KR20070108452A - Nature-friendly engineering method to puryfy pollouted water - Google Patents

Abstract

An environment-friendly construction method to purify water in connection with a system for purifying polluted water is provided to improve construction efficiency, to discharge water quickly, and to prevent damage to a hydraulic line, by forming a rotating water gate larger than stream width, installing the hydraulic line through an axle, and forming a molding flask with respect to a rotating water gate. A waterway(11) is formed between both side support structures(10), and a housing(20) is installed at both sides of the support structure. A rotating water gate(30) is formed with an arc type gate plate(31), and two side plates(32) connected perpendicularly to the gate plate. An axle(33) is fixed to the support structure through the housing. An operating cylinder(40) is fixed to a wall in a space between the two side plates. A piston rod(41) of the operating cylinder is connected to an operating link(34) to be rotated. A power supply system comprises a solar cell plate(61), a solar power generation system(60), a charging circuit(62), a water level sensor(63), and a hydraulic control system(64). A molding flask under the rotating water gate is formed after equipping the rotating water gate.

Description

Nature-friendly engineering method to puryfy pollouted water in combination with a system that cleans contaminated water with clean water

1 is a perspective view of a rotating gate according to a first embodiment of the present invention.

Figure 2 is a front sectional view of the rotating gate according to the first embodiment of the present invention.

Figure 3 is a side cross-sectional view at the time of opening the rotating gate according to the first embodiment of the present invention.

Figure 4 is a side cross-sectional view at the time of closing the rotating gate according to the first embodiment of the present invention.

Figure 5 is a side cross-sectional view when discharging the lower end of the rotating gate according to the first embodiment of the present invention.

6 is a perspective view of a rotating gate according to a second embodiment of the present invention.

Figure 7 is a front sectional view of a rotating gate according to a second embodiment of the present invention.

8 is a sectional view of a fixed shaft according to a second embodiment of the present invention.

Figure 9 is a side cross-sectional view at the time of opening the rotating gate according to the third embodiment of the present invention.

Figure 10 is a side cross-sectional view at the closing of the rotating gate according to a third embodiment of the present invention.

Figure 11 is a side cross-sectional view of the lower discharge of the rotary door according to a third embodiment of the present invention.

12 is a side cross-sectional view at the time of opening the rotating gate according to the fourth embodiment of the present invention.

Figure 13 is a side sectional view at the time of closing the rotating gate according to the fourth embodiment of the present invention.

Figure 14 is a side cross-sectional view when discharging the lower end of the rotating gate according to the fourth embodiment of the present invention.

Figure 16 is a side cross-sectional view at the time of opening the rotating gate according to the fifth embodiment of the present invention.

Figure 17 is a side cross-sectional view of the rotary door in accordance with a fifth embodiment of the present invention.

Figure 18 is a side cross-sectional view when discharging the lower end of the rotating gate according to the fifth embodiment of the present invention.

Figure 19 is a side cross-sectional view at the time of opening the rotating gate according to the sixth embodiment of the present invention.

20 is a side cross-sectional view at the time of closing of the rotating gate according to the sixth embodiment of the present invention.

Figure 21 is a side cross-sectional view when discharging the lower end of the rotating gate according to the sixth embodiment of the present invention.

22 is a perspective view of a sluice gate in accordance with a seventh embodiment of the present invention.

23 is a front sectional view of a rotating gate to which a sluice is applied according to a seventh embodiment of the present invention;

Figure 24 is a cross-sectional view of the sluice plate of the rotating gate according to the eighth embodiment of the present invention.

25 is an exploded perspective view of a sluice gate in accordance with a ninth embodiment of the present invention;

Figure 26 is a side sectional view at the time of opening the rotating gate according to the tenth embodiment of the present invention.

Figure 27 is a side sectional view at the time of closing the rotating gate according to the tenth embodiment of the present invention.

Figure 28 is a side cross-sectional view when discharging the lower end of the rotating gate according to the tenth embodiment of the present invention.

29 is a cross-sectional view at the time of concrete pouring of the rotating gate according to the eleventh embodiment of the present invention.

30 is a cross-sectional view at the completion of the rotating gate according to the eleventh embodiment of the present invention.

31 is a cross-sectional view at the time of concrete pouring of the rotary door according to the twelfth embodiment of the present invention.

32 is a cross-sectional view of the completion of the rotating gate according to the twelfth embodiment of the present invention.

*** Explanation of symbols for the main parts of the drawing ***

10: support structure 11: water channel 12,12 ': formwork

12a: coupling pin 13: connecting member 20: housing

30: sluice 31: sluice plate 31a: engaging projection

31b: bottom plate 31c: intermediate plate 31d: top plate

31e: reinforcement stand 32: both side plates 32a: space part

32b: support protrusion 32c: coupling groove 32d: lid

33: fixed shaft 33a: hydraulic piping receiving groove 34,34 ': operation link

35: protective tube 36: filler 37,37 ': idle roller

38: Operation cable 39: Bolt 40,40 ': Operation cylinder

41, 41 ', 45, 47: Piston rod 43: Hydraulic piping 44: First operation cylinder

46: second operation cylinder 47: operating tube 51: first support roller

52: 1st chain 53: 2nd support roller 54: 2nd chain

60 solar power system 61 solar panel 62 charging circuit

63: sensor 64: hydraulic control system 71: sensing rod

72a ~ 72e: Proximity sensor 73: Control box 74a ~ 74e: Proximity sensor

The present invention relates to an environmentally friendly method for purifying contaminated water in combination with a system for purifying contaminated water with clean water, and more particularly, to improve manufacturability by minimizing the space occupied by the means for driving the rotating gate. Of course, the size of the floodgate is increased relative to the width of the river so that when the water level rises rapidly, it can be discharged in a faster time, and each of the floodgates is equipped with a solar power generation system, and is supplied with electric power therefrom. Minimize power consumption and prevent sudden power outages.Pipe all the hydraulic piping lines through the fixed shaft and the inner space of the water gate to clean the water gate's appearance, minimize foreign material jamming, and It is to prevent damage.

The present invention relates to an environmentally friendly method for purifying contaminated water in combination with a system for purifying contaminated water with clean water, and more particularly, to improve manufacturability by minimizing the space occupied by the means for driving the rotating gate. Of course, the size of the floodgate is increased relative to the width of the river so that when the water level rises rapidly, it can be discharged in a faster time, and each of the floodgates is equipped with a solar power generation system, and is supplied with electric power therefrom. Minimize power consumption and prevent sudden power outages.Pipe all the hydraulic piping lines through the fixed shaft and the inner space of the water gate to clean the water gate's appearance, minimize foreign material jamming, and It is to prevent damage.

As is well known, water flows through various routes into reservoirs such as rivers or reservoirs, so it is obvious that the incoming water contains large amounts of contaminants. Therefore, various methods have been proposed to purify the stored water, and conventional water purification methods include gravel contact oxidation method, reverse contact oxidation method, sewage treatment plant water purification method, chlorine input purification method, etc. Compared to the effect was insignificant.

In order to improve this, a device has been introduced to implement water purification by forming a vortex in water through a separate device to float contaminants and removing it, but this has the disadvantage of having a separate device to improve the water quality. Of course, the water purification area is very limited, so it was vulnerable to water quality improvement in a wider range.

In addition, the "natural water quality improvement method using a multi-stage water storage device" of the Patent Publication No. 2001-0000343, which was created by the present applicant, has a natural self-cleaning effect due to aeration because it is composed of one hydrology. There was a low flaw, and this defect further exacerbated the stored water by causing the algae phenomenon due to the aggregation of substances and contaminants generated by the confinement of water and contaminants trapped inside the water gate. There was a great fault letting.

Here, the term applied to this invention is demonstrated in order to raise the technical value of this invention.

"Material Acceleration" and "Material Scavenging" and "Law of Material Preservation Instinct" and "Material Aggregation" and "Material Coupling" and "Material Rejection" in which contaminated water quality contained in river water is naturally purified or deteriorated. Effect ”and“ material release ”.

Due to the difference in the mass and specific gravity of the material, all materials flow in the different places of the material, ie, in different states, depending on the specific gravity of the material.

By this action, clean water with heavy gravity flows in the lower layer of river water, and polluted water with light gravity flows in the upper layer of river water. The reality is that it flows faster than the lower seawater. This action occurs because the amount of pollutants contained in the water, ie the pollutant load, is high. This principle is defined as the "material acceleration phenomenon."

The reason why the water flowing in the stream is more polluted is because of the "acceleration of substance" and "agglomeration". Lightweight polluted water flows into the lower part of the river while lightly polluted water flows to the lower part of the stream by the action of gravity caused by the rotation of the Earth and the solar system. Pollution in river waters is further aggravated by the deterioration of contamination by "agglomeration", which combines with other pollutants that have been introduced.

