KR20200015239A - Water purification system with coagulation means - Google Patents

Abstract

The present invention relates to a water treatment device with an aggregation means, which comprises: a main body having an injection space formed therein to receive sewage/wastewater to be treated from a wastewater supply unit; a filter unit installed in the main body, having a reception space formed therein, receiving the sewage/wastewater in the reception space, having a plurality of filter holes to filter out contaminant included in the sewage/wastewater, and twisted to separate the contaminant stuck on the outer surface; a discharge pipe communicating with the reception space to discharge the sewage/wastewater received in the reception space of the filter unit; an operation unit installed in the filter unit to twist the filter unit; and an aggregation unit inserting an aggregation agent into the main body to aggregate and precipitate the contaminant separated from the filter unit when the filter unit is twisted by the operation unit. According to the present invention, when the contaminant is removed from the filter unit by the aggregation unit, the aggregation agent is injected into the main body such that the contaminant separated from the filter unit is aggregated and precipitated by the aggregation agent, thereby preventing the contaminant from being discharged to the outside together with purified water.

Description

Water purification system with coagulation means

The present invention relates to a water purification system provided with coagulation means, and more particularly, to a water purification system provided with coagulation means capable of coagulating contaminants separated from the filter unit when the filter unit is washed.

In recent years, due to urban population concentration due to rapid industrial development, the proportion of inorganic and organic components in wastewater and wastewater is gradually increasing along with the increase of various water volumes. Such waste and waste water contains high concentrations of organic substances such as chemical oxygen demand (COD), biochemical oxygen demand (BOD), suspended solids (SS), nitrogen and phosphorus, and flows into rivers, lakes, dams, etc. Pollution, and of course, the destruction of the ecosystem due to toxicity will adversely affect the environment. Therefore, the waste water and waste water are set to a predetermined standard, and purified and drained to a predetermined standard or less.

On the other hand, as a conventional control technology for treating waste water, various techniques using a filter have been proposed in various ways. However, the water treatment apparatus using the filter according to the prior art has a problem that some of the separated pollutants are discharged to the outside through the discharge pipe when separating the pollutants from the filter.

Patent Publication No. 10-1777461: Rainfall treatment and storage facility comprehensive management system of urban rivers

The present invention has been made to improve the above problems, and an object of the present invention is to provide a water purification system provided with agglomeration means so as to aggregate and precipitate contaminants separated from the filter unit.

The water purification system provided with the agglomeration means according to the present invention for achieving the above object is provided with a main body provided with an injection space therein so that the waste water to be treated can be injected from the waste water supply unit, and installed inside the main body and accommodated therein A space is formed, the waste water is introduced into the accommodation space, and a plurality of filter holes are formed to filter the contaminants contained in the waste water, and a filter unit is formed to be twistable to separate the contaminants adhered to the outer surface; A discharge pipe installed in communication with the accommodation space for discharging wastewater contained in the accommodation space of the filter unit, an operation unit installed in the filter unit to twist the filter unit, and when the filter unit is twisted by the operation unit. In the main body to aggregate and settle the contaminants separated from the filter unit And a coagulation unit to inject the coagulant to.

The coagulation unit includes a receiving tank in which the coagulant is accommodated, a supply pipe connected to the accommodation tank and the main body so that the coagulant in the accommodation tank can be supplied to the main body, and installed in the supply pipe, An injection pump for pumping the flocculant contained in the receiving tank to the main body when the filter unit is twisted.

The filter unit includes first and second rotating plates rotatably supported inside the main body at positions spaced apart from each other, and both ends of the first and second rotating plates are respectively installed. A plurality of flexible filter wires are installed to have a closed track along edges of the first and second rotating plates so that the receiving space is provided between the rotating plates, and spaced apart from each other so that the filter holes are provided. It is provided.

The operation unit may include a first rotating part installed on the first rotating plate to rotate the first rotating plate, a second rotating part provided on the second rotating plate to rotate the second rotating plate, and the filter. And a control part for controlling the first and second rotation parts such that the first and second rotation plates rotate in opposite directions so that the wires can be twisted.

