KR20070076579A - Nature-friendly engineering method to puryfy pollouted water - Google Patents

Abstract

An eco-friendly method for purifying water is provided to purify the polluted water when the water door is opened, by discharging the lower water of a water storage space through a space between a water door and a housing so as to discharge sludge, which is deposited on a bottom plate of the housing, with the lower water. A water door(30) is installed asymmetrically such that a water supply side is longer than a water storage side based on a rotary shaft(33). A packing member(40) is fixed to an outside of the water supply side of the water door. The water door is rotated at an angle of 90-360 degrees by driving two operative cylinders(51,61) so that the water door is opened or closed. When the water door is opened, a water door plate(31) and a bottom plate of a housing(20) become horizontal in order to discharge water smoothly. When the door is closed, a space between the water door and the housing is sealed by the packing member. A water storage space is significantly secured by a volume corresponding to the sum total of a length of the water supply side asymmetrically extended based on the rotary shaft, a height of the water supply side rounded downwardly from the bottom plate of the housing, and a thickness of the packing member between the water door and the bottom plate of the housing.

Description

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

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

FIG. 2 is a detailed view of portion A of FIG. 1; FIG.

Figure 3 is a front sectional view of the rotating gate according to the first embodiment of the present invention.

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

Figure 5 is a side cross-sectional view at the maximum rise of the rotating gate according to the first embodiment of the present invention.

Figure 6 is a side sectional view at the time of closing of the rotating gate according to the first embodiment of the present invention.

Figure 7 is a side cross-sectional view during the opening operation of the rotating gate according to the first embodiment of the present invention.

Figure 8 is an exploded perspective view of a rotating gate according to a second embodiment of the present invention.

Figure 9 is a front sectional view of the rotating gate according to the second embodiment of the present invention.

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

Figure 11 is a side cross-sectional view at the time of closing of the rotating gate according to the second embodiment of the present invention.

Figure 12 is a side cross-sectional view when opening the lower end of the rotating door according to a second embodiment of the present invention.

Figure 13 is an exploded perspective view of a rotating gate according to a third embodiment of the present invention.

14 is a front sectional view at the time of opening the rotating gate according to the third embodiment of the present invention.

Figure 15 is a side cross-sectional view when opening the rotating gate according to the third embodiment of the present invention.

16 to 18 is an operation when closing the rotating gate according to a third embodiment of the present invention.

19 is a side cross-sectional view of a closed state of a rotating door according to a third embodiment of the present invention.

20 is a front sectional view at the time of opening the rotating gate according to the fourth embodiment of the present invention.

Figure 21 is a side sectional view at the time of closing of the rotating gate according to the fourth embodiment of the present invention.

Figure 22 is a side cross-sectional view at the time of opening the rotating gate according to the fifth embodiment of the present invention.

Figure 23 is a side cross-sectional view at the time of maximum operation cylinder of the rotating gate according to the fifth embodiment of the present invention.

Figure 24 is a side cross-sectional view at the time of maximum injury of the rotating gate according to the fifth embodiment of the present invention.

Figure 25 is a side cross-sectional view at the time of closing the rotating gate according to the fifth embodiment of the present invention.

Figure 26 is a front sectional view of a rotating gate according to a sixth embodiment of the present invention.

Figure 27 is a side sectional view when opening the rotating gate according to the sixth embodiment of the present invention.

Figure 28 is a side cross-sectional view at the time of the maximum operation cylinder of the rotating lock according to the sixth embodiment of the present invention.

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

30 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 31a is a side cross-sectional view at the time of opening the rotating gate according to the seventh embodiment of the present invention.

31B is a perspective view of the sluice operating part when opening the sluice door according to the seventh embodiment of the present invention.

32A is a side sectional view at the time of closing of a rotating gate according to a seventh embodiment of the present invention;

32B is a perspective view of a sluice operating part when closing the sluice door according to the seventh embodiment of the present invention;

Figure 33a is a side cross-sectional view of the lower discharge of the rotary door according to the seventh embodiment of the present invention.

Figure 33b is a perspective view of the sluice operating part when the lower discharge of the sluice door according to the seventh embodiment of the present invention.