The following describes the process of the "material indentation" that occurs when the material acceleration phenomenon is reversed. There is a close relationship between mass cutting action and material acceleration. The process of material ingestion is performed when contaminated river waters try to pass through the lower part of the hydrology, and the waters forming the river water are pushed to the upper part of the clean water with heavy gravity and then to the upper layer. Through the lower part, it tries to escape first. This principle is called "material cutting action". It is defined as. All materials on earth are different in volume or specific gravity, even if they are the same size, depending on the atomic weight and molecular weight of the materials that make up the material.

Next, all substances are "laws of substance preservation instinct" that seek to instinctively preserve the substance's constituents, and "material massing" exerted by these actions, and "material release" caused by material thrust. The operation will be described. Water has the characteristic of inducing another substance by instinctively accepting the penetrating substance and integrating the substance when water other than water penetrates into the structure of the water by the structural characteristic of water. In the present invention, such an action is defined as a "mass aggregation action".

In addition, when a certain impact is applied to water to shake off the contaminants that penetrate into the pure water molecular structure forming water crystals, the contaminants contained in the pure molecular structure of the water are immediately released from the water molecule. The action that comes out is "material release". It is defined as. In other words, the action of cleaning the polluted water by the force of impact from the outside is the "material release action". It is defined as. As described above, the mass-aggregation action is generated when the water storage system is constructed in such a way that the water storage system for confining the river water is discharged to the upper end of the inflowing river water such as concrete beams, conductive water gates, or rubber dams. Pollution is aggravated by the installation, but if you install a hydrologic system that discharges the river water to the lower end, the contaminated river water is naturally purified as the material grabbing action, the material jungle action and material removal action. Large dams can also be constructed in this way so that they do not add pollution. In addition, the installation of a hydrologic system configured to discharge only a portion of the stream water in the lower part of the water storage system increases the pollution. As the material is pushed by these heavy clean waters, it is pushed out of the outlet, and the pollution is further aggravated by the agglomeration of substances that combine with other pollutants. Due to material jungle action and mass aggregation, contaminated river water with a light weight other than the hydrosphere's outlet is absolutely impossible to move downstream of the stream itself, and combines with other substances. Contamination of contaminated materials becomes more and more contaminated by condensation. More specifically, the installation of a siphon-type water gate configured to selectively discharge only a portion of the outlet water formed at the lower end of the rubber dam or a portion of the bottom water trapped in the lower portion of the conductive water gate will result in a heavy gravity of clean water. Polluted waters that have a high specific gravity by pushing out these light waters and exiting the material first are pushed by clean waters that are heavy, and remain stagnant inside the water gate. In the state of absolutely failing to escape to the downstream part, the contaminated materials are bundled together and the contamination is further aggravated by the condensation of materials and the conjugation of materials that combine to create another material. When the water is confined using a submerged beam that discharges the influent to the upper part by these actions, the material condensation action and the substance generated by condensing the contaminants and water molecules together while confining the water inside the reservoir system There is a significant problem that contamination is rather weighted by the binding action.

The following describes the "law of substance conservation instinct".

All matters are rejected and pushed away if other foreign matter penetrates into the material structure of the material by the natural property of the material by the structural property of the material. Or the action of trying to escape from the substance or contaminants to permanently preserve the pure structure of the substance is defined as "law of the substance conservation instinct" in the present invention.

The following describes the "substance rejection action" caused by the "law of substance conservation instinct".

When all substances enter the water, they are diluted with the substances mixed in the water, and the aggregation of substances that add water pollution is not exerted from the beginning, but the structures of pure water molecules are bound directly by the substance rejection action that rejects the pollutants In other words, it rejects the agglomeration effect of substances and substances, and after a certain period of time, pollutants are released by natural reactions such as dissolved oxygen, solar heat, microorganisms and osmotic pressure. It gradually combines with water molecules and transforms into contaminants. As these substances are naturally decomposed again, the particles generated by natural decomposition are combined with other substances, which increases the pollution of the water. This is caused by the active green algae and the red tide occurring in the sea. . A substance called a terrestrial animal is a by-product produced by the aggregation of organic and inorganic substances.

The following describes mass decomposition, mass binding and mass flotation. The pure molecules of water react to try not to combine with other substances due to substance rejection caused by the "law of substance preservation instinct" to maintain pure water molecules. They are bound by mass-binding action that binds to molecules and at the same time become heavy, and decompose by the natural decomposition that occurs naturally while sitting on the bottom layer of the river. A repetitive action occurs in which the material binds to the water molecules and some of the pollutants coming from the upstream.

Contaminants contained in water molecules change into microparticles by self-decomposing self-decomposition, and then repeatedly bind to other contaminants while exerting repetitive flotation, which moves to the upper layer of the reservoir. The water molecules bound by are repeatedly bonded to become heavy at the same time as they are bound and sink to the bottom of the reservoir, increasing the pollution of the river water. They are called "mass decomposition", "material binding" and " Material injury action ".

The following describes the "material friction action", "material decomposition action" and "material binding action".

All materials are lighter than water or heavier than the specific gravity of water, but the sharp part of the particles and other clean water molecules that make up the clean water molecules by the pressure generated by the action of gravity and the pressure of water upon entering the water. Particles of contaminants that are sandwiched between water molecules, while a continuous blow is naturally applied to the particles of contaminants sandwiched between water molecules when active contact is made with the sharp parts of the particles. As the gradual wear occurs, the presence of the contaminant particles itself wears away, and the contaminated water is changed into clean water.

The natural purification of contaminated water by this action is defined as "natural water purification by material friction" and "academic term" as Hans action. When this action occurs, the polluted water is naturally purified, and the polluted substances are naturally decomposed without the action of oxygen.

In this process, the microparticles of incompletely decomposed substances are combined with the microparticles of water molecules and the microparticles of contaminants by the viscous and magnetic forces exerted by the microparticles exerted by the microparticles. Through it is transformed into particulates heavier than the specific gravity of the water molecules will be settled to the bottom of the river.

In the present invention, this action is defined as "material binding action".

That is, all materials generate polar particles through the process of natural decomposition, which naturally has viscous and magnetic forces.

Water friction is a natural frictional movement in which the pointy part of a material wears another material and its structure while the water molecules move actively by the action of gravity and the enviable motion occurring inside the water. Since the surface tension naturally occurs on the surface of all materials composed of particulate form, the pointed portion of the material naturally has a viscous force to bind to the material and a magnetic force to pull the material.

In the present invention, this action is defined as "material binding action".

The new materials produced by the material binding action generated through this process are heavier than the specific gravity of water, so that the material bonds and settles down to the reservoir where it is stored.

At this time, the contaminants of sedimentation sludge generated at this time generate a large amount of fine particles again through a continuous process in which they are decomposed again by material friction action and another decomposition action. The contaminated water quality is naturally revived as the particles are combined and rubbed again. If this occurs continuously, green algae occurs on land and red tide occurs in the sea. .

As soon as water enters the water, it is decomposed by the material friction action of the fine particles that make up the water molecules and the material decomposition actions that decompose the pollutants.

For example, the cold greens produced by the decomposition of iron are finer particles with a lighter specific gravity than water molecules.

Particles of the preliminary green matter generated through this process are settled in the bed while being transformed into a substance that is heavier than the specific gravity of water as the material binding action is performed with other particles decomposed by the particles forming another substance. Substances that occur when material binding occurs continuously are just sediments.

All polluted river water has a specific gravity of 1 percent through the process of all organic matters, inorganic matters, phosphorus and nitrogen in water, friction of matter, oxygen, microorganism, solar heat and natural decomposition of water molecules. Since it turns into water and herpes on the lower part of the rotating gate, when it is discharged through the lower part of the rotating gate, only the clean water is continuously discharged.

When the water flowing down from the upstream is discharged through the lower layer where water is stored, the material is possessed by the laminar flow which is naturally classified according to the difference of the specific gravity of the material according to the law of material grabbing and specific gravity. Since the location of herpes by the inherent mass is different, the material binding action is not performed, so that the pollution is not aggravated and the polluted water is naturally purified.

Therefore, if the water is confined to a certain place for a long time, the contamination is further increased by the material decomposition action and the material binding action, so that the water stored in the reservoir space always keeps the full water level and the water descending from the upstream of the lower part of the rotating gate It is the best way to purify the contaminated water quality while preventing the pollution of the river water from time to time.

