addition, in describing the present invention, if it is determined that a detailed description of a related known configuration or function may obscure the gist of the present invention, the detailed description thereof will be omitted.

In addition, in describing the components of the present invention, terms such as first, second, A, B, (a), (b), etc. may be used. These terms are only for distinguishing the elements from other elements, and the essence, order, or order of the elements are not limited by the terms. When it is described that a component is “connected”, “coupled” or “connected” to another component, the component may be directly connected or connected to the other component, but between each component another component It will be understood that may also be "connected", "coupled" or "connected".

1 is a side view of an assembled water treatment system according to the present invention, FIG. 2 is a side view showing a distribution hole of a distribution module which is a main part of the present invention, and FIG. 3 is a filter built into the filtration module of the assembled water treatment system shown in FIG. A plan view of the cartridge, FIG. 4 is a side view schematically showing a process of coupling the filter to the filter frame of the filter cartridge shown in FIG. 3 , FIG. 5 is a bottom view of the filtration module shown in FIG. 1 , FIG. 6 is shown in FIG. 7 is a side cross-sectional view showing the structure of an assembled water treatment system according to the present invention, and FIG. is a plan view showing the structure of a coupling unit that is a main part of an assembled water treatment system according to another embodiment of the present invention, FIG. 10 is a side cross-sectional view showing the structure of an assembled water treatment system according to another embodiment of the present invention, and FIG. A plan view showing the operating state of the coupling unit, which is a main part, when separating the distribution module from the filtration module of another embodiment of the present invention. 13 is a side cross-sectional view showing a state in which the distribution module is separated by the operation of the coupling unit from the filtration module of another embodiment of the present invention, and FIG. 14 is an assembled water treatment system according to another embodiment of the present invention A plan view showing the auxiliary locking channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation rotation lever constituting the main part of the coupling unit, FIG. 15 is an auxiliary constituting the coupling unit which is the main part of the assembled water treatment system according to another embodiment of the present invention. A side cross-sectional view showing the locking channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation pivot lever, FIG. 16 is the auxiliary locking channel, the auxiliary locking bar, and the auxiliary locking elastic body, which are main parts when the distribution module is separated from the filtration module of another embodiment of the present invention and a plan view showing the operating state of the separation rotation lever, FIG. 17 is a main part of the coupling when separating the distribution module from the filtration module of another embodiment of the present invention A side cross-sectional view showing the operation state of the unit and the operation state of the auxiliary locking channel, the auxiliary locking bar, the auxiliary locking elastic body and the separation rotation lever, FIG. 18 is the operation and auxiliary locking of the unit combining the distribution module in the filtration module of another embodiment of the present invention It is a side cross-sectional view showing a state in which the channel, the auxiliary locking bar, the auxiliary locking elastic body, and the separation rotation lever are separated by the operation.

Referring to the drawings, the assembled water treatment system according to the present invention includes a filtration module 110 for filtering water, a distribution module 130 for distributing water filtered by the filtration module 110 to a hydroponic facility, and the filtration It includes a coupling unit that allows the distribution module 130 to be detachably coupled to the module 110 .

The filtration module 110 includes a filtration box body 112 and a filter cartridge 120 .

The filtration box body 112 has an inlet 113 through which water is introduced and an outlet 114 through which water is discharged. The inlet 113 is provided in the upper portion of the filtration box body 112 and the outlet 114 is provided in the lower portion of the filtration box body 112 . The filtering box body 112 is provided with a space therein, and the space communicates with the inlet 113 and the outlet 114 . The filter box body 112 is configured in the shape of a hexahedral box having an inlet 113 at the lower end, an inner space, and an outlet 114 at the lower end.

The filter box body 112 has an upper cover plate 115 disposed at the upper end, and the upper cover plate 115 is detachably coupled to the lower end of the filtering box body 112 by a fastener such as a bolt, and the An inlet 113 is provided in the upper cover plate 115 . As water flows in through the inlet 113 of the upper cover plate 112UP, water flows into the inlet of the filtration module 110 . The filtration module 110 can be said to have a structure including a filtration box body 112 and an upper cover plate 115 .

The filter cartridge 120 is embedded in the filter box body 112 . The coupling support frame 128CS provided in the lower part of the filter cartridge 120 is detachably coupled to the lower end of the filter box body 112 by a fastener such as a bolt 128BT, and the filter cartridge 120 is filtered. It is built into the box body 112 . The filter cartridge 120 filters the water entering the inlet 113 so that the filtered water is supplied to the distribution module 130 through the outlet 114 of the filter box body 112 .

The filter cartridge 120 includes a filter frame 122 and a filter 125 .