34 is a sectional front view of a rotating gate according to an eighth embodiment of the present invention;

35 is a sectional front view of a rotating water gate according to a ninth embodiment of the present invention;

36 is a front sectional view of a rotating water gate according to a tenth embodiment of the present invention.

Figure 37 is a side sectional view at the time of closing of the rotating gate according to the eleventh embodiment of the present invention.

Fig. 38 is a side sectional view of the case where the lower layer water is discharged in the closed state of the rotating gate according to the eleventh embodiment of the present invention.

39 is a side cross-sectional view when opening the rotating gate according to the eleventh embodiment of the present invention.

40 is a detailed perspective view of the sluice operating part of the rotating gate according to the twelfth embodiment of the present invention.

41 is a sectional front view of the sluice operating part of the rotating gate according to the twelfth embodiment of the present invention.

42 is a side cross-sectional view at the closing of a sluice door according to a twelfth embodiment of the invention;

Figure 43 is a side cross-sectional view when discharging the bottom of the rotating gate according to the twelfth embodiment of the present invention.

44 is a perspective view of a rotating gate according to a thirteenth embodiment of the present invention;

45 is a side cross-sectional view of the revolving door according to the thirteenth embodiment of the present invention;

Figure 46 is a side sectional view of the rotating hydrograph according to the thirteenth embodiment of the present invention.

47 is a perspective view of a rotating gate according to a fourteenth embodiment of the present invention.

48 is a side sectional view at the time of closing of a rotating gate according to a fourteenth embodiment of the present invention;

49 is a side cross-sectional view of the rotating hydrograph according to the fourteenth embodiment of the present invention;

50 is a perspective view of a rotating door according to a fifteenth embodiment of the present invention;

Fig. 51 is a side sectional view at the time of closing of a rotating gate according to a fifteenth embodiment of the present invention.

Figure 52 is a side cross-sectional view when discharging the lower end of the rotating gate according to the fifteenth embodiment of the present invention.

Figure 53 is a side sectional view when opening the rotating gate according to the fifteenth embodiment of the present invention.

54 is a sectional side view at the start of the rotational gate start according to the sixteenth embodiment of the present invention;

55 is a side cross-sectional view of the revolving door according to the sixteenth embodiment of the present invention.

56 is a perspective view of the sluice gate of the rotating gate according to the seventeenth embodiment of the present invention;

Fig. 57 is a side sectional view of a rotating water gate according to an eighteenth embodiment of the present invention.

58 is a sectional front view of a sluice door according to a nineteenth embodiment of the present invention;

Fig. 59 is a side sectional view at the time of starting in the open state of the rotating gate according to the nineteenth embodiment of the present invention.

60 is a side cross-sectional view of the revolving door according to a nineteenth embodiment of the present invention;

61 is a side cross-sectional view when foreign matter is caught in the rotating gate according to the nineteenth embodiment of the present invention.

62 is an exploded perspective view of an installation part of a packing member of a rotating gate according to a twentieth embodiment of the present invention.

63 is a side cross-sectional view of a closed state of a sluice door according to a twentieth embodiment of the present invention;

64 is a side cross-sectional view of a connecting portion of the rotary shaft of the rotating gate according to the twenty-first embodiment of the present invention.

65 is a state diagram when closing the rotating gate according to the twenty-second embodiment of the present invention.

66 is a side view of a support structure according to a twenty third embodiment of the present invention.

67 is a hydraulic circuit diagram of a rotating gate according to a twenty-third embodiment of the present invention.

