KR100952879B1 - Tidal flat experience water tank - Google Patents

Abstract

PURPOSE: A foreshore experience water tub is provided, which enables the breeding of lugworms, crabs, octopuses, fish, etc. inhabiting a foreshore. CONSTITUTION: A foreshore experience water tub comprises: a water tub(10) equipped with a floor plate inclined downward; an overflow pipe(20) which is detachably installed to a socket installed in the upper part of a drainpipe; a perforated board(30) installed at the center waterway of the water tub; a drainage manhole(40) covering the overflow pipe; a perforated pipe(50) equipped with a water pipe and a drainpipe; a filter non-woven fabric net(60) covering the perforated board and perforated board; granite soil(70), silica earth, and foreshore successively laminated on the top of the filter non-woven fabric net; and solenoid valves(S1,S2) respectively installed in the water pipe and drainpipe.

Description

Tidal flat experience water tank

The present invention relates to a tidal flat experience tank for eco-education to create a habitat environment for fish and shellfish inhabiting coastal tidal flats.

In general, the purpose of tidal flat ecological experience is to provide children with opportunities to create and change tidal flats on coastal tidal flats, and to learn the importance of nature by experiencing and learning children's lives.

However, conventionally, in order to experience the ecological education of tidal flats, there was a cumbersome problem of going directly to the coastal tidal flats.On the other hand, when tidal flats and biological fish and shellfishes are put in a general tank, fish and shellfish decay in less than a day, and the mud flats are mixed with water, and Juktang is As a result, there was a problem that the inhabited species died without being able to live.

An object of the present invention is to invent the conventional drawbacks as described above, by introducing microorganisms, such as organic oxygen into the tank in a naturally occurring principle to prevent the decay of living organic matter in the tidal flat, and also to create a coastal tidal flat habitat environment It is possible to raise tidal worms, crabs, octopus, larvae, fish and shellfish inhabiting tidal flats so that children who grow up can experience ecological education of tidal flats directly without having to go directly to coastal tidal flats. It is to provide a tidal-flat experience tank.

In order to achieve the above object, the present invention forms the bottom plate of the water tank inclined toward the central drain pipe, detachably mounts the overflow pipe to the socket installed on the upper side of the drain pipe, and installs a perforated plate in the central drain path of the water tank. And installing a drainage manhole surrounding the overflow pipe on the upper part of the perforated plate, arranging a perforated pipe having a water supply pipe for supplying seawater and a drainage pipe for discharging seawater on the upper part of the bottom plate, and the upper part of the perforated plate and the perforated pipe. Covering the filtration nonwoven fabric network, and then sequentially stacked Masato, silica sand and tidal flat on the filtration nonwoven fabric network, the solenoid valve is installed in the drain pipe and the water supply pipe of the perforated pipe, respectively.

According to the tidal-flat experience tank of the present invention, in creating a habitat environment for fish and shellfish inhabiting the coastal tidal flats, microorganisms and organic oxygen can be introduced into the tank on the basis of the naturally occurring principle to prevent the decay of living organic matter in the tidal-flat. In addition, by creating a coastal tidal-flat habitat in the tank, tidal flats, crabs, octopuses, flatfishes, and shellfish inhabiting the tidal flats can be reared. It is effective to experience education directly.

Hereinafter, the technical configuration of the present invention according to the accompanying drawings in detail.

1 to 5, the tidal flat experience tank of the present invention includes a water tank 10 having a bottom plate 12 inclined downward toward the central drain pipe 11; An overflow pipe (20) detachably mounted to the socket (11a) installed above the drain pipe (11); A perforated plate 30 installed in the central drainage passage 13 of the water tank 10; A drainage manhole 40 installed on the perforated plate 30 to surround the overflow pipe 20; A perforated pipe 50 arranged on the bottom plate 12 and having a water supply pipe 51 and a drain pipe 52; A filtration nonwoven fabric network 60 covering the perforated plate 30 and the perforated pipe 50 installed on the bottom plate 12; Masato (70) and silica sand (71) and tidal flat (72) are sequentially stacked on top of the filter nonwoven fabric (60); The solenoid valve (S1) (S2) provided in each of the water supply pipe (51) and the drain pipe (52) is characterized by the basic features of the technical configuration.