The operation unit is rotatably installed in the main body and the operating shaft and one end is fixed to be wound on the working shaft, the other end is rotated to the first end so as to rotate the first rotating plate when wound on the working shaft A first fixing wire fixed to the plate and one end fixed to the working shaft, the second rotating plate being rotated when the working shaft is wound, wherein the second rotating plate is rotated in the opposite direction to the rotation direction of the first rotating plate. A second fixing wire having the other end fixed to the second rotating plate at a position opposite to the other end of the first fixing wire with respect to the center of rotation of the second rotating plate so as to rotate the second rotating plate; The rotary motor is installed on the working shaft to rotate the working shaft, and the first rotating plate when the first fixing wire is unwinded from the working shaft A first elastic member provided on the first rotating plate to provide an elastic force to the first rotating plate so as to return to the original position, and the second rotating plate is in an initial position when the second fixing wire is unwound from the working shaft; And a second elastic member installed on the second rotating plate to provide an elastic force to the second rotating plate so as to return to the second rotating plate.

On the other hand, the water purification system is provided with a cohesive means according to the present invention is further provided with a scraping unit is installed on the main body scraping the sediment deposited on the bottom surface of the main body from the front inner surface of the main body to the rear inner surface. .

The scraping unit includes at least one interference member installed on the bottom surface of the main body so as to scrape the deposit and movable in the front and rear directions, and a moving actuator for moving the interference member in the front and rear directions. Is curved in an arc shape so that the collection space can be formed between the rear inner surface and the bottom surface of the main body when in close contact with the rear inner surface of the main body, the left and right sides are formed to be open respectively.

The scraping unit is the main body of the sediment collected in the collection space on any one of the left and right inner surface of the main body corresponding to the collection space formed when the interference member is in close contact with the rear inner surface of the main body; And a pressurizing member provided to be movable in the left and right directions so as to press the other inner surface of the left and right inner surfaces of the main body, and a pressurizing actuator installed in the pressurizing member to move the pressurizing member in the left and right directions. The end is formed so as to contact the other inner surface of the left and right inner surface of the main body, the other inner surface of the left and right inner surface of the main body, when the interference member is formed in close contact with the rear inner surface of the main body In a position corresponding to the collection space, the opening and closing is opened and closed by a stopper, and the precipitate pressurized by the pressing member is discharged to the outside. A discharge port for exiting is formed, it is preferable that the pressing member is formed to have a cross section corresponding to the cross-sectional area of the collection space to prevent the waste water from flowing into the collection space when entering the collection space.

The scraper unit is protruded to the side of the pressing member opposite to the other inner surface of the left and right inner surface of the main body, at least one end sharply formed so as to crush the precipitate in accordance with the movement of the pressing member It may be further provided with a protrusion of.

In the water purification system provided with the agglomeration means according to the present invention, when the contaminant is injected into the main body when the contaminant is removed from the filter unit by the agglomeration unit, the contaminant separated from the filter unit by the coagulant is agglomerated and precipitated so that the pollutant is purified It can prevent the discharge to the outside with water.

1 is a partial cutaway perspective view of the water purification system provided with the aggregation means according to the present invention,
2 is a cross-sectional view of the water purification system provided with the aggregation means of FIG.
3 is a perspective view of an operating unit of a water purification system provided with an aggregation unit according to another embodiment of the present invention;
Figure 4 is a perspective view of the water purification system provided with the aggregation means according to another embodiment of the present invention,
FIG. 5 is a perspective view of a scraping unit of the water purification apparatus provided with the bypass means of FIG. 4;
6 is a cross-sectional view of the scraping unit of FIG. 5,
7 is a cross-sectional view of the scraping unit of the water purification system is provided with the aggregation means according to another embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described in detail with respect to the water purification system provided with the aggregation means according to an embodiment of the present invention. As the inventive concept allows for various changes and numerous modifications, particular embodiments will be illustrated in the drawings and described in detail in the text. However, this is not intended to limit the present invention to a specific disclosure form, it should be understood to include all modifications, equivalents, and substitutes included in the spirit and scope of the present invention. In describing the drawings, similar reference numerals are used for similar elements. In the accompanying drawings, the dimensions of the structures are shown in an enlarged scale than actual for clarity of the invention.

Terms such as first and second may be used to describe various components, but the components should not be limited by the terms. The terms are used only for the purpose of distinguishing one component from another. For example, without departing from the scope of the present invention, the first component may be referred to as the second component, and similarly, the second component may also be referred to as the first component.