68 is a perspective view of a rotating gate according to a twenty-fourth embodiment of the present invention;

69 is a sectional front view of a rotating water gate according to a twenty-fourth embodiment of the present invention;

70 is a side sectional view at the time of opening the rotating gate according to the twenty-fourth embodiment of the present invention;

71 is a side cross-sectional view of the revolving door according to a twenty-fourth embodiment of the present invention;

72 is a side cross-sectional view of the lower discharge of the rotary door according to the twenty-fourth embodiment of the present invention;

73 is a perspective view of a rotating gate according to a twenty fifth embodiment of the present invention;

74 is a sectional front view of a sluice door according to a twenty fifth embodiment of the present invention;

75 is a sectional view of a fixed shaft according to a twenty fifth embodiment of the present invention;

76 is a side sectional view at the time of opening the rotating gate according to the twenty-sixth embodiment of the present invention;

77 is a side cross-sectional view of the revolving door according to a twenty-sixth embodiment of the present invention;

78 is a side sectional view of the lower discharge of the rotary door according to the twenty-sixth embodiment of the present invention;

FIG. 79 is a side sectional view at the time of opening the rotating gate according to the twenty-seventh embodiment of the present invention; FIG.

80 is a side cross-sectional view of the revolving door according to the twenty-seventh embodiment of the present invention;

81 is a side sectional view when discharging the lower end of the rotating gate according to the twenty-seventh embodiment of the present invention;

82 is a sectional front view of a sluice door according to a twenty-eighth embodiment of the present invention;

83 is a side sectional view at the time of opening the rotating gate according to the twenty-eighth embodiment of the present invention;

84 is a side cross-sectional view of the revolving door according to the twenty-eighth embodiment of the present invention;

85 is a side cross-sectional view when discharging the lower end of the rotating gate according to the twenty-eighth embodiment of the present invention;

86 is a side sectional view at the time of opening the rotating gate according to the twenty-ninth embodiment of the present invention;

87 is a side sectional view at the time of closing of a sluice door according to a twenty-ninth embodiment of the present invention;

Figure 88 is a side cross-sectional view when discharging the lower end of the rotating gate according to the twenty-ninth embodiment of the present invention.

89 is a perspective view of a sluice gate of a rotatable gate according to a thirtieth embodiment of the present invention;

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

FIG. 91 is a sectional view of a sluice plate of the rotating gate according to the thirty-first embodiment of the present invention; FIG.

92 is an exploded perspective view of a sluice gate in accordance with a thirty-second embodiment of the present invention;

93 is a side sectional view at the time of opening the rotating gate according to the thirty-third embodiment of the present invention;

94 is a side sectional view of the revolving door according to the 33rd embodiment of the present invention.

95 is a side cross-sectional view of the lower discharge of the rotating gate according to the 33rd embodiment of the present invention;

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

97 is a cross-sectional view of the completion of a rotating water gate according to a thirty-fourth embodiment of the present invention;

98 is a cross-sectional view at the time of concrete pouring of the rotating gate according to the 35th embodiment of the present invention.

99 is a cross-sectional view of the completion of a rotating gate according to the thirty-five embodiment of the present invention;

100 is a side cross-sectional view at the time of opening the rotating gate according to the 36th embodiment of the present invention.

101 is a side sectional view at the time of closing of a sluice door according to a 36th embodiment of the present invention;

102 is a side cross-sectional view when discharging the lower end of the rotating gate according to the 36th embodiment of the present invention.

103 is a cross-sectional view taken along the line A-A of FIG.

FIG. 104 is a sectional view taken along the line B-B in FIG. 100;

105 is a side sectional view at the time of opening the rotating gate according to the thirty-seventh embodiment of the present invention;

106 is a side sectional view at the time of closing of a sluice door according to a thirty-seventh embodiment of the present invention;

107 is a side sectional view when discharging the lower end of the rotating gate according to the thirty-seventh embodiment of the present invention;

108 is a cross-sectional view taken along the line A-A of FIG. 105;

109 is a detailed cross-sectional view of the bent portion of the guide rail according to the 37th embodiment of the present invention.

110 is a side cross-sectional view of the revolving door according to a thirty eighth embodiment of the present invention;

111 is a side sectional view at the time of opening the rotating gate according to the thirty eighth embodiment of the present invention;

112 is a side sectional view at the time of opening the rotating gate according to the 39th embodiment of the present invention;

113 is a side sectional view at the time of closing of a rotating gate according to a thirty-ninth embodiment of the present invention;

114 is a side cross-sectional view when discharging the lower end of the rotating gate according to a thirty-ninth embodiment of the present invention;

115 is a side sectional view when opening the rotating gate according to the forty embodiment of the present invention.