 In addition, if the water in the reservoir is discharged through the lower part of the gate, it releases pollutants such as sedimentation sludge that are gathered by the material binding action that combines the substances contained in the water, and at the same time, accelerates the material acceleration phenomenon and material cutting. It generates phenomena, material decomposition action, material floating action, and the law of material preservation instinct to cleanse the polluted water naturally, and also discharge some water from the upper part of the stream through the upper part of the floodgate to float on the water. It is most desirable to purify the contaminated water quality by diluting it with light pollutants and the clean water discharged through the lower part of the gate.

However, in the case of commonly used rubber dams and conducting floodgates, the support shaft of the floodgate is fixed to the lower or upper side of the support structure so that the rubber dam is completely covered in order to discharge the water stored in the reservoir. It is limited to purify the river water because it is determined to discharge the stored water by using the drainage method and to open the conductive water gate to the top or the bottom of the water gate, and when the water is closed by closing the rubber dam or the water gate is closed The water stored in the reservoir is bound to stagnate, so that the agglomeration of the material is drastically deteriorated and the stored water quality is extremely deteriorated, and a great amount of sedimentation sludge is generated.

In addition, even if the fish tries to move upstream, the passage is closed, causing the ecosystem to be destroyed.

In the case of patent applications 10-2003-0057386, utility model applications 20-2002-0036293, 20-2002-0005190, and 20-2002-0036934, the hydroplate consists of a half moon on a circular rotating body and is perpendicular to both sides. It consists of both side plates formed in the direction to form a rotating gate, but the power means for driving the rotating gate is usually composed of a drive motor and a reduction gear group or a working cylinder and a multi-stage link, connecting rod, etc., the power transmission mechanism is very As it is complicated, there is a high energy loss as well as a high possibility of error. The power means for providing power to the gate and its transmission means are directly connected to the fixed shafts formed on both sides of the gate, so It had no choice but to break down easily due to direct contact with the stored water or foreign substances contained in the water.

In addition, in the state in which the conventional rotatable gate is closed, the water stored in the reservoir is stagnated as in the above-described general floodgate, thereby accelerating pollution of the water, as well as closing the moving passage of the fish, thus destroying the ecosystem. It was still inherent.

In addition, in the conventional rotating hydrograph, the power means for rotating the water gate is complicated, so that the space occupied by them becomes large, and the size of the space formed in the support structure for accommodating the power means increases, so that the size of the hydrological gate is relatively small. As a result, when the water level rises rapidly, such as flooding, the water in the reservoir could not be discharged in a short time, which could lead to a dangerous situation such as flooding, and as the space formed on the support structure grows, As much as the support force of the support structure is lowered, and thus there was a disadvantage that the support structure can be easily broken when a strong hydraulic pressure acts on the support structure continuously.

On the other hand, a hydraulic control system is basically applied to drive the rotating water gate, and general electric power is used to drive such a hydraulic control system. Since the water gate is very heavy, a lot of power is inevitably used to drive the water gate. In particular, if an unexpected power outage occurs, there is a disadvantage in that it is impossible to operate the gate.

The present invention has been proposed in view of this point, and fixes the fixed shaft to the support structure, rotatably fix the both sides of the sluice to the fixed shaft, both sides and the sluice plate through the cylinder inside or outside the two sides Rotate to open or close the waterway, or fix the fixed axis to the support structure in a fixed state and both side plates fixed, and open and close the waterway by rotating both side plates, the hydrology plate, the fixed shaft through the cylinder from the outside of the two side plates In addition to performing the basic functions as a water gate, it is not necessary to store a means for rotating the water gate inside the support structure, thereby improving the bearing capacity of the support structure, and also having a relatively large size of the water gate compared to the width of the river. The polluted water quality that can prevent the flooding by discharging the water quickly in the event of a flood can be defined as clean water. It is intended to provide an eco-friendly method to purify polluted water in combination with a system for ignition.

On the other hand, it generates electricity through photovoltaic power generation and supplies this electricity to the hydraulic control system that controls the rotating gate of the structure described above, minimizing the use of general electricity, minimizing the electricity bill, and sudden power outages. It does not happen.

Another aspect is to pipe all the hydraulic piping lines required for the rotating gate through the fixed shaft and the internal space of the water gate to clean the appearance, to prevent foreign matter jamming, and to extend the life of the hydraulic pipe.

Hereinafter, the present invention will be described in detail with reference to the embodiments presented and the accompanying drawings.

[First Embodiment]

1 is a perspective view of a rotating gate according to a first embodiment of the present invention, Figure 2 is a front sectional view of a rotating gate according to a first embodiment of the present invention, Figure 3 is a rotation according to a first embodiment of the present invention Figure 4 is a side cross-sectional view at the time of opening the water gate, Figure 4 is a side cross-sectional view at the time of closing the rotating gate according to the first embodiment of the present invention, Figure 5 is a side cross-sectional view at the bottom discharge of the rotating door according to the first embodiment of the present invention .

As shown in the figure, in the rotating water gate according to the first embodiment of the present invention, the channel 11 is formed between the two support structures 10, and the housing 20 is provided on the opposite surface of the both support structures 10. Covered with each, the fixed shaft 33 is fixed to the inner side of the support structure 10 through the housing 20, respectively, and both sides of the plate 32 is fixed to the both ends of the arc-shaped sluice plate 31 in a right direction 30 is provided so that both side plates 32 are rotatably fixed to the fixed shaft 33, respectively.

In addition, a space portion 32a is formed inside the two side plates 32, and a rear end portion of the operation cylinder 40 is fixed to one wall surface of the space portion 32a, and the space portion position of the fixed shaft 33 is The actuating link 34 is fixed, and the tip of the piston rod 41 of the actuating cylinder 40 is rotatably fixed to the actuating link 34.

In addition, the power supply system is configured to supply electricity produced through photovoltaic power generation to the hydraulic control system 64 that controls the rotation gate, and the power supply system includes a photovoltaic power generation system having a solar panel 61. The system 60, a charging circuit 62 for charging electricity generated through the photovoltaic power generation system 60, a water level sensor 63 for measuring the water level by receiving electricity collected in the charging circuit 62, and charging Power is supplied from the circuit 62 and consists of a hydraulic control system 64 for controlling the rotational gate according to the detection signal of the water level sensor 63.

When the working cylinder 40 is contracted in this configuration, the fixed shaft 33 and the working link 34 are fixed, so that the rear end portions of the working cylinder 40 are rotatably fixed between the two side plates 32 and between them. When the sluice plate 31 begins to rotate, the rotation angle of 90 ° when the sluice plate 31 is erected in the vertical direction to form a closed state is filled with water in the reservoir.

When the water gate 30 is further rotated in a state where water is stored in the reservoir space, a space is generated between the water gate 30 and the housing 20, and the lower layer water of the reservoir space is discharged through the space to be deposited on the bottom of the river. Foreign substances, such as sedimentation sludge, are released like river water, and the polluted water is naturally purified by material acceleration, material scavenging, material releasing, and material flotation.

In addition, when the water level rapidly increases, such as flooding, the operation cylinder 40 is extended as much as possible, and the water gate 30 is rotated according to the extension of the operation cylinder 40 such that the water plate 31 is the housing 20. The water gate 30 is in a state in which the water gate 30 is completely opened by being in close contact with the rounded portion of the bottom, and the top surface of the water gate plate 31 and the bottom surface of the housing 20 are horizontal when the water gate 30 is opened. Since the rounded side of the sluice plate 31 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, the water in the reservoir space can be smoothly discharged to the upper sluice plate 31 of the sluice 30. And, when the water is discharged foreign matters are not caught between the housing 20 and the water gate (30).

That is, according to the first embodiment of the present invention, the basic function as the rotating gate can be perfectly performed, and the supporting cylinder 40 for rotating the gate 30 is housed in both side plates of the gate 30 so that the supporting structure Workability can be improved without having a separate storage space in (10), and a water gate 30 having a relatively large size can be constructed compared to the width of the river, so that the water level rapidly increases, such as a flood. Faster discharge is possible, which can prevent the occurrence of crisis such as flooding.

Although not shown in the drawings, a packing member is provided between the two side plates 32 and the housing 20, and between the fixed shaft 33 and the both side plates 32, respectively, so that water in the storage space is provided on both sides of the plate 32. ) And the gap between the housing 20 or the gap between the fixed shaft 33 and the side plate 32 is prevented.

On the other hand, in the hydraulic control system 64 for controlling the rotating gate of the above-described structure, there are many members requiring electric power, such as a pump for circulating oil, various solenoid valves, and also the hydraulic control system 64 and the signal Since the water level sensor 63 to be replaced also requires power, power must be supplied to drive the hydraulic control system 64 and the water level sensor 63.