The filter frame 122 is configured in a shape in which a frame post is connected to an upper frame part and a lower frame part in parallel. Since the filter box body 112 is configured in a hexahedral box shape, the filter frame 122 is also configured in a hexahedral frame shape. The upper frame part and the lower frame part are configured in a rectangular frame shape, and the upper and lower ends of the frame post are connected to the four corners of the upper frame part and the lower frame part, respectively, so that the filter frame 122 is configured in a hexahedral frame shape. The upper frame portion of the filter frame 122 is provided with a frame side inlet hole, and the lower frame portion of the filter frame 122 is configured with a frame side discharge hole.

The filter 125 is detachably coupled to the filter frame 122 . The filter cartridge 120 including the filter frame 122 and the filter 125 is built in the filter box body 112 , and the water filtered through the filter 125 is discharged through the outlet 114 of the filter box body 112 . ) through the distribution module 130 is configured to be supplied.

A plurality of filters 125 are erected and coupled to the filter frame 122 . In the filter frame 122, the two core filters 125CFL facing each other are coupled to each other, and the side filters 125SFL are disposed so as to be disposed on the sides of the two core filters 125CFL at the same time. By being coupled to the filtration box body 112, the inlet 113 formed in the filtration box body 112 enters the innermost core filtering space between the two core filters 125CFL facing each other and is filtered through the two core filters 125CFL. As the filtered water is sequentially filtered through another side filter 125SFL, the water entering the inlet 113 of the filtration box 112 is filtered several times by the core filter 125CFL and the side filter 125SFL. is supplied to the distribution module 130 through the outlet 114 of the filtration box body 112 .

The distribution module 130 includes a distribution box body 132 having a space therein, and at least two or more distribution chambers 136 partitioned by a diaphragm 134 inside the distribution box body 132 . It is configured, and at least two or more of the distribution chambers 136 communicate with a distribution connector connected to a hydroponic facility.

The distribution box body 132 is provided with a distribution inlet hole 133 , and the distribution inlet hole 133 communicates with the distribution chamber 136 . Water filtered through the filter cartridge 120 passes through the distribution inlet hole 133 into the distribution chamber 136 . The distribution box body 132 is provided with a distribution hole 135 communicating with the distribution chamber 136 . The distribution hole 135 communicates with the side of the distribution box body 132 . A flange is provided around the distribution hole 135, and a pipe side flange is provided on the distribution connection pipe, and the flange and the pipe side flange are connected by a bolt 128BT and a nut through the distribution connection pipe. The distribution chamber 136 of the distribution module 130 is connected to the hydroponic facility.

The filter cartridge 120 includes a core filter coupling support piece set consisting of a coupling support frame 128CS and a pair of core filter coupling support pieces 123, a side filter coupling support piece set and a pair of side by side filter coupling support pieces set. (125CFL) and a pair of side-by-side side filters (125SFL). In the present invention, the filter 125 includes a core filter 125CFL and a side filter 125SFL.

The coupling support frame 128CS is detachably coupled to the lower end of the filtration box body 112 constituting the filtration module 110 by a fastener such as a bolt 128BT. The coupling support frame 128CS has a flow hole 128FH that penetrates through the upper and lower surfaces. The combined support frame 128CS supports and supports the filter frame 122 from below. A fastener such as a bolt 128BT is coupled to the fixed coupling piece formed in the lower frame portion of the filter frame 122 and the coupling support frame 128CS, so that the coupling support frame 128CS is provided at the lower portion of the filter frame 122. By being coupled, it becomes a structure that supports and supports the filter frame 122 from below on the combined support frame 128CS. The flow hole 128FH of the coupling support frame 128CS communicates with the distribution chamber 136 inside the distribution module 130 . In other words, the coupling support frame 128CS is detachably coupled to the lower end of the filtering box body 112 by a fastener such as a bolt, and the filter cartridge 120 is mounted on the coupling support frame 128CS and is supported. . That is, the coupling support frame 128CS coupled to the lower portion of the filter box body 112 supports the filter cartridge 120 from below when the filter cartridge 120 is built into the inner space of the filtering box body 112 . will function. The coupling support frame 128CS is formed in a plate shape, and a flow hole 128FH communicating from an upper surface to a lower surface is formed in the coupling support frame 128CS, and the distribution module 130 through the flow hole 128FH. Let water in.