Here, the water tank 10 is made of transparent acrylic so that the ecology of the inner tidal flat 70 can be easily seen, the water tank 10 is provided with a bottom plate 12 inclined downward toward the central drain pipe (11). The upper portion of the drain pipe 11, the socket (11a) is installed, the drainage passage 13 is formed in the upper center of the floor plate 12, a plurality of reinforcement 14 is installed in the lower portion of the bottom plate (12). do. At this time, Figure 2 shows that the tank 10 is formed in a square, according to an embodiment of the present invention it will be apparent that the tank 10 may be formed in various shapes such as circular or oval as well as a square. .

The overflow pipe 20 is detachably mounted to the socket 11a installed above the drain pipe 11 to prevent the overflow of seawater. The overflow pipe 20 is made of PVC pipe which does not corrode. Is done. At this time, when filling the water tank 10, the overflow pipe 20 is plugged into the socket 11a, and when draining the sea water, the overflow pipe 20 is removed from the socket 11a. That is, when draining the seawater, the overflow pipe 20 is separated from the socket 11a, and when the seawater is filled in the water tank 10, the overflow pipe 20 is inserted into the socket 11a and the water level of the water tank 10 is removed. It can be adjusted, and continue to circulate the sea water overflows to the overflow pipe (20).

The perforated plate 30 is installed in the central drainage passage 13 of the water tank 10, the perforated plate 30 has a plurality of perforations 30a to discharge the seawater to the drain pipe 11 as shown in FIG. Perforated.

The drainage manhole 40 is installed on top of the perforated plate 30 to surround the overflow pipe 20, the purpose of installing the drainage manhole 40 is the bottom plate 12 when filling the water tank 10 As the water enters), the tidal flat 72 is submerged from the bottom as the sea water is pushed in, and when the water level reaches a certain level, it automatically overflows to the central overflow pipe 20 of the drainage manhole 40. to be.

The perforated pipe 50 is arranged above the bottom plate 12, the perforated pipe 50 is provided with a water supply pipe 51 for supplying sea water and a drain pipe 52 for discharging sea water, respectively, 51 and the drain pipe 52 are provided with solenoid valves S1 and S2, respectively. At this time, as shown in FIG. 3, the perforated pipe 50 is perforated with a plurality of perforations 50a to discharge the seawater supplied through the water supply pipe 51 into the water tank 10, and the water supply pipe 51 has a large amount. Natural seawater having an inorganic component is supplied, while the perforated pipe 50 is made of PVC pipe which does not corrode.

When the water supply pipe 51 of the perforated pipe 50 is connected to the higher side of the inclined bottom plate 12 to open water, the solenoid valve S1 is opened, and the drain pipe 52 of the perforated pipe 50 is inclined. Open solenoid valve (S2) only when drained by connecting to the lower side of the bottom plate (12).

The filter nonwoven fabric 60 is to cover the perforated plate 30 and the perforated pipe 50 installed on the bottom plate 12, the filter nonwoven fabric 60 is a sediment of seawater supplied through the perforated pipe 50 At the same time, the Masato 70 is prevented from escaping into the drain pipe 11.

The masato 70 and the silica sand (71) are sequentially stacked on the upper portion of the filtration nonwoven fabric 60, the masato 70 and the silica sand (71) to prevent the organic matter is decomposed in the tidal flat 72 do.

The tidal flat 72 is stacked on top of the silica sand 71, such a tidal flat 72 creates an environment in which the earthworm, crab, octopus, flatfish, fish and shellfish can inhabit. At this time, the mud flat 72 is used as it is taken from the coast having environmental conditions such as food, salt, organic matter and nutrients, dissolved oxygen, seabed sediment of the species to fully function.

The solenoid valves S1 and S2 are respectively installed in the water supply pipe 51 and the drain pipe 52 of the perforated pipe 50, and these solenoid valves S1 and S2 are automatically controlled by a controller. At this time, according to the present invention, it is preferable to make water supply and drainage in the same manner as the sea tide low tide natural environment 2 to 3 times a day.

According to the present invention, a plurality of perforated partitions 80 are installed in the water tank 10 to prevent the rolling of the Masato 70 at appropriate intervals. At this time, as shown in FIG. 3, a plurality of perforations 80a are perforated to allow the seawater to pass through the perforated partitions 80.

