KR102597781B1 - small organism blocking device - Google Patents

Abstract

The present invention relates to a small organism blocking device, which is coupled to a water supply pipe and removes foreign substances in water, comprising: a main unit coupled between the water supply pipes that are adjacent to each other and spaced apart by a set distance; a mesh unit provided inside the main body unit, through which constant water flowing inside the main body unit passes, but filters out foreign substances contained in the constant water; and a nozzle unit that is provided inside the main body unit and spaced apart from the mesh unit by a set distance, and supplies washing water in a direction opposite to the flow direction of the clean water so that the mesh unit can be cleaned.

Description

Small organism blocking device}

The present invention relates to a device for blocking small organisms, and more specifically, to a device for blocking small organisms that is installed in water purification ponds and water pipes that supply water to each household, and is capable of removing foreign substances in water while the water flows.

In general, tap water is purified from water from rivers or dams through standard water treatment of coagulation, sedimentation, filtration, and disinfection at a water purification plant, or through advanced water purification stages that add ozone oxidation and activated carbon adsorption to standard water treatment, and is then purified through pipes. It is supplied to homes.

Foreign substances such as scale present in pipes fall out of the pipes due to rapid changes in the direction and speed of water flow in the pipes and reach homes or water storage tanks, causing red water.

In addition, there have been cases where live larvae or dead corpses that were not killed by chlorine disinfection were supplied to homes due to the influx of various flying insects from water intake plants or water purification plant drains, which became a social issue.

In particular, recently, in the process of supplying tap water to each home after the water purification process at the water purification plant and through the reservoir, etc., larvae have been generated, causing social problems such as being found in showers of end users or red rust coming out of faucets at home. It is becoming.

In the case of midget larvae, the eggs are translucent, milky-white in size, 0.1 to 0.2 mm, and are contained in a thin, linear egg case surrounded by a sticky substance. In the case of larvae, the eggs are thin, 1 to 2 mm, and the size is 0.5 to 2 cm, similar to red threadworms. It has a similar shape. Although there are no research results showing that it is harmful to the human body yet, it is true that it increases anxiety about tap water due to its aesthetic effects.

Therefore, devices are being developed that can remove foreign substances from water supply pipes to prevent these larvae and pipes from reaching homes. However, recently developed foreign matter removal devices are complicated and expensive to install in water pipes. In particular, the device must be replaced or cleaned at regular intervals, but in this case, the device must be separated from the water pipe, making the process complicated and cumbersome, and resulting in high costs.

The present invention can be installed in a water supply to remove foreign substances such as larvae contained in the water while the water flows, and can be cleaned from the inside even if not separated from the water supply, and the washing water used for cleaning can be easily discharged. It provides a small organism blocking device.

According to one embodiment of the present invention, the present invention provides a small organism blocking device that is coupled to a water supply pipe and removes foreign substances in water, comprising: a main body unit coupled between the water supply pipes that are adjacent to each other and spaced apart by a set distance; a mesh unit provided inside the main body unit, through which constant water flowing inside the main body unit passes, but filters out foreign substances contained in the constant water; and a nozzle unit that is provided inside the main body unit and spaced apart from the mesh unit by a set distance, and supplies washing water in a direction opposite to the flow direction of the clean water so that the mesh unit can be cleaned. The small organism blocking device When cleaning the mesh unit, the flow of constant water is blocked, the washing water is sprayed toward the mesh unit through the nozzle unit to wash the mesh unit, and the washing water cleaning the mesh unit is discharged from the main unit to the outside. Drain and remove.

Additionally, the mesh unit includes a mesh plate with a plurality of mesh holes formed thereon; a mesh frame that is closely coupled to the front and rear surfaces of the mesh plate and has a hollow area formed in a central area to expose the mesh hole; and a fixing member for fixing the mesh plate and the mesh frame.

Additionally, the nozzle unit includes a nozzle fixing plate; A plurality of nozzles are coupled to penetrate the nozzle fixing plate and are provided to spray the washing water; and a washing water flow hose connected to the plurality of nozzles and supplying the washing water to the nozzles from the outside.

In addition, the nozzle fixing plate includes a plurality of constant flow holes formed through the front and rear directions to allow constant water to flow; and one or more nozzle coupling holes that are formed to penetrate in the front-back direction between adjacent constant flow holes, and into which the nozzles are fastened.

Additionally, the nozzle coupling hole is formed so that the center of the nozzle coupling hole coincides with the center of an imaginary circle circumscribed in an imaginary triangle formed by the centers of the three neighboring constant flow holes.