The set of core filter coupling support pieces includes a pair of core filter coupling support pieces 123 that extend in the vertical direction of the filter frame 122 and are disposed to face each other. The core filter coupling support piece 123 is configured in a shape of a digutja channel with an open inner end facing each other, and the core filter (125CFL) is disposed in the core coupling slit of a pair of core filter coupling support pieces 123 facing each other. By inserting a pair of side by side peripheral portions, the core filter 125CFL is placed upright on the filter frame 122 by a set of core filter coupling support pieces. In a state in which the filter frame 122 and the core filter 125CFL facing each other are embedded in the space inside the filtration box 112 of the filtration module 110, a core filtering chamber formed between the two core filters 125CFL. (125CCH) communicates with the inlet 113 of the filtering box body 112, so that water entering the inlet 113 flows into the core filtering chamber 125CCH between the two core filters 125CFL.

The side filter (125SFL) coupling support piece set includes a pair of side filter (125SFL) coupling support pieces 124 extending in the vertical direction of the filter frame 122 to face each other. A pair of side filter (125SFL) coupling support piece 124 is provided in the filter frame 122 so as to be disposed outside the core filter coupling support piece 123 . The side filter (125SFL) coupling support piece 124 is also configured in the shape of a diverter channel with an open inner end facing each other, and a pair of side filter (125SFL) coupling support pieces are parallel to each other from the outside of the filter 125 coupling support piece. By inserting a pair of side-by-side peripheral portions of the side filter (125SFL) into the side coupling slit of 124, the side filter (125SFL) is erected on the filter frame 122 by the side filter (125SFL) coupling support piece set. are placed Two side filtering chambers 126SCH are formed between the two core filters 125CFL and the two side filters 125SFL.

That is, the filter cartridge 120 has a peripheral portion coupled to a pair of core filter coupling support pieces 123 of the set of core filter coupling support pieces, so that the inlet of the filter box body 112 inside the filter box body 112 ( A pair of side-by-side core filters (125CFL) forming a core filtering chamber (125CCH) in communication with 113), and the filter cartridge 120 are a pair of side filters (125SFL) of a side filter (125SFL) coupling support piece set The periphery is coupled to the coupling support piece 124 to form a side filtering chamber 126SCH between the filter box body 112 and the discharge chamber 127DCH between the inner surface of the filtering box body 112 and the filter box body 112 . and a pair of side-by-side side filters (125SFL).

A state in which the filter frame 122 and the pair of core filters 125CFL facing each other and at least one pair of side filters 125SFL in parallel are embedded in the space inside the filtration box body 112 of the filtration module 110 In this case, the core filtering chamber 125CCH formed between the two core filters 125CFL communicates with the inlet 113 of the filtration box 112, and the water entering the inlet 113 flows into the two core filters 125CFL. It flows into the core filtering chamber (125CCH) between the two core filters (125CFL) and the two side filtering chambers (126SCH) secured between the two side filters (125SFL) pass through the two core filters (125CFL). After the filtered water enters, it passes through the side filtering chambers 126SCH parallel to each other, and the filtered water passes through the side filters 125SFL that are parallel to each other. At least two flow holes formed in the coupling support frame 128CS It passes through 128FH and flows into the distribution chamber 136 inside the distribution box body 132 constituting the distribution module 130 .

The discharge chamber 127DCH formed between the side filter 125SFL and the filter box body 112 communicates with the distribution chamber 136 formed inside the distribution box body 132 of the distribution module 130, and the filter module (110) The water entering the inlet 113 of the filtration box body 112 enters the core filtering chamber (125CCH) between the pair of opposing core filters (125CFL), the pair of opposing core filters (125CFL) Water entering the side filtering chamber 126SCH in a filtered state while passing through the side filtering chamber 126SCH is filtered while passing through a pair of side-by-side side filters 125SFL, and the side filter 125SFL ), the water that has passed through enters the discharge chamber 127DCH and is supplied to the distribution chamber 136 formed inside the distribution box body 132 of the distribution module 130, and as a result, water is It is filtered and supplied to the distribution chamber 136 inside the distribution box body 132 forming the distribution module 130 .

At this time, a distribution hole 135 is provided in each distribution chamber 136 of the distribution box body 132 , and a distribution pipe is connected to the distribution hole 135 , so that the core filter 125CFL and the side filter 125SFL are provided. ), the filtered water several times can be supplied to the hydroponic facility through the distribution pipe. By the assembled water treatment system of the present invention, it is possible to supply water filtered by the filter 125 to the hydroponic facility.

Therefore, the assembly type water treatment system according to the present invention is installed in a hydroponic facility such as a playground, a park pool, or a water park only by simple assembly, and has the effect of making efficient filtration in various hydroponic facilities.

In addition, according to the present invention, the filtration module 110 for filtering water and the distribution module 130 for distributing water are formed so that they can be assembled in a prefabricated manner, so that the filtration efficiency of water in a hydroponic facility is increased while the replacement cost is low. It is effective in reducing costs and solving problems that are difficult to operate.