In the first embodiment of the present invention to cover the power required by the hydraulic control system 64 and the water level sensor 63 through the photovoltaic power generation system 60, the solar light through the solar panel 61 When electricity is collected and collected through the photovoltaic power generation system 60, the electricity is charged through the charging circuit 62, and the electricity collected in the charging circuit 62 is transferred to the hydraulic control system 64 and the water level sensor 63. It supplies them to drive them to control the rotating gate.

At this time, the solar panel 61 of the photovoltaic system 60 may be configured on the roof of the control box 73 or the management room of the water gate 30, or may be installed on the roof of the pagora around the water gate 30, In this way, the solar panel 61 can be utilized as a roof of the facility.

In addition, such a photovoltaic power generation system 60 is preferably provided at a place where the water gate 30 is installed to cover the power itself.

However, there are times when the weather is good, but sometimes it is bad, and because there is a difference in the amount of sunshine according to the season, the power to drive the hydraulic control system 64 and the water level sensor 63 to control the rotational gate purely by solar power generation It is very difficult to supply and demand, and therefore, it is desirable to use a combination of general electric power and solar power.

Second Embodiment

Figure 6 is a perspective view of a rotating gate according to a second embodiment of the present invention, Figure 7 is a front sectional view of the rotating gate according to a second embodiment of the present invention, Figure 8 is a fixed according to a second embodiment of the present invention A cross section of the shaft.

As shown, the second embodiment of the present invention relates to a hydraulic piping system when the operation cylinder 40 is located inside the two side plates 32 of the water gate 30, and the two side plates of the water gate 30 At the edge of the fixed shaft (33) rotatably fixed to 32 receives the hydraulic pipe 43 to pass through the space portion 32a of the two side plates 32, each hydraulic pipe 43 is a side plate ( It is withdrawn from the adjacent operating cylinder installation position located in the space portion (32a) of the 32 and connected to the working cylinder 40, respectively.

At this time, a plurality of hydraulic pipe receiving grooves (33a) in the longitudinal direction on the rim of the fixed shaft 33 may be accommodated in each of the hydraulic pipes 43, the inner diameter on the rim of the fixed shaft (33) The protective tube 35 and the fixed shaft (35) larger than the diameter of the fixed shaft 33 are inserted, and the hydraulic pipes 43 are installed between the fixed shaft 33 and the protective tube 35. The filling material 36 may be filled in the space between the 33), and any structure may be applied as long as it can accommodate each hydraulic pipe 43 at the edge of the fixed shaft 33.

When the water gate 30 is closed in the state configured as described above, the water is filled into the reservoir space, and when the water level becomes a certain level, the water gate 30 is opened to discharge the water filled in the reservoir space.

Since the opening and closing operation of the water gate is made by the operation cylinder 40 accommodated in the space 32a of the side plate 32 of the water gate 30, the operation cylinder 40 is not exposed to the outside of the water gate to have a neat appearance. Although it is possible, a pipe for supplying oil to the working cylinder 40 is required.

To this end, the present invention accommodates the hydraulic pipe 43 at the edge of the fixed shaft 33 so as to communicate with the space portion of both side plates 32, and closes the cylinder connection position of the space portion 32a of both side plates 32. By drawing through and connected to the operation cylinder (40), respectively, in this way, the hydraulic pipes 43 are not arranged to the outside of the water gate 30 is very clean appearance of the water gate 30, the hydraulic pipe 43 Twisting does not occur between the two does not affect the operation of the operation cylinder 40 can be improved the reliability of the operation.

In addition, since most of the hydraulic pipe 43 is accommodated in the space 32a of the fixed shaft 33 and both side plates 32 to be cut off from the outside, it is possible to minimize the probability that the hydraulic pipe 43 is damaged by external force. , There is no risk of causing environmental pollution because foreign matter is not caught in the hydraulic pipe 43.

At this time, when forming a plurality of hydraulic pipe receiving groove (33a) on the rim of the fixed shaft 33 to accommodate the hydraulic pipe 43 to the hydraulic pipe 43 is very easy to receive instead of the hydraulic pipe 43 and When the hydraulic pipe receiving groove 33a is not tight and the protective pipe 35 is covered on the outside of the fixed shaft 33, and the filling material 36 is filled in the state in which the hydraulic pipe 43 is accommodated therebetween. There is an advantage that the hydraulic pipe 43 does not flow, but the operation of accommodating the hydraulic pipe 43 will be very difficult and costly to be installed and used according to the user's preferences.

In addition, in the case of the operation cylinder 40, since the hydraulic pipe 43 is made of the inlet pipe and the discharge pipe, it is obvious that the hydraulic pipe 43 always has an even number, and thus the hydraulic pipe receiving groove 33a on the fixed shaft 33. Of course, when forming the 2, 4, 6, 8 ... it is natural to form an even number.

And, since the hydraulic pipe 43 according to the second embodiment of the present invention can be made of any material such as metal, synthetic resin, rubber, and the like, the scope thereof is not limited, and as described above, both side plates 32 of the gate 30 are as described above. The number of hydraulic pipes 43 can also be increased or decreased to suit the number of working cylinders 40 or hydraulic mechanisms accommodated in the space portion 32a of the hydraulic pipes 43.

Third Embodiment

9 is a side cross-sectional view at the time of opening the rotating gate according to the third embodiment of the present invention, FIG. 10 is a side cross-sectional view at the time of closing the rotating door according to the third embodiment of the present invention, and FIG. 11 is a third cross-sectional view of the present invention. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the waterway 11 is formed between the two support structures 10, the rotating door according to the third embodiment of the present invention, the housing 20 on the opposite surface of the two support structures 10, respectively The fixed shaft 33 is fixed to the inside of the support structure 10 through the housing 20, and both sides of the water plate (32) are fixed at right angles to both ends of the arc-shaped sluice plate 31. 30 is provided so that both side plates 32 are rotatably fixed to the fixed shaft 33.

In addition, a first operation cylinder 44 is installed at the upper wall storage side of the housing 20, and a first support roller 51 is rotatably installed at a horizontal position of the drainage side of the first operation cylinder 44. The first chain 52 is connected to the water storage side of the two side plates 32 from the distal end of the piston rod 45 of the operation cylinder 44 via the first support roller 51, and the middle part of the wall of the housing 20; The second operation cylinder 46 is installed on the drain side, and the second support roller 53 is rotatably installed on the water storage side horizontal position of the second operation cylinder 46, and the piston rod of the second operation cylinder 46 is installed. (47) The second chain 54 is connected to the drainage side of both side plates 32 via the second support roller 53 from the tip portion.

In this case, in the third embodiment of the present invention, the first chain 52 and the second chain 54 are used as an example, but various connection members such as ropes and wires may be used in addition to each of these chains.

In this configuration, when the first operation cylinder 44 is contracted and the second operation cylinder 46 is elongated, the water gate 30 is rotated in the closing direction, and when the rotation angle reaches 90 °, the water gate As the plate 31 is erected in the vertical direction, water is filled in the reservoir space by closing.

When the first operating cylinder 44 is contracted as much as possible while the water is stored in the storage space and the second operating cylinder 46 is extended as much as possible, a space is generated between the water gate 30 and the housing 20. Through this space, the subsurface water of the reservoir is discharged, and foreign substances such as sedimentary sludge deposited on the bottom of the stream escape like the river water, and contaminated water quality due to material acceleration, material cutting, material desorption, and material injury. This is naturally purified.

In addition, when the low water level rapidly increases, such as flooding, the first operating cylinder 44 is extended as much as possible, and the second operating cylinder 46 is contracted as much as possible, and the driving of the respective operating cylinders 44 and 46 is performed. Accordingly, the water gate 30 is rotated in the direction in which the water gate 30 is opened, and the water gate plate 31 is in close contact with the rounded portion of the bottom of the housing 20, so that the water gate 30 is completely opened. At the time of opening, the top surface of the sluice plate 31 and the bottom surface of the housing 20 form a horizontal state, and the rounded side of the sluice plate 31 closely adheres to the rounded portion of the bottom of the housing 20 in the downward direction. Therefore, the water in the reservoir space can be smoothly discharged to the top of the sluice plate 31 of the sluice 30, the foreign matter is not caught between the housing 20 and the sluice 30 during the discharge of the water.

That is, according to the third embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and each operating cylinder 44 and 46 for rotating the gate 30 is installed in the housing 20 to support it. It is not necessary to form a separate storage space in the structure 10 can improve the workability, it is possible to build a water gate 30 of a relatively large size compared to the width of the river, so that the water level rapidly increases, such as flood In this case, it is possible to discharge more quickly, thereby preventing the occurrence of a crisis situation such as flooding.