In addition, the small organism blocking device includes a timer that transmits an alarm at a set time; and a control unit that receives an alarm from the timer and blocks the water supply pipe to block the flow of water when the alarm is received from the timer.

Specific details of other embodiments are included in the detailed description and drawings.

The small organism blocking device according to the present invention has the following effects.

First, it has the advantage of being able to easily clean the mesh unit that filters out foreign substances by simply blocking the flow of water without disconnecting the device from the water supply pipe.

Second, the washing water used to clean the mesh unit can be discharged to the outside through the drain hole formed in the device, which has the advantage of keeping the device clean.

Third, since there is no need to separate the device from the water supply pipe, management costs can be reduced and management is easy.

Figure 1 is a conceptual diagram showing a device for blocking small organisms according to an embodiment of the present invention.
Figure 2 is a perspective view showing the mesh unit of the small organism blocking device according to Figure 1.
Figure 3 is a perspective view showing the nozzle unit of the small organism blocking device according to Figure 1.
Figure 4 is a perspective view for explaining the nozzle spray surface of the nozzle unit according to Figure 3.
Figure 5 is an exploded perspective view showing the main unit, nozzle unit, and mesh unit of the small organism blocking device according to Figure 1.
Figure 6 is a cross-sectional view showing the combined structure of the main unit, nozzle unit, and mesh unit of the small organism blocking device according to Figure 1.

Hereinafter, with reference to the attached drawings, embodiments of the present invention will be described in detail so that those skilled in the art can easily implement the present invention. The present invention may be implemented in many different forms and is not limited to the embodiments described herein.

Please note that the drawings are schematic and not drawn to scale. The relative dimensions and proportions of parts in the drawings are shown exaggerated or reduced in size for clarity and convenience in the drawings, and any dimensions are illustrative only and are not limiting. And for identical structural elements or parts that appear in two or more drawings, the same reference numerals are used to indicate similar features.

The embodiments of the present invention specifically represent ideal embodiments of the present invention. As a result, various variations of the diagram are expected. Accordingly, the embodiment is not limited to the specific shape of the illustrated area and also includes changes in shape due to manufacturing, for example.

Hereinafter, the device for blocking small organisms according to the present invention will be described in detail with reference to FIGS. 1 to 6.

The small organism blocking device 100 according to an embodiment of the present invention includes a mesh unit 110, a nozzle unit 120, and a main body unit 130. The small organism blocking device 100 is coupled between neighboring water pipes 10 spaced apart by a set distance. The small organism blocking device 100 is installed in the flow path that flows from the filter pond to the water purification pond and the flow path that flows from the drainage pond to each home.

The small organism blocking device 100 filters out foreign substances contained in the water when the water flows and prevents foreign substances (such as midge larvae) from entering the home. The small organism blocking device 100 can clean itself using washing water when foreign substances accumulate above a certain amount. At this time, the small organism blocking device 100 can be cleaned without separating it from the neighboring water supply pipes 10.

Referring to FIG. 1, a butterfly valve 20 is coupled to the other side of the water pipe 10. The small organism blocking device 100 is coupled to one side of the water pipe piping 10. The butterfly valve 20 is normally open, and is closed by a signal from the control unit 40 when the small organism blocking device 20 needs to be cleaned.

When the butterfly valve 20 is closed, most of the water remaining between the butterfly valve 20 and the butterfly valve 20 before cleaning the small organism blocking device 100 flows naturally and is transferred to a purified water reservoir. do. Additionally, the remaining constant water is discharged to the drain part 11 formed in the water supply pipe 10.

The mesh unit 110 allows water flowing inside the main unit 130 to pass through, but serves to filter out foreign substances contained in the water. The mesh unit 110 is provided inside the main body unit 130.

The mesh unit 110 includes a mesh plate 111, a mesh frame 112, and a fixing member 113.

The mesh plate 111 serves to filter out foreign substances contained in clean water. The mesh plate 111 is formed as a flat plate and has a plurality of mesh holes 111a. The mesh hole 111a is formed by penetrating the mesh plate 111 in the front-back direction. In this embodiment, the mesh plate 111 is formed as a circular plate, but is not limited thereto.

Constant water flows while passing through the mesh hole (111a). When constant water passes through the mesh hole (111a), foreign substances such as midget larvae contained in the constant water do not pass through the mesh hole (111a).

In this embodiment, the size of the mesh hole 111a is 0.1 mm. However, it is not limited anymore and can be formed in various sizes.

There may be a plurality of mesh plates 111, and when a plurality of mesh plates 111 are provided, they may be arranged in series. When a plurality of mesh plates 111 are provided, the sizes of the mesh holes 111a of each mesh plate 111 are formed differently.