In the present invention, the coupling unit includes a fastener such as a bolt 128BT for coupling the coupling support frame 128CS for supporting the filter cartridge 120 from below to the lower end of the filtering box body 112 of the filtration module 110, and the It is composed of a fastener for coupling the distribution module 130 such as another bolt 128BT coupled from the lower portion of the distribution box body 132 of the distribution module 130 .

Accordingly, the filter cartridge 120 in which the filter frame 122, the core filter 125CFL, and the side filter 125SFL are combined is supported by a coupling support frame 128CS, and the coupling support frame 128CS is bolted. (128BT) is detachably coupled to the lower end of the filtration box body 112 of the filtration module 110 by a fastener such as 128BT, while coupled from the lower surface of the distribution box body 132 of the distribution module 130 By coupling another distribution module 130 coupling fastener such as a bolt 128BT to the filtering box body 112, the filtering module 110 and the distribution module 130 can be detachably coupled, and the The distribution module 130 can be separated from the filtration module 110 by loosening the fastener for coupling the distribution module 130 , and coupled with the filter cartridge 120 by loosening the fastener fixing the coupling support frame 128CS Since the support frame 128CS can be separated from the filtration module 110 together, the water filtration efficiency of the hydroponic facility is increased while the replacement cost is reduced, thereby reducing the maintenance cost and solving the problem of difficulties in operation there will be

On the other hand, in the coupling unit in another embodiment of the present invention, the flow hole 128FH through the upper and lower surfaces is the discharge chamber 127DCH of the filtration module 110 and the distribution chamber 136 inside the distribution module 130 . ) in communication with the coupling support frame 128CS that is detachably coupled to the lower end of the filtration box body 112 of the filtration module 110 and supports and supports the filter frame 122 from below, and the coupling support frame ( 128CS) provided on the lower surface of the locking channel 128LCH having a pair of locking bar insertion holes facing each other, and a separation formed in the locking channel 128LCH and disposed in a direction perpendicular to the locking bar insertion hole The operation lever insertion hole and the distribution box body 132 of the distribution module 130 are coupled to the front and rear ends to face each other, and the locking channel 128LCH through the locking bar insertion hole of the locking channel 128LCH. A pair of locking bars 128LB and a pair of locking bars that are inserted into and support the distribution box body 132 of the distribution module 130 to be coupled to the lower end of the filter box body 112 of the filtration module 110 A locking elastic body 128EL connected between the 128LB and the distribution box body 132 to push the pair of locking bars 128LB to be inserted into the locking channel 128LCH, and the distribution box body 132 moves forward and backward. The separation operation lever 128DL coupled to the distal end portion of the separation operation lever insertion hole formed in the locking channel 128LCH and the separation operation lever 128DL are provided on the periphery of the distal end side of the separation operation lever 128DL. ), a pair of locking bars (128LB) is pushed out of the locking channel (128LCH) to fall out of the locking channel (128LCH) to release the locking state in which the pair of locking bars (128LB) are coupled to the locking channel (128LCH). 128DP).

The locking channel 128LCH is provided in the center of the lower surface of the coupling support frame 128CS. The locking channel 128LCH has a pair of locking bar insertion holes facing each other on two circumferential surfaces facing each other among the four circumferential surfaces. In addition, in the locking channel 128LCH, a separation operation lever insertion hole is formed in a circumferential surface orthogonal to the two circumferential surfaces facing each other.

In addition, a pair of locking bar (128LB) operation holes facing the pair of locking bar insertion holes are provided in the distribution box body 132 of the distribution module 130 to move to the locking bar 128LB operation hole. A pair of possibly coupled locking bars 128LB passes through the locking bar insertion hole of the locking channel 128LCH coupled to the filtering box body 112 of the filtering module 110 to enter the locking channel 128LCH. configured to do so.

In addition, the distribution box body 132 of the distribution module 130 is provided with a separation operation lever 128DL operation hole in the other peripheral portion orthogonal to the peripheral portion formed with a pair of locking bar insertion holes, the separation operation lever (128DL) The separation operation lever 128DL movably coupled to the operation hole is configured to pass through the separation operation lever insertion hole of the locking channel 128LCH and enter between the front ends of the pair of locking bars 128LB.

According to another embodiment of the present invention, in the state in which the distribution module 130 is coupled to the filtration module 110, the pair of locking bars 128LB is supported by a pair of locking elastic bodies 128EL, and the coupling Since the front end of the pair of locking bars 128LB enters and is coupled to the locking channel 128LCH provided in the support frame 128CS, the locking channel 128LCH of the pair of locking bars 128LB and the combined support frame 128CS ), the distribution box body 132 of the distribution module 130 is maintained in a coupled state to the lower end of the filter box body 112 of the filtration module 110 by the combination. That is, the distribution module 130 is maintained in a coupled state to the filtration module 110 .