6 and 7 show a state in which the filtration system is connected to the present invention and the filtration system according to the present invention, and according to an embodiment of the present invention, the sump pipe 11 and the sump having a pump P1 (Sump) tank 100 is connected, the sump tank 100 is connected to the skimmer (skimmer) 200 having a pump (P2), the pump (P1) and the water supply pipe 51 is a water temperature regulator ( 300 and a sterilizer 400 are connected, and a solenoid valve S3 is installed between the water supply pipe 51 and the sterilizer 400, and the pump P1, the sump tank 100, the pump P2, the skimmer. Each of the connection lines 200, the water temperature controller 300, and the sterilizer 400 is characterized in that the solenoid valve (V) is installed.

Here, the sump tank 100 is connected to the drain pipes 11 and 51, and the sump tank 100 stores seawater discharged to the drain pipes 11 and 52. At this time, the sump tank 100 has a built-in filter for filtering foreign substances contained in the seawater, the sump tank 100 is provided with a pump (P1) for circulating the discharged seawater to the water supply pipe 51, the pump P1 is automatically controlled by the controller.

The skimmer 200 is connected to the sump tank 100, and the skimmer 200 removes proteins and impurities contained in seawater. At this time, the skimmer 200 is provided with a pump P2 for circulating the seawater from which proteins and impurities have been removed to the sump tank 100, and the pump P2 is automatically controlled by a controller.

The water temperature controller 300 and the sterilizer 400 is connected between the pump P1 and the water supply pipe 51, the water temperature controller 300 controls the cold temperature of the sea water, and the sterilizer 400 is included in the sea water. Remove the bacteria. At this time, the water temperature controller 300 is preferably configured as a cooler and a heater, the sterilizer 400 is preferably configured as a UV sterilizer.

The solenoid valve S3 is installed between the water supply pipe 51 and the sterilizer 400. The solenoid valve S3 is automatically controlled by the controller. At this time, the solenoid valve (S1) is opened when the sea water is supplied and shut off when circulating the sea water, the solenoid valve (S3) is shut off when water supply and sea water is opened when circulating the sea water.

The solenoid valve (V) is installed in each connection line of the pump (P1), sump tank (100), pump (P2), skimmer (200), filter (300), water temperature controller (400), sterilizer (500) In this way, the solenoid valve (V) is automatically controlled by the controller.

According to the present invention, the bio ball tank 500 for activating microorganisms is installed on the sump tank 100, and the bio ball tank 500 is connected to the water temperature controller 300.

Referring to the overall operation of the present invention, the experience of the mudflat experience tank configured as described above are as follows.

First, in the case of a tidal flat experience tank installed as shown in FIG. 4, water and drainage are performed in the same manner as the sea tide low tide low tide by the controller two to three times a day, and the solenoid valve S2 of the drain pipe 52 is closed. When the solenoid valve S1 of the water supply pipe 51 is opened in the state, the natural sea water is supplied to the water supply pipe 51, and the seawater supplied to the water supply pipe 51 is discharged to the perforation 50a of the perforated pipe 50 while the Masato ( 70) and the silica sand (71) and the tidal flat (72) is gradually raised. At this time, when the seawater is supplied in the water tank 10 above the appropriate water level, the seawater rising through the overflow pipe 20 is discharged to the drain pipe 11.

When the seawater is filled to the appropriate level in the water tank 10, the solenoid valve S1 is automatically stopped by the controller. In this state, microorganisms and organic oxygen are introduced into the water tank 10 on the basis of the naturally occurring principle. 10) The mud flats 72 create a living environment without corrosion.

When the proper time passes and the supply time of the seawater is reached, the solenoid valve S1 is opened as described above, and the seawater is automatically supplied. At this time, the seawater filled in the water tank 10 is tidal flat 72, silica sand 71, and Masato. While passing through the 70 and slowly discharged to the drain pipe 11 through the perforations 30a of the perforated plate 30, and in this state, the solenoid valve S2 of the drain pipe 52 is automatically opened and the perforated pipe 50 The seawater in the water is discharged to the sewer through the drain pipe 52. At this time, when draining the seawater, the overflow pipe 20 mounted on the socket 11a is taken out.

Next, when the filtration system is connected to the tidal-flat experience tank as shown in Figure 6 and 7 the seawater discharged to the drain pipe (11) (52) is stored in the sump tank 100, the seawater stored in the sump tank (100) Protein and impurities are removed while circulating back to the sump tank 10 via the skimmer 200, and the seawater from which the proteins and impurities have been removed is passed through the water temperature controller 300, the sterilizer 400, and the bioball tank 500. Circulating through the perforated pipe 50 through the 51 is discharged back into the water tank (10). At this time, the pumps P1 and P2 continue to operate for 24 hours, and the solenoid valves S1 and S2 are operated by timer operation only when water enters the water tank 10.