For example, when three mesh plates 111 are provided, the mesh plates 111 are arranged so that the size of the mesh holes 111a gradually decreases in the direction in which constant water flows.

The mesh frame 112 is for fixing the mesh plate 111. The mesh frame 112 has a hollow area formed in the central area. The mesh frame 112 is tightly coupled to the front and rear surfaces of the mesh plate 111. When the mesh frame 112 is in close contact with the front and rear surfaces of the mesh plate 111, the mesh hole 111a is exposed through the hollow.

The mesh frame 112 is also formed in a circular shape. The shape of the mesh frame 112 is formed to correspond to the shape of the mesh plate 111.

The fixing member 113 serves to fix the mesh plate 111 and the mesh frame 112. In this embodiment, the fixing member 113 is made of stainless steel or Teflon. Since this is limited to this embodiment, the fixing member 113 may be provided in various forms and methods. In particular, the fixing member 113 may be provided as a fastening member such as a bolt to fix the mesh plate 111 and the mesh frame 112 and then finish them with the Teflon material.

The nozzle unit 120 is provided to remove foreign substances filtered in the mesh unit 110. The nozzle unit 120, like the mesh unit 110, is provided inside the main body unit 130. The nozzle unit 120 is provided to be spaced apart from the mesh unit 110 by a set distance.

The distance between the nozzle unit 120 and the mesh unit 110 is selected within ±20 cm based on the radius length of the mesh unit 110. Since this is limited to this embodiment, it may vary depending on the environment of the small organism blocking device 100 and the water supply pipe 10.

The nozzle unit 120 sprays washing water to clean the mesh unit 110. The washing water sprayed by the nozzle unit 120 is sprayed in a direction opposite to the direction in which constant water flows.

The nozzle unit 120 includes a nozzle fixing plate 121, a nozzle 123, and a flow hose 124. The nozzle fixing plate 121 is formed as a circular flat plate like the mesh plate 111.

The nozzle fixing plate 121 includes a constant flow hole 121a and a nozzle coupling hole 121b.

The constant flow hole 121a is formed as a through hole in the front-back direction of the nozzle fixing plate 121. A plurality of constant flow holes 121a are formed in the nozzle fixing plate 121. The constant flow hole 122 is formed to allow constant water to pass through the nozzle fixing plate 121.

The size of the area of the mesh hole 111a is smaller than the size of the area of the constant flow hole 122. The constant flow first passes through the constant flow hole 122 and then through the mesh hole 111a.

Since the constant flows through the water supply pipe 10, which has a large cross-sectional area, and passes through the constant flow hole 122, which is smaller than the cross-sectional area of the water supply pipe 10, the constant flow occurs when passing through the constant flow hole 122. The flow speed becomes faster.

And, when passing through the mesh hole 111a, which is smaller in size than the cross-sectional area of the constant flow hole 122, the flow speed of the constant water becomes faster. In other words, the flow rate of clean water gradually becomes faster as it passes from the water supply pipe 10 to the small organism blocking device 100.

The nozzle coupling hole 121b is formed so that the nozzle 123 can be coupled to the nozzle fixing plate 121. The nozzle coupling hole 121b is formed between the neighboring constant flow holes 121a. The nozzle coupling hole 121b is formed by penetrating the nozzle fixing plate 121 in the front-to-back direction, and is formed with a screw thread and fastened to the nozzle 123.

More specifically, the nozzle coupling hole 121b has the center of a virtual circle circumscribed by an imaginary triangle formed by connecting the centers of the three neighboring constant flow holes 121a. formed to match.

The nozzle 123 is fastened to the nozzle fixing plate 121 through the nozzle coupling hole 121b. Washing water to remove foreign substances filtered into the mesh unit 110 is sprayed from each nozzle 123. The nozzle 123 is coupled to the nozzle fixing plate 121 so that the direction of the injection hole is toward the mesh unit 110.

When washing water is sprayed from the nozzle 123, a spray surface 123a of a certain area is formed. Adjacent spray surfaces 123a formed by spraying washing water from adjacent nozzles 123 form an intersection area 123b where some areas overlap.

The intersection area 123b is formed at a set ratio or less with respect to the spray surface 123a. In this embodiment, the intersection area 123b is formed at a ratio of 20% or less of the spray surface 123a. However, the 20% figure is limited to this embodiment and may be changed.

The euro hose 124 is connected to a plurality of nozzles 123. Washing water for washing the mesh unit 110 is supplied from the outside. Washing water is stored in the tank and supplied by the pump 127. The euro hose 124 and the pump 127 are connected to the main hose 125. A valve 126 is provided on the main hose 125 to open and close the main hose 125.