On the other hand, when the separation operation lever 128DL is pulled out from the circumference of the distribution box body 132 in a state where the distribution module 130 is coupled to the lower portion of the filtration module 110, the separation operation lever 128DL is The separating piece 128DP provided on the periphery of the front end of the pair of locking bars 128LB enters between the distal ends. When the 128DP) enters the tip of the pair of locking bars 128LB, the pair of locking bars 128LB is pushed to fall out of the locking channel 128LCH provided in the coupling support frame 128CS, Since the locking bar 128LB and the coupling support frame 128CS release the coupling state of the locking channel 128LCH, the distribution box body 132 can be separated from the filtering box body 112 . That is, the distribution module 130 can be separated from the filtration module 110 .

At this time, a lever elastic body 128LEL is coupled to the periphery of the separating operation lever 128DL, and one end of the lever elastic body 128LEL is in contact with the elastic support protrusion provided in the separating operation lever 128DL, and the lever elastic body 128LEL. ), the other end is in contact with the inner surface of the filtration box body 112 of the filtration module 110, and when pulling the separation operation lever 128DL, the lever elastic body 128LEL is compressed to retain the elastic restoring force, , when the pulling force of the separation operation lever 128DL is released, the compressed lever elastic body 128LEL is unfolded by the elastic restoring force, and the separation piece 128DP of the separation operation lever 128DL is locked by a pair of opposing locks. When the separation piece 128DP of the separation operation lever 128DL falls out between the front ends of the pair of opposing locking bars 128LB, the locking elastic body 128EL is compressed and Since the locking bar 128LB is inserted into the inside of the locking channel 128LCH and is in a coupled state as it unfolds, the locking channel 128LCH and the pair of locking bars 128LB are coupled by the combination. The distribution module 130 is maintained under the filtration module 110 in a coupled state.

Accordingly, in the case of another embodiment of the present invention, a pair of locking bars 128LB provided in the distribution box body 132 of the distribution module 130 and the filtering box body 112 of the filtration module 110 are provided. It is possible to maintain the distribution module 130 to be stably and firmly coupled to the filtration module 110 by the coupling of the locking channel 128LCH, and to move the separation operation lever 128DL from the periphery of the distribution box body 132 . By pulling outward, the coupling state of the pair of locking bars 128LB and the locking channel 128LCH is released and the distribution module 130 can be separated from the filtration module 110, so the filtration module 110 or distribution Since the replacement cost of the module 130 is reduced, there is an effect of reducing the maintenance cost and solving the problem of difficulties in operation. The coupling means for detachably coupling the filtration module 110 and the distribution module 130 simplifies the structure while reducing the replacement cost of the filtration module 110 or the distribution module 130, thereby reducing maintenance costs and improving operation. It is effective in resolving difficult problems.

On the other hand, the inside of the distribution box body 132 of the distribution module 130 is further provided with an end filter 142, the water entering through the flow hole (128FH) of the coupling support frame (128CS) end filter (142). ) is finally filtered. By doing so, the water coming into contact with the water through the coupling unit and entering the distribution chamber 136 inside the distribution module 130 can be more reliably filtered by the end filter 142 .

In addition, in the present invention, the coupling unit is detachably coupled to the lower end of the filtration box body 112 of the filtration module 110 and the auxiliary coupling support frame (128SCS) provided under the coupling support frame (128CS), and the auxiliary An auxiliary locking channel (128SLCH) provided on the lower surface of the coupling support frame (128SCS) and having a pair of auxiliary locking bar insertion holes facing each other, and the distribution box body 132 of the distribution module 130 can be moved forward and backward. A pair of auxiliary locking bars (128SLB) coupled to each other so that the front ends face each other, and a pair of auxiliary locking bars (128SLB) provided at the front ends of the pair of auxiliary locking bars (128SLB) to stand up in a direction facing each other The separation movable piece (128SLDP) and the pair of auxiliary locking separation movable pieces (128SLDP) are provided and inserted into the auxiliary locking channel (128SLCH) through the auxiliary locking bar insertion hole of the auxiliary locking channel (128SLCH), the filter module 110 ) of a pair of auxiliary locking blocks (128SLCB) supporting the distribution box body 132 of the distribution module 130 to be coupled to the lower end of the filtering box body 112 of the filtration box body 112, and a pair of auxiliary locking bars (128SLB) and distribution It is connected between the box body 132 and pushes a pair of auxiliary locking bars 128SLB to advance toward the auxiliary locking channel 128SLCH, so that the pair of auxiliary locking blocks 128SLCB is inserted into the auxiliary locking channel 128SLCH. An auxiliary locking elastic body (128SEL) which is pushed to be inserted, and a pair of auxiliary locking blocks (128SLCB) that are rotatably coupled to the distribution box body (132) and that the front end is provided on a pair of auxiliary locking bars (128SLB) A separation rotation lever 128DCL disposed between, and a pair of auxiliary locking separation movable pieces 128SLDP provided at the front end of the separation rotation lever 128DCL and provided on a pair of auxiliary locking bars 128SLB are in contact with By rotating the separation pivot lever (128DCL), a pair of auxiliary locking blocks (128SLCB) and a pair of By pushing the auxiliary locking separation movable piece (128SLDP) and the pair of auxiliary locking bars (128SLB) to fall out of the auxiliary locking channel (128SLCH), the pair of auxiliary locking bars (128SLB) are coupled to the auxiliary locking channel (128SLCH) It may be configured to include a rotation separation piece (128CDP) for releasing the locked state.