The terminology used herein is for the purpose of describing particular example embodiments only and is not intended to be limiting of the invention. Singular expressions include plural expressions unless the context clearly indicates otherwise. In this application, the terms "comprise" or "have" are intended to indicate that there is a feature, number, step, action, component, part, or combination thereof described on the specification, and one or more other features. It is to be understood that the present invention does not exclude the possibility of the presence or the addition of numbers, steps, operations, components, parts, or combinations thereof.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art. Terms such as those defined in the commonly used dictionaries should be construed as having meanings consistent with the meanings in the context of the related art, and shall not be construed in ideal or excessively formal meanings unless expressly defined in this application. Do not.

1 and 2 illustrate a water purification system 100 provided with a cohesive means according to the present invention.

Referring to the drawings, the water purification system 100 provided with the coagulation means includes a main body 110 having an injection space 111 provided therein so that the waste water to be treated can be injected from the waste water supply unit, and the main body 110 inside. Is installed in, the receiving space 121 is formed therein, the waste water is introduced into the receiving space 121, a plurality of filter holes are formed to filter the contaminants contained in the waste water, contaminants adhered to the outer surface A filter unit 120 that is formed to be twistable to separate the discharge unit, a discharge pipe 130 installed in communication with the accommodation space 121 to discharge the wastewater contained in the accommodation space 121 of the filter unit 120, An operation unit 140 installed on the filter unit 120 to twist the filter unit 120, and the filter unit 120 when the filter unit 120 is twisted by the operation unit 140. Agglomerated with separated contaminants It is provided with a coagulation unit 160 for injecting a coagulant into the main body 110 to be precipitated by.

The main body 110 is formed as a rectangular structure having an injection space 111 therein, the injection pipe 171 of the waste water supply unit is connected to the front, the discharge pipe 130 is installed on the upper surface. At this time, the waste water supply unit is installed in the receiving tank 161 (not shown) in which the waste water is received, the injection pipe 171 connected between the receiving tank 161 and the main body 110, and the injection pipe 171 It is provided with a supply pump 163 (not shown) for injecting the waste water contained in the receiving tank 161 into the main body 110.

The discharge pipe 130 extends to enter a predetermined depth downward with respect to the upper portion of the main body 110 so that one end is drawn into the injection space (111). Although the other end of the discharge pipe 130 is not shown in the figure, it is installed in a water storage facility capable of storing water from which contaminants have been removed.

The filter unit 120 includes first and second rotating plates 122 and 123 rotatably supported inside the main body 110 at positions spaced apart from each other, and both ends of the first and second rotating plates 122 and 123. A plurality of filter wires 124 are provided, respectively.

The first rotating plate 122 is formed in a disc shape having a predetermined thickness and is rotatably installed in the discharge pipe 130 drawn into the main body 110. Discharge pipe 130 is installed to penetrate the center portion of the first rotating plate 122, although not shown in the figure, a bearing is installed between the discharge pipe 130 and the first rotating plate 122, the first rotating plate 122 ) Is rotatably supported by the discharge pipe 130. On the other hand, the first rotating plate 122 is not limited to this may be rotatably installed on the ceiling surface of the main body 110 through a separate rotation shaft.

The second rotating plate 123 is formed in a disk shape having a predetermined thickness to have an area corresponding to the first rotating plate 122. The second rotating plate 123 is rotatably installed on the bottom surface of the main body 110 opposite to the first rotating plate 122. At this time, the second rotation plate 123 is preferably installed so that the rotation center is located on the rotation center line of the first rotation plate 122. Meanwhile, in the illustrated example, a structure in which the first and second rotating plates 122 and 123 are formed in a disc shape is illustrated, but the first and second rotating plates 122 and 123 are not limited thereto but may be formed in an oval or polygonal shape. have.

The filter wire 124 extends in the vertical direction, and both ends thereof are fixed to the first and second rotating plates 122 and 123, respectively. In this case, a plurality of filter wires 124 are closed along the edges of the first and second rotating plates 122 and 123 so that the accommodation space 121 may be provided between the first and second rotating plates 122 and 123. It is installed to have. At this time, the filter wires 124 are preferably arranged to be spaced apart from each other so that the filter hole to filter the contaminants from the waste water can be formed. In addition, the filter wire 124 is flexible to be twisted when the rotational force is applied to the first and second rotating plates (122, 123) from the operating unit 140, and is formed of a synthetic resin material having a predetermined elasticity.