The flow hose 124 is formed with a plurality of branch pipes (not shown) branching from the flow hose 124. Each of the branch pipes (not shown) faces the respective nozzle 123, and each branch pipe (not shown) is connected to the nozzle 123.

When the washing water flows through the flow hose 124, it branches and flows into each branch pipe (not shown) and is sprayed into the mesh unit 110 through each nozzle 123.

The main unit 130 is provided between adjacent water supply pipes 10. The main body unit 130 is provided with the mesh unit 110 and the nozzle unit 120 therein.

The main unit 130 includes a main body pipe 131 and a connection housing 132.

The main body pipe 131 has a hollow flow path 131a formed to allow constant water to flow along the longitudinal direction. The main body pipe 131 is formed in a cylindrical shape. The mesh unit 110 is provided at the center of the main pipe 131 in the longitudinal direction, and the nozzle unit 120 is provided at a position spaced apart from the mesh unit 110 by a set distance. The nozzle unit 120 is fixed by a fixing method such as welding.

The main body pipe 131 is formed with a mesh unit insertion hole 131b. The mesh unit insertion hole 131b is formed at the center of the longitudinal direction and penetrates the inside and the outside in a direction intersecting the longitudinal direction.

The main body pipe 131 is formed with a mesh unit fixing groove 131e. The mesh unit fixing groove 131e is formed at a position opposite to the mesh unit insertion hole 131b. The mesh unit fixing groove 131e is formed concavely on the inner peripheral surface of the main body pipe 131.

The mesh unit 110 inserted into the interior of the main body pipe 131 through the mesh unit insertion hole 131b has one side of the mesh unit 110 first inserted into the interior of the main body pipe 131. It is inserted into the mesh unit fixing groove (131e). Since the mesh unit 110 is inserted into the mesh unit fixing groove 131e, the mesh unit 110 is fixed without shaking within the main body pipe 131.

The main body pipe 131 is further formed with a sealing member insertion groove 131c. When the mesh unit 110 is inserted into the main body pipe 131, constant water may leak through the mesh unit insertion hole 131a. To prevent this, the main body pipe 131 is provided with a sealing member 131f. The sealing member 131f is inserted into the sealing member insertion groove 131c.

The sealing member insertion groove 131c is formed concavely from the outer peripheral surface of the main body pipe 131 toward the inner peripheral surface. The cross-sectional size of the sealing member insertion groove 131c is formed to be larger than that of the mesh unit insertion hole 131e.

The main body pipe 131 is further formed with a drain hole 131e. Washing water used to wash the mesh unit 110 is discharged to the outside through the drain hole 131e. The drain hole 131e is formed by penetrating outward from the mesh unit fixing groove 131d.

The drain hole 131e is connected to a drain pipe (not shown), and the used washing water is completely discharged to the outside through the drain pipe (not shown). The drain pipe (not shown) penetrates the connection housing 132 and is connected to the drain hole 131e.

The connection housing 132 is provided to communicate the main body pipe 131 with the neighboring water supply pipe 10. The main body pipe 131 is provided inside the connection housing 132. Referring to FIG. 6, the connection housing 132 consists of a first housing part 132a and a second housing part 132b.

The first housing part 132a and the second housing part 132b are formed in a semicircular shape, and one side is hinged. Accordingly, the first housing part 132a and the second housing part 132b are rotated based on the hinge.

In order for the main body pipe 131 to be provided inside the connection housing 132, the first housing part 132a and the second housing part 132b are opened by rotating about the hinge. When the main body pipe 131 is located inside the connection housing 132, the first housing part 132a and the second housing part 132b are rotated and closed based on the hinge.

Each of the first housing part 132a and the second housing part 132b has a first fixing flange 132c formed on one side that is hinged and the other side corresponding to the other side. The first fixing flange 132c extends along the longitudinal direction of the connection housing 132.

When the first housing part 132a and the second housing part 132b are closed, the first fixing flange 132c of the first housing part 132a and the first fixing flange 132c of the second housing part 132b (132c) are in close contact with each other, and a fastening member (not shown) penetrates the first fixing flange (132c) to secure the first housing portion (132a) and the second housing portion (132b) from opening.

Meanwhile, second fixing flanges 131g extending radially from the outer peripheral surface are formed at both longitudinal ends of the main body pipe 131. When the main body pipe 131 is provided inside the connection housing 132, the second fixing flange 131g is caught on the longitudinal end of the connection housing 132. The second fixing flange 131g is caught on the longitudinal end of the connection housing 132 to prevent the main body pipe 131 from moving along the longitudinal direction inside the connection housing 132, and the main body pipe 131 Fix the position of (131).