Although not shown in the drawings, a packing member is provided between the two side plates 32 and the housing 20, and between the fixed shaft 33 and the both side plates 32, respectively, so that water in the storage space is provided on both sides of the plate 32. ) And the gap between the housing 20 or the gap between the fixed shaft 33 and the side plate 32 is prevented.

In addition, the hydraulic control system 64 for controlling the rotating gate according to the third embodiment of the present invention can be configured to be supplied with electric power generated from the photovoltaic system 60 applied to the first embodiment of the present invention. Is self explanatory.

Fourth Embodiment

12 is a side cross-sectional view at the time of opening the rotating door according to the fourth embodiment of the present invention, Figure 13 is a side cross-sectional view at the closing of the rotating door according to a fourth embodiment of the present invention, Figure 14 is a fourth Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the waterway 11 is formed between the two support structures 10, the rotating door according to the fourth embodiment of the present invention, the housing 20 on the opposite surface of the two support structures 10, respectively The fixed shaft 33 is fixed to the inside of the support structure 10 through the housing 20, and both sides of the water plate (32) are fixed at right angles to both ends of the arc-shaped sluice plate 31. 30 is provided so that both side plates 32 are rotatably fixed to the fixed shaft 33.

In addition, an operation cylinder 40 'is rotatably installed on one side of the wall 20 of the housing 20 so that the piston rod 41' may be rotatably connected to the drain side of both side plates 32.

When the operation cylinder 40 'is expanded in the state configured as described above, the water gate 30 rotates in the closing direction, and when the rotation angle reaches 90 °, the water plate 31 stands in the vertical direction to form a closed state. Water fills up the reservoir.

When the working cylinder 40 'is extended as much as possible in the state where water is stored in the reservoir, a space is generated between the water gate 30 and the housing 20, and the bottom layer of the reservoir is discharged through the space. Foreign substances such as sewage sludge deposited on the ground escapes like river water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material releasing, and material flotation.

In addition, when the low water level rapidly increases, such as flooding, the operation cylinder 40 'is contracted as much as possible, and the floodgate 31 is rotated in the direction in which the water gate 30 is opened in accordance with the operation of the operation cylinder 40. The bottom surface of the housing 20 is in close contact with the rounded portion, and the water gate 30 is completely opened. When the water gate 30 is opened, the top surface of the water plate 31 and the bottom surface of the housing are horizontal. A state in which the rounded side of the sluice plate 31 is in close contact with the rounded portion of the bottom of the housing 20 is to be discharged smoothly to the upper sluice plate 31 of the sluice 30. And, when the water is discharged, these materials do not get caught between the housing 20 and the sluice 30.

That is, according to the fourth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and since the operation cylinder 30 'for rotating the gate 30 is installed in the housing, the support structure 10 is additionally provided. It is possible to improve workability without forming a storage space, and it is possible to construct a floodgate 30 having a relatively large size compared to the width of the river, so that when the water level increases rapidly, such as a flood, discharge is possible faster. Crisis situations such as flooding can be prevented.

Although not shown in the drawings, a packing member is provided between the two side plates 32 and the housing 20, and between the fixed shaft 33 and the both side plates 32, respectively, so that water in the storage space is provided on both sides of the plate 32. ) And the gap between the housing 20 or the gap between the fixed shaft 33 and the side plate 32 is prevented.

In addition, the hydraulic control system 64 for controlling the rotating gate according to the fourth embodiment of the present invention can be configured to be supplied with power generated from the photovoltaic power generation system 60 applied to the first embodiment of the present invention. Is self explanatory.

[Example 5]

FIG. 15 is a front sectional view of the rotatable sluice according to the fifth embodiment of the present invention, FIG. 16 is a side cross-sectional view when opening the rotatable sluice according to the fifth embodiment of the present invention, and FIG. 17 is a fifth embodiment of the present invention. Side cross-sectional view at the time of closing the rotating gate according to Figure 18 is a side cross-sectional view at the bottom discharge of the rotating gate according to the fifth embodiment of the present invention.

As shown, the waterway 11 is formed between the two support structures 10, the rotating door according to the fifth embodiment of the present invention, the housing 20 on the opposite surface of the two support structures 10, respectively The fixed shaft 33 is fixed to the inside of the support structure 10 through the housing 20, and both sides of the water plate (32) are fixed at right angles to both ends of the arc-shaped sluice plate 31. 30 is provided so that both side plates 32 are rotatably fixed to the fixed shaft 33.

In addition, a sealed space 12 is formed between the housing 20 and the support structure 10, and the working tube 46 is inserted into the fixed shaft connection portions of both side plates 32 to the outside, respectively. 46 is located in the sealed space 12, the operation link 34 'is fixed to the closed space position of the operating pipe 46, the operating cylinder 40' is rotatable on one side of the sealed space (12). It is fixed so as to, the front end of the piston rod 41 'of the operating cylinder 40' is made rotatably connected to the front end of the operating link 34 '.

When the actuating cylinder 40 'is contracted in such a configuration, the actuating tube 46 is rotated by the actuating link 34', so that the actuating tube 46 and the water gate 30 fixed thereto are closed. When the rotation angle is 90 °, the water gate plate 31 is vertically erected in a closed state, and water is filled in the reservoir space.

When the operating cylinder 40 'is contracted as much as possible in the state where water is stored in the reservoir, a space is generated between the water gate 30 and the housing 20, and the bottom layer of the reservoir is discharged through such a space. Foreign substances such as sewage sludge deposited on the ground escapes like river water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material releasing, and material flotation.

In addition, when the low water level is rapidly increased, such as flooding, the operation cylinder 40 'is extended as much as possible, and the water gate 30 is rotated in the direction in which the water gate 30 is opened in accordance with the operation of the operation cylinder 40'. The door 20 is in close contact with the rounded portion of the bottom of the housing 20, and the water gate 30 is completely opened. When the water gate 30 is opened, the top surface of the water gate plate 31 and the bottom surface of the housing are closed. A horizontal state is formed, and the rounded side of the sluice plate 31 closely contacts the rounded portion in the bottom direction of the bottom of the housing 20 so that the water in the reservoir space is smoothly discharged to the top of the sluice plate 31 of the sluice 30. The foreign matter may be caught between the housing 20 and the water gate 30 when the water is discharged.

That is, according to the fifth embodiment of the present invention, the basic function as the rotating gate can be perfectly performed, and since the fixed shaft 33 is fixed to the support structure 10, a support bracket for supporting the fixed shaft 33 is provided. Since there is no need for such a member, the size of the enclosed space 12 can be minimized, and as the size of the enclosed space 12 can be minimized, the water gate 30 having a relatively large size compared to the width of the river can be constructed. When the water level increases rapidly, such as flooding, it is possible to discharge more quickly, thereby preventing the occurrence of a crisis situation such as flooding.

Although not shown in the drawings, a packing member is provided between the two side plates 32 and the housing 20, and between the fixed shaft 33 and the both side plates 32, respectively, so that water in the storage space is provided on both sides of the plate 32. ) And the gap between the housing 20 or the gap between the fixed shaft 33 and the side plate 32 is prevented.

In addition, the hydraulic control system 64 for controlling the rotating gate according to the fifth embodiment of the present invention can be configured to be supplied with power generated from the photovoltaic system 60 applied to the first embodiment of the present invention. Is self explanatory.

[Sixth Embodiment]

Figure 19 is a side cross-sectional view when opening the rotating door according to the sixth embodiment of the present invention, Figure 20 is a side cross-sectional view when closing the rotating door according to a sixth embodiment of the present invention, Figure 21 is a sixth aspect of the present invention Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the rotatable gate according to the sixth embodiment of the present invention has a water channel 11 formed between the two support structures 10, and the housing 20 is provided on the opposite surface of the both support structures 10, respectively. The fixed shaft 33 is fixed to the inside of the support structure 10 through the housing 20, and both sides of the water plate (32) are fixed at right angles to both ends of the arc-shaped sluice plate 31. 30 is provided so that both side plates 32 are rotatably fixed to the fixed shaft 33.

In addition, a space portion 32a is formed in both side plates 32, and the operation link 34 is fixed at the space portion position of the fixed shaft 33, and the opposite side parallel to the tip of the operation link of the space portion 32a. The idle roller 37 is located at the site, and the other idle roller 37 'is rotatably positioned inside the fixed shaft 33, and the idle roller 37, idle from the tip of the operation link 34 is rotated. The operation cable 38 is connected to the outside through the inside of the fixed shaft 33 via the roller 37 '.

In addition, although not shown in the drawings, the outer side of the gate of the operation cable 38 may be configured to connect the winding rolls connected to the winches to wind or unwind the operation cable 38, and in addition to pulling the operation cable 38 Naturally, the release device should be connected to the position outside the water gate of the operation cable 38.