Preferably, the distribution box body 132 of the distribution module 130 includes a distribution-side housing 137 detachably coupled to an upper end with a fastener such as a bolt, and the distribution-side housing 137 communicates with upper and lower surfaces. The distribution box body 132 has a connection distribution hole 137CH communicating with the distribution chamber inside, and the auxiliary locking bar 128SLB, the auxiliary locking separation movable piece 128SLDP, the auxiliary locking block 128SLCB, and the auxiliary locking elastic body (128SEL), the separation rotation lever 128DCL, and the rotation separation piece 128CDP are configured to be coupled to the distribution side housing 137, the inlet 113 of the filtration box body 112 of the filtration module 120 The water filtered through the filter cartridge 120 comes out of the outlet 114 of the filter box body 112 and passes through the flow hole 128FH formed in the coupling support frame 128CS to the distribution side housing 137. It may be configured to flow into the distribution chamber 136 inside the distribution box body 132 of the distribution module 130 through the connection distribution hole 137CH formed in the . On the other hand, when separating the distribution module 130 from the filtration module 120, the distribution side housing 137, the auxiliary locking bar (128SLB), the auxiliary locking separation movable piece (128SLDP), the auxiliary locking block (128SLCB) and the auxiliary locking elastic body (128SEL) and the separation pivot lever (128DCL), the pivot separation piece (128CDP) and the distribution box body 132 may be configured to be separated from the filter box body 122 together. Of course, the auxiliary locking bar operation hole to which the auxiliary locking bar 128SLB is coupled to move forward and backward is provided in the distribution side housing 137 .

In addition, a pair of auxiliary locking bar (128SLB) operation holes facing the pair of auxiliary locking bar insertion holes are provided in the distribution box body 132 of the distribution module 130 to operate the auxiliary locking bar (128SLB). A pair of auxiliary locking bars (128SLB) movably coupled to the hole pass through the auxiliary locking bar insertion hole of the auxiliary locking channel (128SLCH) coupled to the filtering box body 112 of the filtration module 110 to lock the auxiliary lock It is configured to be able to enter into the channel 128SLCH.

In addition, the distribution box body 132 of the distribution module 130 is provided with a separation pivot lever (128DCL) operation hole in the other peripheral portion orthogonal to the peripheral portion formed with a pair of auxiliary locking bar insertion holes, the separation rotation The separation rotation lever 128DCL and the rotation separation piece 128CDP rotatably coupled to the lever 128DCL operation hole are disposed inside the distribution box body 132, and are provided in the separation rotation lever 128DCL. The rotational separation piece 128CDP may be disposed at a position in contact with the pair of auxiliary separation movable pieces.

The rotating separating piece 128CDP has a plate shape having a long side portion 128LLP having a relatively larger width between both sides and a short side portion 128SLP having a relatively smaller width between both sides than the long side portion 128LLP. In a state in which both surfaces of the short side portion 128SLP of the rotation separation piece 128CDP are in contact with the pair of auxiliary locking separation movable pieces 128SLDP respectively provided on the pair of auxiliary locking bars 128SLB, the pair A pair of auxiliary locking elastic body (128SEL) pushes the auxiliary locking bar (128SLB) of the auxiliary locking channel (128SLCH) toward the auxiliary locking channel (128SLCH), and the auxiliary locking block ( 128SLCB) enters and is maintained in a combined locking state, and both sides of the long side portion 128LLP of the rotation separation piece 128CDP provided in the separation rotation lever 128DCL are provided in a pair of auxiliary locking bars 128SLB, respectively. In the state in which the pair of auxiliary locking separation movable pieces 128SLDP are in contact, the pair of auxiliary locking bars 128SLB is pushed to fall out of the auxiliary locking channel 128SLCH, and the pair of auxiliary locking channels 128SLCH The auxiliary locking block 128SLCB of the auxiliary locking bar 128SLB is maintained in the disengaged unlocked state.