116 is a side sectional view at the time of closing of a sluice door according to a forty embodiment of the invention;

Figure 117 is a side cross-sectional view when discharging the bottom of the rotating gate according to a 40th embodiment of the present invention.

Figure 118 is a side cross-sectional view at the opposite side closing of the rotating door according to a forty embodiment of the present invention.

Figure 119 is a side cross-sectional view when discharging the lower side of the opposite side of the rotating gate according to a 40th embodiment of the present invention.

120 is a side sectional view when opening the rotating gate according to the forty-first embodiment of the present invention.

121 is a side cross-sectional view of the revolving door according to the forty-first embodiment of the present invention;

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

123 is a perspective view of a sluice plate according to a forty-second embodiment of the present invention;

124 is a sectional view of a hydroplate according to a forty-second embodiment of the present invention;

125 is a front sectional view of a rotating water gate according to a 43rd embodiment of the present invention;

126 is a side sectional view at the time of opening the rotating gate according to the 43rd embodiment of the present invention;

127 is a side sectional view at the time of closing of a sluice door according to a 43rd embodiment of the present invention;

Figure 128 is a side cross-sectional view when discharging the lower end of the rotating gate according to the 43rd embodiment of the present invention.

Figure 129 is a side cross-sectional view at the time of opening the rotating gate according to the 44th embodiment of the present invention.

130 is a side cross-sectional view of the revolving door according to a 44th embodiment of the present invention.

Figure 131 is a side cross-sectional view when discharging the lower end of the rotating gate according to the 44th embodiment of the present invention.

132 is a front sectional view of a rotating water gate according to a forty-fifth embodiment of the present invention;

133 is a side cross-sectional view at the time of opening the rotating gate according to the 45th embodiment of the present invention;

134 is a side sectional view at the time of closing of a sluice door according to a forty-fifth embodiment of the invention;

135 is a sectional front view of a rotating hydrograph according to a forty-sixth embodiment of the present invention;

Figure 136 is a side cross-sectional view at the time of opening the rotating gate according to the forty-sixth embodiment of the present invention.

Figure 137 is a side sectional view at the time of closing of the rotating gate according to the forty-sixth embodiment of the present invention.

Figure 138 is a side cross-sectional view when discharging the bottom of the rotating gate according to a forty-sixth embodiment of the present invention.

139 is a side sectional view at the time of closing of a rotating gate according to a forty-seventh embodiment of the present invention;

140 is a side sectional view at the time of opening the rotating gate according to the forty-seventh embodiment of the present invention;

Figure 141 is a side sectional view at the time of closing of the rotating gate according to the forty-eighth embodiment of the present invention.

142 is a side cross-sectional view at the time of opening the rotating gate according to the forty-eighth embodiment of the present invention;

Figure 143 is a side cross-sectional view at the time of repair replacement of the rotating gate according to the forty-eighth embodiment of the present invention.

FIG. 144 is a side sectional view of a rotating gate according to a forty-ninth embodiment of the present invention;

145 is a side sectional view in the case of raising the one side rotating door of the rotating door according to the forty-ninth embodiment of the present invention;

146 is a view illustrating the installation of a rotating water gate according to a fifty embodiment of the present invention;

147 is a detailed cross-sectional view of a connection portion of a rotating gate according to a fifty embodiment of the present invention;

148 is a schematic diagram of a hydrological drive system according to a fifty-first embodiment of the present invention;

149 is a front sectional view of a rotating water gate according to a fifty-second embodiment of the present invention;

150 is a side sectional view at the time of opening the rotating gate according to the 52nd embodiment of the present invention;

151 is a side sectional view at the time of closing of a sluice door according to a fifty-second embodiment of the present invention;

Figure 152 is a side cross-sectional view when discharging the lower end of the rotating gate according to a 52nd embodiment of the present invention.

Figure 153 is a view showing one embodiment of a cylinder connecting structure of a rotating gate according to a 52nd embodiment of the present invention.