When the operation cable 38 is pulled in the state configured as described above, the position of the operation link 34 and the idle roller 37 becomes close, and the operation link 34 is fixed so that the water gate 30 rotates in the direction in which the water gate 30 is closed. When the rotation angle is 90 °, the sluice plate 31 is erected in the vertical direction to form a closed state is filled with water in the reservoir.

Pulling the operation cable 38 further in the state where the water is stored in the reservoir, the water gate 30 is further rotated to generate a space between the water gate 30 and the housing 20, and through this space the lower layer of the reservoir As the water is discharged, foreign substances such as sewage sludge deposited on the bottom of the stream are discharged like the river water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material desorption, and material flotation.

In addition, when the low water level is rapidly increased, such as flooding, the operation cable 38 is released, and the water gate 30 starts to rotate in the opening direction by its own weight, and the water plate 31 is bottomed out of the housing 20. When the contact with the rounded portion in the lower direction of the negative direction, the water gate is completely open, and when the water gate 30 is opened, the top surface of the water gate plate 31 and the bottom surface of the housing form a horizontal state and at the same time the water gate plate ( 31) the rounded side is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, water in the reservoir can be smoothly discharged to the top of the sluice plate 31 of the sluice 30, foreign matters when the water is discharged Are not caught between the housing 20 and the sluice 30.

That is, according to the sixth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the actuating cable 38 for rotating the gate 30 is connected to the gate 30 through the inside of the fixed shaft 33. Since it is drawn out to the outside of the support structure 10 does not need to form a separate storage space to improve the workability, it is possible to build a floodgate 30 of a relatively large size compared to the width of the river and Likewise, when the water level increases rapidly, faster discharge is possible, thereby preventing the occurrence of a crisis situation such as flooding.

In addition, although not shown in the drawings, the upper side of the side plate 32 is formed with a slit-type operation cable withdrawal groove to pull the operation cable 38 to rotate the water gate 30 when the operation cable 38 and both side plates It is obvious that the 32 should not interfere with each other, and the packing member is provided on the outside of the slit-type operation cable lead-out groove to prevent water from entering the space 32a inside the side plates 32. do.

In addition, a packing member is provided between the side plate 32 and the housing 20, and between the fixed shaft 33 and the side plate 32, respectively, so that water in the storage space is stored in the side plate 32 and the housing 20. It is prevented from leaking into the gap between the gap or between the fixed shaft 33 and the side plate 32.

In addition, the device for pulling or releasing the winding operation cable 38 to rotate the rotating gate according to the sixth embodiment of the present invention, the photovoltaic system 60 applied to the first embodiment of the present invention It is obvious that the power generated from the power supply can be configured.

[Seventh Embodiment]

FIG. 22 is a perspective view of a sluice gate of a sluice gate according to a seventh embodiment of the present invention, and FIG.

As shown, the seventh embodiment of the present invention relates to the structure of a sluice gate applied to a rotating sluice gate, and the sluice gate 30 has a sluice plate 31 having a rounded lower surface and a sluice plate 31. The upper side of both side plate 32 is rotatably fixed to a fixed shaft 33 which is composed of both side plates 32 connected at right angles to both sides and fixed to the support structure 10, both side plates 32 The bottom projections 32) are formed in the direction facing each other, respectively, and the sluice plate 31 is fixed by the bolts 39 in a state mounted on the support projections 32b.

At this time, the sluice plate 31 may be made of any material as long as it is a material that can withstand the water pressure of the reservoir, such as metal, rubber, and synthetic resin.

In addition, the coupling groove 32c is formed in the middle of the support protrusion 32b so as to improve the operational convenience and coupling force when the watermark plate 31 and the support protrusion 32b are coupled to each other. Coupling protrusions 31a are formed at the corresponding positions of both coupling grooves so as to be fitted into the coupling grooves 32c, and the coupling protrusions 31a are assembled to the coupling grooves 32c by the bolts 39.

This configuration makes it very easy to assemble the sluice plate 31 and the two side plates 32 when constituting the sluice 30, and the sluice plate 31 and the two side plates 32 to each other according to their functional characteristics. It can be made of other materials to reduce the manufacturing cost, and when any one of the members of the watermark plate 31 and the two side plates 32 forming the water gate 30 is damaged, only the member can be replaced, the water gate (30 ) Has the advantage of not having to discard the whole.

Of course, it is a matter of course that the sluice 30 having such a structure can be applied to both the sluice gates according to the first, third and sixth embodiments of the present invention.

[Eighth Embodiment]

24 is a cross-sectional view of the hydrologic plate of the rotating gate according to the eighth embodiment of the present invention.

As shown, the eighth embodiment of the present invention relates to a structure and a manufacturing method of a sluice plate applied to the rotating gate, the sluice plate 31 has a rounded bottom surface, the top surface is configured for this purpose Fixing both ends of the flat middle plate 31c and the top plate 31d to the bottom plate 31b rounded with a constant curvature, the top plate 31d so that the middle plate 31c and the top plate 31d do not cry or bend. The H-shaped reinforcing table 31e is fixed to the center portions of the intermediate plate 31c and the lower plate 31b.

At this time, the upper plate 31d, the intermediate plate 31c, the lower plate 31b, and the reinforcing rod 31e constituting the sluice plate 31 may be welded or brazed, or assembled through a connecting member such as a bolt-nut. It may be configured, and the material constituting this may be made of a metal material such that welding or soldering, or coupling through a connecting member can be performed, or a rubber or synthetic resin material that can be joined using a connecting member. .

In this configuration, the sluice plate 31 can be light in weight while having both a shape and rigidity applicable to the rotating sluice according to the present invention, which is easy to handle, and is very convenient to manufacture, and greatly reduces manufacturing costs. There is an advantage to this.

Of course, the sluice plate 31 of such a structure is naturally applicable to the rotating gate according to the first embodiment, the third embodiment to the sixth embodiment of the present invention.

[Example 9]

25 is an exploded perspective view of a hydrological gate of a sluice gate according to a ninth embodiment of the present invention.

As shown, the sluice according to the ninth embodiment of the present invention, when the space portion 32a is formed inside the side plate 32, the side plate 32 to facilitate replacement or repair of the members housed therein. To configure one side of the prefabricated, one side of both side plate 32 is open to communicate with the space portion (32a), and has a lid 32d to seal such an open portion, the lid 32d It is configured to fasten with the bolt 39 against the open portion.

In this way, a power means such as an operation cylinder is accommodated in the side plate 32 to rotate the water gate 30 to drive the water gate 30, and when the failure occurs or becomes obsolete, the bolt 39 needs to be replaced. When the cap 32d is removed, the space 31a may be opened so that the power means or the member may be easily repaired or replaced through the open portion.

Of course, although not shown in the application of the ninth embodiment of the present invention, the inner edge surface of the lid 32b or the space portion of both side plates 32 is provided with a packing member on the open portion of the lid 32d and the space portion. Obviously, no leakage should occur due to the gap between (32a).

In addition, it is a matter of course that the ninth embodiment of the present invention can be applied to both the rotating gate according to the first embodiment, the third embodiment to the sixth embodiment of the present invention.

[Example 10]

Figure 26 is a side cross-sectional view when opening the rotating gate according to the tenth embodiment of the present invention, Figure 27 is a side cross-sectional view when closing the rotating gate according to the tenth embodiment of the present invention, Figure 28 is a tenth aspect of the present invention Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the tenth embodiment of the present invention is to adjust the distance between the water gate 30 and the bottom of the housing 20 according to the water level, the inflow water amount, the inflow rate, the first embodiment of the present invention , The rotating doors are configured according to the third to sixth embodiments, and the sensing rods 71 are fixed to the reservoir sides of both side plates 32, and the plurality of proximity sensors 72a are sequentially formed on the housing 20. 72e), the control box 73 for controlling the water gate 30 is formed by forming the proximity sensor control buttons (74a ~ 74e) according to the number of each proximity sensor (72a ~ 72e).

At this time, the position of the proximity sensor (72a ~ 72e) to share the center of rotation of the water gate (30) so that when the detection rod 71 is in close proximity when the detection rod 71 is rotated together with the water gate (30) Obviously, the position of the proximity sensors 72a to 72e may vary depending on the size of the water gate 30, the average inflow of water, and the climatic conditions. It shows the example which installed five 72e).

In addition, the position of the proximity sensor (72a ~ 72e) may also vary depending on the size of the water gate (30), the average amount of water inflow, climatic conditions, for example, the number of the proximity sensor (72a ~ 72e) to each of the five If the distance between the proximity sensor (72a ~ 72e) is composed of 5cm intervals can be adjusted to the difference between the water gate 30 and the bottom of the housing 20 up to 20cm difference.