In the present invention, in a state in which the distribution module 130 is coupled to the filtration module 110, a pair of the locking bars 128LB is supported by a pair of locking elastic bodies 128EL, and the coupling support frame 128CS is attached to the coupling support frame 128CS. Since the front end of the pair of locking bars 128LB enters into the provided locking channel 128LCH and is coupled, the locking channel 128LCH of the pair of locking bars 128LB and the coupling support frame 128CS is filtered by the coupling. In addition to maintaining the distribution box body 132 of the distribution module 130 coupled to the lower end of the filtration box body 112 of the module 110, the long side portion 128LLP of the rotation separation piece 128CDP In a state in which both sides are in contact with a pair of auxiliary locking separation movable pieces 128SLDP provided on each of the pair of auxiliary locking bars 128SLB, the pair of auxiliary locking bars 128SLB is connected to the outside of the auxiliary locking channel 128SLCH. The auxiliary locking block (128SLCB) of the pair of auxiliary locking bars (128SLB) in the auxiliary locking channel (128SLCH) is maintained in the unlocked state, and the distribution module 130 at the lower part of the filtration module 110 ) in the coupled state, when the separation operation lever 128DL is pulled outward from the periphery of the distribution box body 132 , a pair of locking bars 128LB becomes the filtering box body 112 of the filtering module 110 . ) is pushed out of the locking channel (128LCH) of the coupling support frame (128CS) provided in the pair of locking bars (128LB) and the coupling support frame (128CS) to release the coupling state of the locking channel (128LCH) On the other hand, by turning the rotation separation piece 128CDP, both sides of the long side portion 128LLP of the rotation separation piece 128CDP are provided on a pair of auxiliary locking bars 128SLB, respectively. A pair of auxiliary locking separation movable pieces 128SLDP. When switched to be in contact with the auxiliary locking bar (128SLB) and a pair of auxiliary locking block (128SLCB) auxiliary locking. Auxiliary locking block (128SLCB) of the auxiliary locking channel (128SLCH) and a pair of auxiliary locking bars (128SLB) provided in the filtering box body 112 of the filtering module 110 by pushing it out of the channel (128SLCH) It becomes the unlocked state in which the coupling of is released.

Accordingly, in the present invention, a pair of locking bars 128LB provided in the distribution box body 132 of the distribution module 130 and a locking channel 128LCH provided in the filtering box body 112 of the filtration module 110 are provided. ) can be maintained to be stably and firmly coupled to the distribution module 130 to the filtration module 110 by the combination of a pair of auxiliary locking devices provided in the distribution box body 132 of the distribution module 130 The distribution module 130 is more stably and firmly coupled to the filtration module 110 by the combination of the bar 128SLB and the auxiliary locking channel 128SLCH provided in the filtration box body 112 of the filtration module 110. On the other hand, if the separation operation lever 128DL is pulled out from the periphery of the distribution box body 132, the engagement state of the pair of locking bars 128LB and the locking channel 128LCH is released, By rotating the separation rotation lever 128DCL, both sides of the long side portion 128LLP of the auxiliary rotation separation piece 128CDP provided in the separation rotation lever 128DCL are a pair of auxiliary locking bars 128SLB, respectively. By pushing the auxiliary locking separation movable piece (128SLDP) of Since the filtration box body 112 of the filtration module 110 and the distribution box body 132 of the distribution module 130 can be easily and quickly separated, the replacement cost of the filtration module 110 or the distribution module 130 is low. This has the effect of reducing maintenance costs and solving operational difficulties.

On the other hand, an end filter 142 is further provided inside the distribution box body 132 of the distribution module 130 so as to be disposed under the auxiliary locking channel 128SLCH, the flow hole of the coupling support frame 128CS. The end filter 142 filters the water coming in through (128FH), and comes down in contact with the auxiliary coupling support frame 128SCS provided with the auxiliary locking channel 128SLCH, and the distribution module 130 inside the distribution chamber 136 ), the end filter 142 more reliably filters the water coming in, so that the water can be more reliably filtered.

In the above, specific embodiments of the present invention have been described above. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope that does not change the gist of the present invention. Anyone who has it will understand.

Therefore, since the embodiments described above are provided to fully inform those of ordinary skill in the art to which the present invention pertains to the scope of the invention, it should be understood that they are exemplary in all respects and not limiting, The invention is only defined by the scope of the claims.