The operation unit 140 may rotate the first rotating part 141 installed on the first rotating plate 122 and the second rotating plate 123 to rotate the first rotating plate 122. The second and second rotating parts 142 installed on the second rotating plate 123 and the first and second rotating plates 122 and 123 rotate in opposite directions so that the filter wires 124 may be twisted. The control unit 143 controls the first and second rotation units 141 and 142.

The first rotating part 141 is installed on the first driving motor 241 installed on the upper part of the main body 110 so that the rotating shaft is introduced into the main body 110, and on the rotating shaft of the first driving motor 241. The first driving gear 242 is formed on the outer circumferential surface of the first rotating plate 122, and a plurality of first driving gear 242 along the circumferential direction of the first rotating plate 122 to be engaged with the first driving gear 242. A first driven gear 243 is provided with a gear tooth.

The second rotating part 142 is installed on the second driving motor 244 installed in the lower portion of the main body 110 so that the rotating shaft is introduced into the main body 110 and the rotating shaft of the second driving motor 244. The second driving gear 245 is formed on the outer circumferential surface of the second rotating plate 123, and a plurality of second driving gears 245 along the circumferential direction of the second rotating plate 123 to be driven by the second driving gear 245. A second driven gear 246 is provided with a gear tooth.

The controller 143 controls the first driving motor 241 of the first rotating part 141 and the second driving motor 244 of the second rotating part 142. In this case, the controller 143 further includes an input module (not shown) through which the administrator can input a washing signal. When the manager inputs a washing signal through the input module, the controller 143 operates the first driving motor 241 and the second driving motor 244 so that the first and second rotating plates 122 and 123 rotate in opposite directions. Let's do it. When the first and second rotating plates 122 and 123 rotate in opposite directions by the operation unit 140, the plurality of filter wires 124 are twisted and contaminants adhering to the filter wires 124 are filtered out of the filter wires 124. ) Meanwhile, the controller 143 may operate the first driving motor 241 and the second driving motor 244 at predetermined time intervals set by an administrator to remove contaminants attached to the filter wire 124.

The agglomeration unit 160 includes a receiving tank 161 in which a coagulant is accommodated, and a coagulation agent in the accommodating tank 161 to the accommodating tank 161 and the main body 110 so as to be supplied to the main body 110. The supply pipe 162 is connected to the injection pipe 162 is installed in the supply pipe 162 when the filter unit 120 is twisted by the operation unit 140 pumping the coagulant contained in the receiving tank 161 to the main body 110 A pump 163 is provided.

The receiving tank 161 is formed of a synthetic resin material such as plastic that does not generate a chemical reaction with the flocculant. In this case, the flocculant may be one or more selected from among inorganic coagulants (PACI; Al ₂ (OH) ₃ Cl ₃ ), Alum (sulfate alumina; Al ₂ (SO ₄ ) ₃ · 16H ₂ O), and benzzones. Can be. Meanwhile, the coagulant is not limited thereto, and any coagulant may be used as long as it can aggregate contaminants separated from the filter unit 120.

When the supply pipe 162 is provided with an internal flow path through which the flocculant flows, one end is connected to the main body 110 so as to communicate with the injection space 111, and the other end is connected to the receiving tank 161. . At this time, it is preferable that one end of the supply section is installed above the main body 110.

Injection pump 163 is installed in the supply pipe 162 is operated by the control unit. At this time, the control unit 143 injects the coagulant into the main body 110 by operating the injection pump 163 during the operation of the first drive motor 241 and the second drive motor 244. The coagulant injected into the main body 110 aggregates the contaminants separated from the filter unit 120, and the aggregated contaminants are precipitated on the bottom surface of the main body 110.

Referring to the operation of the water purification system 100 is provided with a cohesive means according to the present invention configured as described in detail as follows.

First, wastewater to be treated is injected into the injection space 111 of the main body 110 through the injection pipe 171 in the wastewater supply unit. The waste water injected into the main body 110 is discharged to the discharge pipe 130 through the filter wires 124 of the filter unit 120. At this time, the contaminants contained in the waste water are filtered by the filter wires 124.

Meanwhile, when a manager inputs a cleaning signal to the controller 143 to remove contaminants adhered to the filter wires 124, the controller 143 may rotate the first and second rotating plates 122 and 123 in opposite directions. Operate the operation unit 140. As the first and second rotating plates 122 and 123 rotate, the filter wires 124 are twisted and contaminants are separated from the filter wires 124. At this time, the control unit 143 injects the coagulant into the main body 110 by operating the injection pump 163 during the operation of the first drive motor 241 and the second drive motor 244. The coagulant injected into the main body 110 aggregates the contaminants separated from the filter unit 120, and the aggregated contaminants are precipitated on the bottom surface of the main body 110 and prevented from being discharged to the outside along with the purified water. do.