Meanwhile, the small organism blocking device 100 may further include a timer (not shown) and a control unit 40.

The timer (not shown) transmits an alarm at each set time. The alarm transmitted by the timer (not shown) may be transmitted as a sound so that the worker can hear it, or may be transmitted to the control unit 40. In this embodiment, the case where the alarm of the timer (not shown) is transmitted to the control unit 40 will be described as an example.

When the control unit 40 receives an alarm from the timer (not shown), it shields the water supply pipe 10 to block the flow of water. Specifically, the control unit 40 is connected to the butterfly valve 20 and controls the operation of the normally open butterfly valve 20 to close when an alarm is received from the timer (not shown).

By providing the timer (not shown) and the control unit 40, the small organism blocking device 100 can be implemented in an automated manner.

Applying the small organism blocking device 100 as described above has the advantage of being able to clean the mesh unit in which foreign substances have been filtered even without separating the small organism blocking device 100 between water supply pipes.

In addition, the washing water used to clean the mesh unit can be discharged to the outside through the drain hole, which has the advantage of keeping the small organism barrier device clean.

Since the small organism barrier device is not separated from the water supply pipe, it has the advantage of saving the maintenance/repair costs and time required to maintain the small organism barrier device.

Although embodiments of the present invention have been described above with reference to the attached drawings, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing its technical idea or essential features. will be.

Therefore, the embodiments described above should be understood in all respects as illustrative and not restrictive, and the scope of the present invention is indicated by the claims described later, and the meaning and scope of the claims and their equivalent concepts are derived from the meaning and scope of the claims and their equivalent concepts. All resulting changes or modified forms should be construed as falling within the scope of the present invention.

10: Water supply pipes
20: Butterfly valve
100: Small organism blocking device
110: mesh unit
111: mesh plate
111a: mesh hole
112: mesh frame
113: Fixing member
120: nozzle unit
121: Nozzle fixing plate
122: Constant flow hole
123: nozzle
124: Eurohorse
125: Main hose
126: valve
127: pump
130: Main unit
131: body pipe
131a: Euro hollow
131b: Mesh unit insertion hole
131c: Sealing member insertion groove
131d: Mesh unit fixing groove
131e: drain hole
132: connection housing
132a: first housing portion
132b: second housing portion
132c: first fixed flange
132d: second fixed flange

Claims (6)

In the small biological blocking device that is coupled to the water supply pipe and removes foreign substances in the water,
a main body unit coupled between the water supply pipes that are adjacent to each other and spaced apart by a set distance;
a mesh unit provided inside the main body unit, through which constant water flowing inside the main body unit passes, but filters out foreign substances contained in the constant water; and
A nozzle unit is provided inside the main body unit and spaced apart from the mesh unit by a set distance, and supplies washing water in a direction opposite to the flow direction of the water so that the mesh unit can be cleaned.
The nozzle unit includes a nozzle fixing plate; A plurality of nozzles are coupled to penetrate the nozzle fixing plate and are provided to spray the washing water; and a washing water flow path hose connected to the plurality of nozzles and supplying the washing water to the nozzles from the outside.
The nozzle fixing plate includes a plurality of constant flow holes formed through the front and rear directions to allow constant water to flow; and one or more nozzle coupling holes formed between adjacent constant flow holes in the front-back direction and through which the nozzles are fastened,
The small organism blocking device blocks the flow of water when cleaning the mesh unit, sprays the washing water toward the mesh unit through the nozzle unit to wash the mesh unit, and the washing water used to clean the mesh unit is A small organism blocking device that drains the main unit to the outside and removes it. According to paragraph 1,
The mesh unit is,
A mesh plate with a plurality of mesh holes formed thereon;
a mesh frame that is closely coupled to the front and rear surfaces of the mesh plate and has a hollow area formed in a central area to expose the mesh hole; and
A small organism blocking device comprising a fixing member for fixing the mesh plate and the mesh frame. delete delete According to paragraph 1,
The nozzle coupling hole is,
A small organism blocking device formed so that the center of the nozzle coupling hole coincides with the center of an imaginary circle circumscribed by an imaginary triangle composed of the centers of the three neighboring constant flow holes. According to paragraph 1,
The small organism blocking device,
Timer that sends an alarm at a set time; and
A small organism blocking device that receives an alarm from the timer and further includes a control unit that shields the water supply pipe to block the flow of water when the alarm is received from the timer.

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