110. Filtration module 112. Filtration box body
113. Inlet 114. Outlet
120. Filter Cartridge 122. Filter Frame
123. Core filter coupling support piece 124. Side filter coupling support piece
125. Filter 125CFL. core filter
125 CCH. Core filtering chamber 125SFL. side filter
126 SCH. Side filtering chamber 128CS. combined support frame
128 FH. Flowhole 128BT. volt
128 LCH. Locking Channel 128LB. locking bar
128EL. Locking elastomer 128DL. release lever
128DP. Separation 128SCS. Auxiliary combined support frame
128SLCH. Auxiliary locking channel 128SLB. Auxiliary locking bar
128SLDP. Auxiliary locking detachable movable piece 128SLCB. auxiliary locking block
128SEL. Auxiliary locking elastomer 128DCL. Separation Rotation Lever
128 CDP. Rotating Separator 128LLP. long side
128 SLP. Short side 130. Distribution module
132. Distribution box body 134. Diaphragm
136. Dispensing Chamber 135. Dispensing Hall
142. End filter

Claims (5)

Filtration module 110 for filtering water;
a distribution module 130 for distributing the water filtered by the filtration module 110 to a hydroponic facility;
It includes; a coupling unit that allows the distribution module 130 to be detachably coupled to the filtration module 110 ,
The filtration module 110,
and a filtration box body 112 having an inlet 113 through which water is introduced and an outlet 114 for discharging water; and
The filter box body 112 has a filter cartridge 120 that filters the water entering the inlet 113 and supplies water to the distribution module 130 through the outlet 114 of the filter box body 112 . ); is built-in,
The filter cartridge 120,
filter frame 122;
It includes; a filter 125 detachably coupled to the filter frame 122.
The filter cartridge 120 is built in the filter box body 112, and the water filtered through the filter 125 is sent to the distribution module 130 through the outlet 114 of the filter box body 112. configured to be supplied,
A plurality of filters 125 are erected and coupled to the filter frame 122 , and the inlet 113 formed in the filter box 112 is the innermost core between the two core filters 125CFL facing each other. Water entering the filtering space and filtered through the two core filters 125CFL is sequentially filtered through the other side filters 125SFL, so that the water entering the inlet 113 of the filtration box 112 is transferred to the core filter. (125CFL) and the side filter (125SFL) are filtered several times and then configured to be supplied to the distribution module 130 through the outlet 114 of the filtration box body 112,
The coupling unit is detachably attached to the lower end of the filtration box body 112 of the filtration module 110 so that the flow hole 128FH penetrated through the upper and lower surfaces communicates with the distribution chamber 136 inside the distribution module 130 . A locking having a coupling support frame 128CS that is operably coupled and supporting the filter frame 122 from below, and a pair of locking bar insertion holes provided on the lower surface of the coupling support frame 128CS and facing each other Channel 128LCH, a separation operation lever insertion hole formed in the locking channel 128LCH and disposed in a direction perpendicular to the locking bar insertion hole, and the distribution box body 132 of the distribution module 130 before and after The lower end of the filtration box body 112 of the filtration module 110 is inserted into the locking channel 128LCH through the locking bar insertion hole of the locking channel 128LCH. A pair of locking bars 128LB supporting the distribution box body 132 of the distribution module 130 to be coupled thereto, and the pair of locking bars 128LB and the distribution box body 132 are connected between A locking elastic body 128EL that pushes the pair of locking bars 128LB to be inserted into the locking channel 128LCH, and is coupled to the distribution box body 132 so as to be reversible and a front end portion is the locking channel 128LCH. A separation operation lever 128DL coupled to the separation operation lever insertion hole formed in the separation operation lever 128DL and a pair of locking bars provided at the periphery of the distal end of the separation operation lever 128DL to pull the separation operation lever 128DL (128LB) to the outside of the locking channel (128LCH) by pushing the locking channel (128LCH) a pair of locking bars (128LB) to release the locking state coupled to that comprising a detachable piece (128DP) A prefabricated water treatment system.
delete delete According to claim 1,
The distribution module 130,
Distribution box body 132 provided with a space therein;
At least two or more distribution chambers 136 partitioned by a diaphragm 134 inside the distribution box body 132;
At least two or more distribution chambers (136) are assembled water treatment system, characterized in that the communication with a distribution connector connected to a hydroponic facility.
5. The method of claim 4,
The distribution box body 132 is provided with a distribution hole 135 communicating with the distribution chamber 136 , a flange is provided around the distribution hole 135 , and the distribution connection pipe is provided with a pipe side flange Assembled, characterized in that by connecting the flange and the pipe side flange with a bolt (128BT) and a nut, the distribution chamber 136 of the distribution module 130 is connected to a hydroponic facility through the distribution connection pipe Mold water treatment system.

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