The water purification system 100 provided with the coagulation means according to the present invention configured as described above is a coagulant is injected into the main body 110 when the contaminant is removed from the filter unit 120 by the coagulation unit 160. By the contaminants separated from the filter unit 120 by the condensation and precipitation can be prevented to be discharged to the outside with the purified water contaminants.

On the other hand, Figure 3 shows an operating unit 210 according to another embodiment of the present invention.

Elements having the same function as in the above-described drawings are denoted by the same reference numerals.

Referring to the drawings, the operation unit 210 has an operating shaft 211 rotatably installed in the main body 110, one end is wound around the operating shaft 211, the other end of the first rotating plate ( A first fixing wire 212 fixed to 122, a second end of which is wound on the operating shaft 211, and a second fixing wire 213 fixed to the second rotating plate 123, and the operation A rotating motor 214 installed on the main body 110, a first elastic member 216 installed on the first rotating plate 122, and a second rotating plate 123 to rotate the shaft 211. And a second elastic member 216 installed at the control panel and a control unit 217 for controlling the rotary motor 214.

The operation shaft 211 extends a predetermined length in the vertical direction, the upper end is rotatably installed on the ceiling surface of the main body 110, the other end is rotatably installed on the bottom surface of the main body 110.

The first fixing wire 212 is fixed to the upper outer circumferential surface of the operating shaft 211 so that one end thereof is wound around the operating shaft 211, and the other end rotates the first rotating plate 122 when winding the operating shaft 211. It is fixed to the first rotating plate 122 to enable. In this case, the first fixing wire 212 is preferably fixed at a position spaced apart from the rotation axis of the first rotating plate 122.

The second fixing wire 213 is fixed to the lower outer circumferential surface of the operating shaft 211 so that one end thereof is wound around the operating shaft 211, and the other end rotates the second rotating plate 123 when the second fixing wire 213 is wound around the operating shaft 211. It is fixed to the second electrical plate to make it possible. At this time, the second fixing wire 213 is based on the rotation center of the second rotating plate 123 to rotate the second rotating plate 123 in the direction opposite to the rotation direction of the first rotating plate 122. Therefore, the other end is preferably fixed to the second rotating plate at a position opposite to the other end of the first fixing wire 212.

The rotary motor 214 is fixed to the upper portion of the main body 110, is installed on the upper portion of the operating shaft 211 to rotate the operating shaft 211. The control unit 217 operates the rotary motor 214 so that the operating shaft 211 is rotated by a predetermined angle when the administrator inputs a washing signal through the input module. At this time, the first and second rotating plates 122 and 123 rotate in opposite directions as the operating shaft 211 rotates, the plurality of filter wires 124 are twisted, and contaminants adhered to the filter wires 124 are rotated. Depart from the filter wire 124. On the other hand, the control unit 217 may operate the rotary motor 214 at predetermined time intervals set by the administrator to remove contaminants attached to the filter wire 124.

Although not illustrated in the drawing, the first elastic member 216 may be configured to return the first rotating plate 122 to the initial position when the first fixing wire 212 is unwound from the operating shaft 211. It is installed on the first rotating plate 122 to provide an elastic force to (122). At this time, the first elastic member 216 is preferably applied to the torsion spring installed between the first rotating plate 122 and the main body 110.

Although not shown in the drawings, the second elastic member 216 may be configured to return the second rotating plate 123 to its initial position when the second fixing wire 213 is unwound from the operating shaft 211. It is installed on the second rotating plate 123 to provide an elastic force to the (123). At this time, the second elastic member 216 is preferably applied to the torsion spring installed between the second rotating plate 123 and the main body 110.

Referring to the operation of the operation unit 140 configured as described above in detail as follows.

First, when a washing signal is input to the controller 217 or a predetermined set time elapses, the controller 217 operates the rotary motor 214 to rotate the operating shaft 211 by a predetermined angle. The first fixing wire 212 and the second fixing wire 213 are wound around the operating shaft 211 by the rotation axis of the operating shaft 211, the first fixing wire 212 and the second fixing wire 213 is wound The first and second rotating plates 122 and 123 rotate in opposite directions. Filter wires 124 are twisted by rotating first and second rotating plates 122 and 123, and contaminants adhering to filter wires 124 are separated from filter wires 124.