As shown in FIG. 6, the seawater circulated back into the water reservoir 10 through the filtration system according to the present invention is controlled to an appropriate temperature by the water temperature controller 300, and bacteria are removed by the sterilizer 400, and the bioball The microorganisms are activated by the tank 500.

According to the tidal-flat experience tank of the present invention, in order to create a habitat environment for fish and shellfish inhabiting the coastal tidal flats, it is natural in the tank 10 in which the Masato 70, the silica sand 71 and the tidal flat 72 are sequentially stacked. Since the seawater can be circulated like the sea tide and the ebb tide to create the same habitat environment as the natural environment, the tidal flat 72 in the tank (10) is structurally created a living environment without corrosion.

Therefore, the present invention can prevent the decay of living organic matter in the tidal flat 72 by introducing microorganisms, organic oxygen, etc. into the tank 10 on a naturally occurring basis, and also provides a coastal tidal flat habitat environment to the tank 10. There is an advantage that can be easily bred by the mudworms, crabs, octopus, larvae, fish and shellfish inhabiting the tidal flat 72.

In addition, the present invention can be easily installed anywhere without regard to the place, there is an advantage that children growing through this can directly experience the ecological education of the tidal flat in the near place without going directly to the coastal tidal flat.

Figure 1 is a side cross-sectional view showing the internal structure of the tank according to the present invention.

2 is a plan view of FIG.

3 is an enlarged cross-sectional view of portion “A” of FIG. 1.

Figure 4 is an exemplary view showing a state in which the Masato, silica sand, tidal flat is stacked in the interior of FIG.

5 is a perspective view showing a perforated plate and a drainage manhole according to the present invention.

Figure 6 is an exemplary view showing a state in which the filtration system is connected to the present invention.

7 is a block diagram of a filtration system according to the present invention.

<Code Description of Main Parts of Drawing>

10: tank 11: drain pipe

11a: socket 12: bottom plate

13: drainage channel 20: overflow pipe

30: punched plate 40: drainage manhole

50: perforated pipe 51: water supply pipe

52: drain pipe 60: filtration non-woven fabric

70: Masato 71: Quartz

72: mudflat 80: perforated partition

100: sump tank 200: skimmer

300: water temperature controller 400: sterilizer

500: Bio Ball Tank S1, S2, S3: Solenoid Valve

P1, P2: Pump V: Solenoid Belt

Claims (5)

A water tank (10) having a bottom plate (12) inclined downward toward the central drain pipe (11); An overflow pipe (20) detachably mounted to the socket (11a) installed above the drain pipe (11); A perforated plate 30 installed in the central drainage passage 13 of the water tank 10; A drainage manhole 40 installed on the perforated plate 30 to surround the overflow pipe 20; A perforated pipe 50 arranged on the bottom plate 12 and having a water supply pipe 51 and a drain pipe 52; A filtration nonwoven fabric network 60 covering the perforated plate 30 and the perforated pipe 50 installed on the bottom plate 12; Masato (70) and silica sand (71) and tidal flat (72) are sequentially stacked on top of the filter nonwoven fabric (60); Tidal flat experience tank comprising a solenoid valve (S1) (S2) respectively installed in the water supply pipe (51) and the drain pipe (52). The tidal flat experience tank according to claim 1, wherein the water tank (10) is made of transparent acrylic. The tidal flat experience tank according to claim 1, wherein a plurality of perforated partitions (80) are installed inside the water tank (10) to prevent the rolling of the Masato (70) at appropriate intervals. The sump tank 100 having a pump P1 is connected to the drain pipes 11 and 52, and the skimmer 200 having a pump P2 is connected to the sump tank 100. Is connected, the water temperature controller 300 and the sterilizer 400 is connected to the pump (P1) and the water supply pipe 51, a solenoid valve (S3) is installed between the water supply pipe 51 and the sterilizer 400, Tidal flat characterized in that the solenoid valve (V) is installed in each connection line of the pump (P1), sump tank (100), pump (P2), skimmer (200), water temperature controller (300), sterilizer (400) Experience tank. The tidal flat experience tank according to claim 1, wherein a bio ball tank (500) is installed at an upper portion of the sump tank (100), and the bio ball tank (500) is connected to a water temperature controller (300).

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