154 is a view showing another embodiment of a cylinder connecting structure of a rotating gate according to a 52nd embodiment of the present invention.

155 is a detailed cross-sectional view of a rotating door according to a fifty-third embodiment of the present invention;

156 is a block diagram of a sluice gate according to a fifty-fourth embodiment of the present invention;

157 is a block diagram of a multi-stage floodgate applied to a fifty-fifth embodiment of the present invention.

158 is a sectional view when opening the rotating gate according to a fifty-eighth embodiment of the present invention;

159 is a cross-sectional view of the revolving door according to a fifty-eighth embodiment of the present invention;

160 is a cross-sectional view of the lower discharge of the rotary door according to a 57th embodiment of the present invention.

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

10,210: support structure 11,211,301: waterway

12,214: Enclosed space 13,13 ', 25,25', 303,312: Step

20,220,311: housing 20a: round face of housing

21: Shaft hole 22,22 ', 125a, 249a: Guide groove

23,23 ', 36: Packing plate 24,24': Packing plate guide groove

30,230: sluice 31,231: sluice plate

31a, 330: support plate 31b: waterproof plate

31c, 231e: Reinforcement 31d, 239: Bolt

31e: Nut 31f: Round face of sluice plate

32,232: side plate 32a, 232a: space part

33,112,401,401 ': rotating shaft 33a, 106a, 283,283a, 283b: winding roll

33b: push rod 33c: shield

34,116,116 ', 234,234', 403,403 ': Operation link

34a, 34 ', 102,404,404': working rod

35: pressing plate 37: connecting rod

38,402,402 'Support 39,128: Guide

40,115,409: packing member 51,244,285a: first working cylinder

52: support roller 53: chain

56,66,94,104,104 ', 114,124,241,241', 245,247,286,286a, 286b, 406,406 ': piston rod