On the other hand, when the washing operation of the filter unit 120 is completed, the control unit 217 operates the rotary motor 214 to return the operating shaft 211 to the initial position. The first fixing wire 212 and the second fixing wire 213 are unwound from the operating shaft 211 by the return of the operating shaft 211. At this time, the first and second rotating plates 122 and 123 are returned to their initial positions by the elastic force provided from the first and second elastic members 216.

The operating unit 140 configured as described above rotates the first and second rotating plates 122 and 123 in opposite directions using a single rotating motor 214 through the operating shaft 211 and the fixing wire. It is relatively simple, which saves the cost and manpower required to manufacture the device.

On the other hand, Figure 4 to Figure 6 shows a water purification system 300 is provided with a cohesive means according to another embodiment of the present invention.

Referring to the drawings, the water purification system 300 is provided with the coagulation means is installed in the main body 110, the sediment deposited on the bottom surface of the main body 110 in the front inner surface of the main body 110 It is further provided with a scraping unit 310 for scraping to the rear inner surface.

At this time, the main body 110 is formed with a discharge port 101 for discharging the precipitate in the lower rear. The outlet 101 is formed to penetrate through the left side of the main body 110, is formed in the rear end of the main body 110, it is preferably formed in a position adjacent to the bottom surface of the main body 110. . In addition, the water purification system 300 provided with the aggregation means further includes an opening and closing stopper 102 to open and close the outlet 101. On the other hand, the outlet 101 is not limited to the illustrated example may be formed on the right side of the main body 110.

On the other hand, the second rotating plate 123 is supported to be spaced apart a predetermined height upwards with respect to the bottom surface of the main body 110 in order to prevent interference with the scraping unit 310, the rotating shaft is the outside of the main body 110 It is installed to protrude. In addition, the second rotating part 142 may include a third driving motor 301 installed outside the main body 110, a driving pulley 302 installed on a rotation shaft of the third driving motor 301, and the main body 110. And a driven pulley 303 provided on the rotating shaft of the second rotating plate 123 exposed to the outside, and a driving belt 304 provided on the driving pulley 302 and the driven pulley 303.

The scraping unit 310 is a plurality of interference member 311 and the interference member 311 is installed on the bottom surface of the main body 110 to be movable in the front and rear directions to scrape the deposit, and the interference member 311 in the front and rear direction A moving actuator 312 for moving and a precipitate discharge part 313 for discharging the precipitate deposited on the bottom surface of the main body 110 to the discharge port 101 are provided.

The interference member 311 is mounted on the bottom surface of the main body 110 so that a plurality of the interference members are spaced apart from each other in the left and right directions. At this time, the interference members 311 are installed such that one side end thereof contacts the left inner wall surface or the right inner wall surface of the main body 110, respectively. In addition, the interference members 311 are arc-shaped so that the collection space 314 may be formed between the rear inner surface and the bottom surface of the main body 110 when in close contact with the rear inner surface of the main body 110. It is preferable that it is curved and formed so that right and left side surfaces may open, respectively. When the interference member 311 is in close contact with the rear inner surface of the main body 110, sediment is collected in the collection space 314. On the other hand, the main body 110 is the discharge port 101 is formed on the left side of the main body 110 of the position corresponding to the collection space 314 formed in close contact with the rear inner surface of the main body 110 It is preferable.

Meanwhile, in the illustrated example, a structure in which two interference members 311 are installed inside the main body 110 is illustrated, but one interference member 311 is not limited thereto but according to the size of the main body 110. Alternatively, three or more may be installed in the main body 110.

The plurality of moving actuators 312 are installed at the front of the main body 110, and move the interference members 311 in the front and rear directions, respectively. The interference member 311 is moved from the front inner surface to the rear inner surface of the main body 110 by the moving actuator 312, and the sediment deposited on the bottom surface of the main body 110 is adjacent to the discharge port 101. The back of the main body 110 is scraped.

Sediment discharge portion 313 in the left and right directions on the right side of the main body 110 corresponding to the collection space 314 formed when the interference member 311 is in close contact with the rear inner surface of the main body 110. A pressure member 315 slidably provided and a pressure actuator 316 installed on the pressure member 315 to move the pressure member 315 in left and right directions are provided.