When the first proximity sensor control button (74a) of the control box 73 in the state configured as described above is set by pressing, and when the water gate (30) is rotated to the closed position, the first proximity sensor (72a) is operated to operate the rod 71 When approaching the first proximity sensor 72a, the sensor detects the signal and transmits the detection signal to the integrated control system (not shown). The integrated control system controls the oil supply according to the detected signal to control the water gate 30. By stopping, the water gate 30 can be stopped in a closed state, and in this state, water is filled in the reservoir space.

When a lot of water is filled in the reservoir, the first proximity sensor 72a is turned off, and the second proximity sensor control button to the fifth proximity sensor control button 74b to 74e according to the water level of the reservoir, water inflow or inflow rate. If you select any one to rotate the water gate 30 in the setting state by pressing it when the detection bar 71 is approached to the corresponding proximity sensor (72b ~ 72e) as described above the proximity sensor (72b ~ 72e) The position is sensed and transmitted to the integrated control system through the control system, and the integrated control system controls the oil supply according to the detection signal to stop the water gate 30 to stop the water gate 30 and the bottom of the housing 20. It is possible to form a space in the space, and through this space, the lower layer water of the reservoir is discharged, and foreign substances such as sedimentary sludge deposited on the bottom of the stream are discharged like the stream water, thereby accelerating matter, The contaminated water due to stroke symptoms, substance liberation action, material injury would act naturally purify.

Of course, it is possible to control the distance between the water gate 30 and the bottom of the housing 20 according to the proximity sensor control buttons (74a ~ 74e) selected by the operator, the selection criteria of the proximity sensor control buttons (74a ~ 74e) Of course, the current weather conditions, water inflow or inflow rate, the water level of the water reservoir should be taken into consideration, for example, if the water inflow rate is not very fast, select the second proximity sensor control button (74b) to the water gate 30 and the housing The distance between the bottom of the (20) can be adjusted to 5cm, and if it is determined that the inflow rate of water is fast and the low water level rises quickly, the fifth proximity sensor control button 74e is selected to select the water gate 30 and the housing ( The distance between 20) can be adjusted to 20 cm.

In addition, the operation of each of the proximity sensor control buttons (74a ~ 74e) can be arbitrarily selected by the operator, based on the signals detected through the various sensors such as water level sensor, flow rate sensor, the self-calculation in the integrated control system automatically each sensor Obviously, you can select and control a button.

In addition, when the water level rapidly increases, such as flooding, the floodgate is completely opened to discharge the water in a short time to prevent flooding.

That is, according to the tenth embodiment of the present invention, in performing the basic function as the rotating gate, the gap between the water gate 30 and the bottom of the housing 20 can be adjusted according to the current weather condition, low water level, inflow rate or inflow rate. Since there is an advantage that can be adjusted more finely.

[Eleventh embodiment]

FIG. 29 is a cross-sectional view of the revolving door according to the eleventh embodiment of the present invention, and FIG. 30 is a cross-sectional view of the revolving door according to the eleventh embodiment of the present invention.

As shown, the eleventh embodiment of the present invention relates to a construction method of a rotating gate, and in the case of a rotating gate, both side walls are first constructed when the supporting structure 10 is constructed in relation to being rotated about the fixed shaft 33. In the state of construction, the water gate 30 is installed on the supporting structure 10, and the concrete 12 is placed under the same curvature and the curing is placed under the lower surface of the water gate. When dismantling and constructing, when the water gate 30 is randomly moved when constructing the concrete of the lower surface of the water gate 30, the formwork 12 is damaged and thus the concrete structure of the desired shape cannot be obtained. (12) is installed between the water gate 30 and the formwork 12 to connect the connection member 13, such as bolt-nut, to integrate the formwork 12 with the formwork 12 so as not to rotate, After pouring and curing concrete, When dismantling is to complete by dismantling the connection member 13 together.

In this way, it is possible to form a rounded bottom of a clean shape without any jamming when the water gate 30 rotates.

Of course, it is obvious that the eleventh embodiment of the present invention can be applied to the production of any rotating gate, such as the first, third, and sixth embodiments of the present invention.

[Twelfth Example]

31 is a cross-sectional view when the concrete is poured in the rotating door according to the twelfth embodiment of the present invention, Figure 32 is a cross-sectional view when completing the rotating door according to the twelfth embodiment of the present invention.

As shown, the twelfth embodiment of the present invention also relates to the construction method of the sluice gate, and similarly to the eleventh embodiment of the present invention, when the support structure 10 is constructed, both side walls are first constructed in the sluice gate 30. ) Is installed on the support structure (10), the formwork 12 'of the same curvature is installed directly under the lower surface of the water gate, and the bolt-nut connection between the water gate 30 and the formwork 12' The member 13 'is connected and cured by pouring concrete in an integrated state with the formwork 12' so that the water gate 30 is not rotated. The coupling pin 12a is embedded in the bottom of the support structure 10 to be a concrete structure, and when the bottom of the support structure 10 is cured, the water gate 30 and the formwork 12 'are interposed therebetween. The connection member 13 'which was connected is dismantled and completed.

That is, when constructing the bottom of the support structure 10 with concrete, the formwork 12 'is to be integrated with the bottom of the support structure 10 of the concrete structure, after which the formwork 12' of the support structure It forms the bottom of the channel, which is always fixed to the floor.

Therefore, since the bottom portion of the waterway is always in contact with water, the formwork 12 'is preferably made of a material such as non-ferrous metal or synthetic resin or rubber having corrosion resistance without using wood.

In addition, although the coupling pin 12a is also illustrated in the figure by taking a sharper shape toward the lower portion as an example, it is apparent that it can be configured in various shapes such as a tooth shape so that the formwork 12 'is not detached from the buried state once. .

In this way, it is possible to form a rounded bottom of a clean shape without any jamming at the time of rotation of the water gate 30, as well as to dismantle only the connecting member after curing of the concrete structure, the construction is very easy, the bottom of the waterway Since the formwork 12 'is padded, there is an advantage that can enhance the rigidity of this area.

Of course, it is obvious that the twelfth embodiment of the present invention can be applied to the production of any rotating gate, such as the first, third, and sixth embodiments of the present invention.

As described above, in the present invention, the fixed shaft is fixed to the support structure, and the power means for rotating the floodgate is located inside or outside both sides of the floodgate, so it is necessary to form a separate sealed space inside the support structure. It can improve workability and support capacity of support structure, and it can form a relatively large sized hydrology compared to the width of river, so that when water level rises at high speed such as flood, It can be discharged in time, which has the advantage of preventing the occurrence of dangerous situations such as flooding, and each hydrology can be operated by electricity generated through solar power generation, which saves the cost of using general electricity. In addition, it is possible to use electricity stored in the solar power generation to prevent the occurrence of a power outage.

In addition, when the power means are stored in both sides of the sluice can be connected to the hydraulic line through the fixed shaft has the advantage that the appearance is not only clean, but also to prevent damage to the hydraulic line, the sluice plate in the composition of the sluice Since both side plates and fixed shafts can be assembled to each other, they can be made of different materials according to their functional characteristics, which can reduce manufacturing costs. Will be able to cure the concrete in the fixed state of the formwork and the rotating gate when the construction of the rotating gate is that there is an advantage that can build a concrete structure with a clean round surface without a separate post-treatment process.

Claims (13)