 The pressing member 315 is moved by the pressing actuator 316, the collection space between the interference member 311 and the main body 110 when the interference member 311 contacts the rear inner surface of the main body (110) ( 314 is transferred to the discharge port 101 precipitates collected in the collection space 314 of the interference member 311. At this time, the pressing member 315 is installed on the right inner wall surface of the main body 110 at the position opposite to the discharge port 101, the waste water is introduced into the collection space 314 when entering into the collection space 314 It is preferable to have a cross section corresponding to the cross-sectional area of the collection space 314 to prevent it.

Meanwhile, in the illustrated example, the structure in which the pressing member 315 is installed on the right side of the main body 110 is illustrated, but the pressing member 315 is not limited thereto, but the discharge port 101 of the main body 110 is provided. When formed on the right inner wall surface may be installed on the left inner wall surface of the main body 110.

The pressure actuator 316 is installed on the side of the main body 110, it is preferable that the hydraulic device is stretched in the left and right directions to move the pressing member 315 in the left and right directions.

Referring to the operation of the scraping unit 310 according to the present invention configured as described in detail as follows.

First, in the case of collecting the precipitate on the bottom surface of the main body 110, in the state of closing the outlet 101 through the opening and closing stopper 102, by operating the moving actuator 312 to move the interference member 311 main body It moves from the front medial side of 110 to the rear medial side. The interference members 311 move backward along the bottom surface of the main body 110 to collect precipitates. The precipitate is collected in the rear portion of the interference member 311.

When the collected precipitate is discharged to the outside of the main body 110, by operating the moving actuator 312, the interference member 311 is in close contact with the rear inner surface of the main body (110). When the interference member 311 is in close contact with the rear inner surface of the main body 110 to operate the pressure actuator 316 to move the pressing member 315 located on the right inner wall surface of the main body 110 to the left. The pressurizing member 315 moving by the pressurizing actuator 316 enters the collection space 314 of the interference member 311 and forcibly transfers the precipitate collected in the collection space 314 to the discharge port 101 side. At this time, when the pressing member 315 enters the collection space 314 of the leftmost interference member 311 adjacent to the outlet 101, the operator separates the opening and closing stopper 102 from the main body 110 to discharge the outlet 101. To open. When the pressure member 315 is in close contact with the discharge port 101, the precipitate collected through the discharge port 101 is discharged.

The scraping unit 310 configured as described above automatically collects contaminants precipitated on the bottom surface of the main body 110 when the contaminants separated from the filter unit 120 and discharges them to the outside of the main body 110. .

On the other hand, Figure 7 shows a scraping unit 320 according to another embodiment of the present invention.

Referring to the drawings, the scraping unit 320 is protruded to the left side of the pressing member 315 opposite to the inner left side of the main body 110, the movement of the pressing member 315 It is further provided with a plurality of protrusions 321 formed sharply at the end to crush the precipitate. The protrusion 321 protrudes from the pressing member 315 in a direction adjacent to the outlet 101.

The pressure member 315 by the protruding protrusions 321 can break the sediment fixed when entering the collection space 314 of the interference member 311, the sediment is more easily through the main body (101) 110 may be discharged to the outside.

The description of the presented embodiments is provided to enable any person skilled in the art to make or use the present invention. Various modifications to these embodiments will be apparent to those skilled in the art, and the generic principles defined herein may be applied to other embodiments without departing from the scope of the invention. Thus, the present invention should not be limited to the embodiments set forth herein but should be construed in the broadest scope consistent with the principles and novel features set forth herein.

100: water purification device equipped with bypass means
110: main body
111: injection space
120: filter unit
121: accommodation space
122: first rotating plate
123: second rotating plate
124: filter wire
130: discharge pipe
140: operating unit
141: first rotating part
142: second rotating part
143: control unit
160: coagulation unit
161: receiving tank
162: supply pipe
163: injection pump

Claims (9)