A water channel 11 is formed between the two side support structures 10, and the housings 20 are respectively covered on opposite surfaces of the both side support structures 10, and both sides are perpendicular to both ends of the arc-shaped hydrology plate 31. In the rotating gate that is fixed to the water gate 30, the plate 32 is fixed rotatably between the housing 20 to open and close the waterway 11, A fixed shaft 33 constituting the rotation center of the floodgate 30 is fixed to the wall surface of the support structure 10 through the housing 20; A space portion 32a is formed inside the two side plates 32, and a rear end portion of the operation cylinder 40 is fixed to one wall surface of the space portion 32a, and the space portion of the fixed shaft 33 Fixing the operation link 34, the front end of the piston rod 41 of the operation cylinder 40 is rotatably fixed to the operation link 34, the side plate 32 in accordance with the expansion and contraction of the operation cylinder (40) ) And opening and closing the waterway 11 while rotating the watermark plate 31 to form a space between the water gate 30 and the bottom of the housing 20 to discharge the contaminated water in the reservoir space through this. Eco-friendly method for purifying water quality by combining with the system for purifying polluted water with clean water, characterized in that the purified water quality. The method of claim 1, At the rim of the fixed shaft 33 accommodates the hydraulic pipe 43 to pass through the space portion 32a of the two side plate 32, each of the hydraulic pipe 43 is the space of the two side plate 32 Eco-friendly to clean the water quality by combining with the system for purifying the contaminated water with clean water, characterized in that it is withdrawn from each of the adjacent operating cylinder 40 installation position located in the portion and connected to the operation cylinder 40, respectively Method. A water channel 11 is formed between the two side support structures 10, and the housings 20 are respectively covered on opposite surfaces of the both side support structures 10, and both sides are perpendicular to both ends of the arc-shaped hydrology plate 31. In the rotating gate that is fixed to the water gate 30, the plate 32 is fixed rotatably between the housing 20 to open and close the waterway 11, A fixed shaft 33 constituting the rotation center of the floodgate 30 is fixed to the wall surface of the support structure 10 through the housing 20; The first operation cylinder 44 is installed on the wall upper water storage side of the housing 20, and the first support roller 51 is rotatably installed on the drainage side horizontal position of the first operation cylinder 44. A first chain (52) is connected to the water storage side of the both side plates (32) via the first support roller (51) from the tip of the piston rod (45) of the first operating cylinder (44); The second operation cylinder 46 is installed at the drainage side of the wall middle portion of the housing 20, and the second support roller 53 is rotatably installed at the water storage side horizontal position of the second operation cylinder 46. The second chain 54 is connected to the drain side of the two side plates 32 via the second supporting rollers 53 from the end of the piston rod 47 of the second working cylinder 46 to connect the respective working cylinders ( 44 and 46, opening and closing the waterway 11 while rotating the both side plate 32 and the sluice plate 31, the space between the sluice 30 and the bottom of the housing 20 Eco-friendly method to purify the water quality by combining with the system to purify the contaminated water quality to clean water, characterized in that by purifying the contaminated water quality by discharging the lower layer water in the reservoir through this. A water channel 11 is formed between the two side support structures 10, and the housings 20 are respectively covered on opposite surfaces of the both side support structures 10, and both sides are perpendicular to both ends of the arc-shaped hydrology plate 31. In the rotating gate that is fixed to the water gate 30, the plate 32 is fixed rotatably between the housing 20 to open and close the waterway 11, A fixed shaft 33 constituting the rotation center of the floodgate 30 is fixed to the wall surface of the support structure 10 through the housing 20; An actuating cylinder 40 'is rotatably installed at one side of the wall 20 of the housing 20, and a tip of the piston rod 41' of the actuating cylinder 40 'is rotated at the drain side of the both side plates 32. It is possible to connect and open and close the waterway 11 while rotating the both side plate 32 and the watermark plate 31 in accordance with the expansion and contraction of the operation cylinder (40 ') and the water gate (30) and the housing (20) Eco-friendly method to clean the water quality by forming a space between the bottom of the water purification system through the contaminated water to clean the contaminated water, characterized in that through the discharge of the lower layer water of the reservoir. A water channel 11 is formed between the two support structures 10, and the housings 20 are respectively covered on opposite surfaces of the two support structures 10, and are perpendicular to both ends of the arc-shaped hydrology plate 31. In the rotatable gate in which the sluice gate 30 on which the side plates 32 are fixed is rotatably fixed between the housings 20 to open and close the channel 11. A fixed shaft 33 constituting the rotation center of the floodgate 30 is fixed to the wall surface of the support structure 10 through the housing 20; An airtight space 12 is formed between the housing 20 and the support structure 10, and the operation pipe 46 is inserted into the fixed shaft connection portions of the both side plates 32 to the outside, respectively. The 46 is positioned in the sealed space 12, and the operating link 34 'is fixed to the sealed space position of the working pipe 46, and the working cylinder 40' is fixed to one side of the sealed space 12. ) Is rotatably fixed, and the tip of the piston rod 41 'of the actuating cylinder 40' is rotatably connected to the distal end of the actuating link 34 'according to the expansion and contraction of the actuating cylinder 40'. Opening and closing the water channel 11 while rotating the side plate 32 and the watermark plate 31 to form a space between the water gate 30 and the bottom of the housing 20 through the lower layer of the storage space Purifying contaminated water with clean water, characterized by purifying contaminated water by discharging water. Is an eco-friendly method that purifies water quality by combining with the system. A water channel 11 is formed between the two side support structures 10, and the housings 20 are respectively covered on opposite surfaces of the both side support structures 10, and both sides are perpendicular to both ends of the arc-shaped hydrology plate 31. In the rotating gate that is fixed to the water gate 30, the plate 32 is fixed rotatably between the housing 20 to open and close the waterway 11, A fixed shaft 33 constituting the rotation center of the floodgate 30 is fixed to the wall surface of the support structure 10 through the housing 20; The side plate 32 is formed with a space portion 32a, and the operation link 34 is fixed to the space portion position of the fixed shaft 33, and is parallel to the front end of the operation link of the space portion 32a An idle roller 37 is positioned on the opposite side, and another idle roller 37 'is rotatably positioned inside the fixed shaft 33, and the idle roller 37 is formed from the tip of the actuating link 34. As shown in FIG. ), By connecting the operation cable 38 to be pulled out through the inside of the fixed shaft 33 via the idle roller 37 'in order to pull or release the operation cable 38, the both sides Opening and closing the water channel 11 while rotating the plate 32 and the water gate plate 31 to form a space between the water gate 30 and the bottom of the housing 20 through which the bottom water of the reservoir space Polluted by purifying polluted water by discharge Eco-friendly method to purify water quality by combining with water purification system. The method according to any one of claims 1 and 3 to 6, The lower end portions of the two side plates 32 are respectively formed in the supporting projections 32b in a direction facing each other, and the water gate plate 31 is fixed by the bolt 39 in a state mounted on the supporting projections 32b. Eco-friendly method for purifying water by combining with the system for purifying contaminated water with clean water, characterized in that. The method according to any one of claims 1 and 3 to 6, The sluice plate 31 is fixed to both ends of the intermediate plate 31c and the top plate 31d of the flat shape on the rounded bottom plate 31b, the middle plate 31c and the top plate 31d cry or bend System to purify the contaminated water quality with clean water, characterized in that the H-shaped reinforcement (31e) is fixed to the center of the upper plate (31d), the intermediate plate (31c), the lower plate (31b) so as not to Eco-friendly method for purifying water by combining with water. The method according to claim 1 or 6, One side of the side plate 32 is opened to communicate with the space portion 32a, and has a lid 32d to seal the open portion, and bolts the lid 32d to the open portion. (39) Eco-friendly method for purifying water by combining with a system for purifying contaminated water quality of clean water, characterized in that the fastening. The method according to any one of claims 1 and 3 to 6, The sensing rod 71 is fixed to the reservoir side of the both side plates 32, and a plurality of proximity sensors 72a to 72e are sequentially installed to detect the position of the sensing rod 71 on the upper portion of the housing 20. In addition, the control box 73 for controlling the water gate (30) is contaminated water quality, characterized in that each of the proximity sensor control buttons (74a ~ 74e) is formed according to the number of each of the proximity sensors (72a ~ 72e) Eco-friendly method to purify water quality in combination with the system to purify clean water. The method according to any one of claims 1 and 3 to 6, The connecting member 13 is connected between the water gate 30 and the formwork 12 in a state where the formwork 12 is installed on the lower surface of the water gate 30 so that the water gate 30 is not rotated. It is integrated with the formwork 12, and after disintegration curing the concrete, when the disassembly of the formwork 12, the contaminated water quality, characterized in that disassembled together with a system for purifying the clean water with clean water Eco-friendly method to cleanse. The method according to any one of claims 1 and 3 to 6, A connecting member 13 'between the water gate 30 and the formwork 12' in a state in which a formwork 12 'having a plurality of coupling pins 12a on the bottom surface is installed on the lower surface of the water gate 30. ) Is integrated with the formwork 12 'so that the water gate 30 is not rotated, and after the curing of concrete, only the connecting member 13' is dismantled, and the formwork 12 'is connected to the waterway ( Eco-friendly method for purifying water quality by combining with the system for purifying contaminated water quality with clean water, characterized by forming the bottom of 11). The method according to any one of claims 1 and 3 to 6, A solar power generation system 60 having a solar panel 61, a charging circuit 62 for charging electricity generated through the solar power generation system 60, and electricity supplied to the charging circuit 62. A power supply system comprising a water level sensor 63 for measuring the water level, and a hydraulic control system 64 for supplying power from the charging circuit 62 and controlling the rotation gate according to the detection signal of the water level sensor 62. It is equipped with the environmentally friendly method for purifying the water quality in combination with the system for purifying the contaminated water quality to clean water, characterized in that for driving each rotating gate using the electricity generated from the photovoltaic power generation system (60).

Images