A main body provided with an injection space therein so that the waste water to be treated can be injected from the waste water supply unit;
It is installed inside the main body, the receiving space is formed therein, the waste water is introduced into the receiving space, a plurality of filter holes are formed to filter the contaminants contained in the waste water, the contaminants adhered to the outer surface A filter unit formed to be twistable to separate;
A discharge pipe installed in communication with the accommodation space to discharge the wastewater contained in the accommodation space of the filter unit;
An operation unit installed in the filter unit to twist the filter unit; And
And a coagulation unit for introducing a coagulant into the main body so that the contaminant separated from the filter unit can be aggregated and precipitated when the filter unit is twisted by the operation unit.
Water purification system with coagulation means.
The method of claim 1,
The aggregation unit is
An accommodation tank containing the coagulant therein;
A supply pipe connected to the accommodation tank and the main body so that the coagulant in the accommodation tank can be supplied to the main body; And
And an injection pump installed at the supply pipe to pump the coagulant contained in the accommodation tank to the main body when the filter unit is twisted by the operation unit.
Water purification system with coagulation means.
The method according to claim 1 or 2,
The filter unit is
First and second rotating plates rotatably supported inside the main body at mutually spaced positions; And
Both ends of the first and second rotating plates are respectively installed, and the closed tracks are formed along edges of the first and second rotating plates so that the accommodation space is provided between the first and second rotating plates. Installed, but arranged to be spaced apart from each other so that the filter hole is provided, and provided with a plurality of flexible filter wires,
Water purification system with coagulation means.
The method of claim 3,
The operation unit
A first rotating part installed on the first rotating plate to rotate the first rotating plate;
A second rotating part installed on the second rotating plate to rotate the second rotating plate; And
And a controller configured to control the first and second rotation parts to rotate the first and second rotation plates in opposite directions so that the filter wires are twisted.
Water purification system with coagulation means.
The method of claim 3,
The operation unit
An operating shaft rotatably installed inside the main body;
A first fixing wire having one end fixed to the working shaft and the other end fixed to the first rotating plate so as to rotate the first rotating plate when the working shaft is wound;
One end is fixed so as to be wound on the working shaft, and when the winding on the working shaft to rotate the second rotating plate, the second rotating plate to rotate in the opposite direction of the rotation direction of the first rotating plate A second fixing wire having the other end fixed to the second rotating plate at a position opposite to the other end of the first fixing wire with respect to the rotation center of the second rotating plate;
A rotating motor installed on the working shaft to rotate the working shaft;
A first elastic member installed on the first rotating plate to provide elastic force to the first rotating plate so that the first rotating plate returns to an initial position when the first fixing wire is unwound from the operating shaft; And
And a second elastic member installed on the second rotating plate to provide elastic force to the second rotating plate so that the second rotating plate returns to an initial position when the second fixing wire is unwound from the working shaft. ,
Water purification system with coagulation means.
The method of claim 1,
And a scraping unit installed on the main body to scrape the precipitate deposited on the bottom surface of the main body from the front inner side to the rear inner side of the main body.
Water purification system with coagulation means.
The method of claim 6,
The scraping unit is
At least one interference member installed on the bottom surface of the main body to move forward and backward to scrape the deposits; And
And a moving actuator for moving the interference member in the front-rear direction.
The interference member is curved in an arc shape so that a collection space can be formed between the rear inner surface and the bottom surface of the main body when the interference member is in close contact with the rear inner surface of the main body, the left and right sides are formed to be open, respectively,
Water purification system with coagulation means.
The method of claim 7, wherein
The scraping unit is
The sediment collected in the collection space in the left and right of the main body in any one of the left and right inner surface of the main body corresponding to the collection space formed when the interference member is in close contact with the rear inner surface of the main body; A pressing member movably installed in the left and right directions to press the other inner side of the side surface; And
And a pressurizing actuator installed on the pressurizing member and moving the pressurizing member in left and right directions.
The interference member is formed so that the end portion is in contact with the other inner surface of the left and right inner surface of the main body,
On the other inner surface of the left and right inner surface of the main body, the interference member is opened and closed by an opening stopper at a position corresponding to the collection space formed when the interference member is in close contact with the rear inner surface of the main body, The discharge port for discharging the pressurized precipitate to the outside is formed,
The pressing member is formed to have a cross-section corresponding to the cross-sectional area of the collection space to prevent waste water from flowing into the collection space when it is drawn into the collection space,
Water purification system with coagulation means.
The method of claim 8,
The scraper unit is
At least one protruding protrusion formed on a side of the pressing member facing the other inner surface of the left and right inner surfaces of the main body, and having an end portion sharply crushed in accordance with the movement of the pressing member; Further provided with,
Water purification system with coagulation means.

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