57,67: Long hole 61,246,285b: Second working cylinder

62: base plate 63: operating plate

64: slider 65: working groove

71: third operation cylinder 72: variable operation plate

80: fixing member 90: lifting block

91: elevating pipe 92: fixed pipe

93: lifting cylinder 100: integrated control system

101: heavy object 102 ': crank part

103,103 ', 240,240', 285,405,405 ': working cylinder

105: reducer 106: drive motor

107: wire rope 108: first crank portion

108 ': second crank section 109: first rotating shaft section

109 ': second rotating shaft 111: support frame

113: support frame working cylinder 117: connecting link

123: front and rear truth cylinder 125: support bracket

126: Gomwood 127: door frame

129 siphon plate 130 siphon passage

131: filtering member 141: closed piping

142: open pipe 143: oil tank

144,266: oil pump 145: control valve

146,147: check valve 148: bypass piping

149: compensation valve 150: hydraulic plate

151: Protection net 212,212 ': Formwork

212a: Coupling pins 213,213 ': Connecting member

231a: engaging projection 231b: bottom plate

231c: middle plate 231d: top plate

231f, 231f ': guide protrusion 231g: first guide protrusion

231h: second guide protrusion 231i: first guide roller

231j: second guide roller 232b: support protrusion

232c: Coupling groove 232d: Lid

233: fixed shaft 233a: hydraulic piping receiving groove

233b: rotating tube 235: protective tube

236: Filling material 237,237 ': Idle roller

238,284,284a, 284b: Operation cable 243: Hydraulic piping

247: operating tube 248: drive link

248 ': First drive link 248 ": Second drive link

249: driven link 249 ': first driven link

249 ": Second driven link 251: First supporting roller

252: first chain 253: second support roller

254: second chain 255: driving screw

256: driven gear 257: working shaft

257 ': 1st working shaft 257 ": 2nd working shaft

260 solar power unit 261 solar panel

262: charging circuit 263: water level sensor

264: hydraulic unit 265: central control unit

267: engine 268: starting motor

271: sensing rod 272a ~ 272e: proximity sensor

273: Control box 274a ~ 274e: Proximity sensor control button

280: guide rail 281: guide

282,282a, 282b: traction cable 290: hinge member

291: engaging jaw 292: shaft rotation part

293: leg plate 294: uneven portion

300: dam structure 302: guide space

310: hydrologic structure 320: hoisting machine

321: lifting cable 407,407 ': fixed plate

408,409: Guide Roller 410: Stopper

411: foreign material removal plate 420: foreign material collection groove

421: introduction portion 422: space portion

423: jaw 1000: reservoir

The present invention relates to a method for purifying contaminated river water using the law of material grabbing action and material preservation instinct generated by a rotating control gate and a comprehensive control system for controlling the rotation thereof, and more particularly, when the rotating gate is closed. In addition to improving the exponential performance with the bottom part, it is possible to secure a larger reservoir space, and when the water gate is lifted for opening, it is possible to purify the contaminated river water by discharging the lower layer water from the space between the gate and the housing. I would have to.

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 to be provided with a separate device to improve water quality. Of course, the water purification area is very limited, there was a weak point to improve the water quality 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 substance, all the substances flow in the different places of the material, ie in different states, depending on the specific gravity of the substance.

Due to this action, clean water with heavy specific gravity flows in the lower layer of the river water, and polluted water with light specific gravity flows in the state of herpes at the upper layer of the 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, but if you install a hydrologic system that discharges the river water to the lower end, the contaminated river water will be naturally purified as the natural material grabbing action, material jungle action and material release action. Large dams also constitute a dam in this way, so that there is absolutely no 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. By confining water using submerged beams that discharge the influent to the upper part by these actions, the condensation and condensation of the contaminants and water molecules are generated while confining the water inside the reservoir system. There are significant problems in that contamination is rather aggravated by material 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 decomposed naturally, the particles generated by natural decomposition are combined with other substances, which increases the pollution of water. This is caused by the active green algae and the red tide occurring in the sea. will be. 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 explosion" that increases water pollution.

Substances that undergo various kinds of chemical reactions are naturally introduced into the water. These unknown substances come into contact with other substances, and when the unique chemical components of the substance and the unknown chemical components meet, As it explodes, it creates a substance like tiny bubbles that rises above the water. That is, the fine droplets continuously occur in the beer glass because the fine particles and the fine particles contained in the beer are exploded to meet and continue to generate droplets.

Subsequent mass explosions occur in water, which are produced continuously by the tiny droplets due to the explosive mass of materials that meet and explode. When these explosions occur, another substance is formed by the combination of air bubbles and other fine particles contained in the water, and the generated fine particles have a specific gravity that is heavier than the molecular structure of the water. As it precipitates in the bottom layer of the water, it will increase the pollution of the water.

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 contaminant particulates itself wears off and the contaminated water is changed to 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 particles of incompletely decomposed materials are combined with pollutants and clean water by the viscous force contained in the particles, that is, the viscous force and magnetic force contained in the decomposed particles in another material. This action is "material binding action". The microparticles generated by the decomposition of materials naturally have viscous and magnetic forces due to the material frictional movement that causes the water molecules to move in an enormous motion inside the water, ie, to wear them and move them innumerably. Since the surface tension of the material occurs naturally and naturally occurs on the surface of the material, the viscous force to bond with the material and the magnetic force to attract the material are naturally strengthened. "Is defined.

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. .

All materials are decomposed by the material friction and other material decomposition actions exerted by the particles that make up the water molecules at the moment they enter the water.

For example, the sea rust produced by the decomposition of iron is finer particles having a lighter specific gravity than water molecules, and they are settled in the bed as the material binds to other particles decomposed by water molecules. The material that arises at the time is deposition.

All the organic, inorganic, phosphorus and nitrogen substances contained in the water convert the polluted water into clean water with heavy gravity through the process of material friction, the action of oxygen, microorganisms, solar heat and the natural decomposition of water molecules. As it is shrouded in the lower part of the reservoir, when it is discharged through the lower part of the water gate, that is, it produces only clean water continuously.

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 and material binding action, so that the water stored in the reservoir is always kept at the full water level and water flowing from the upstream through the lower part of the sluice gate. The method of frequent discharge is the best way to prevent the contamination of river water, and also by using the method of discharging the water in the reservoir through the lower part of the sluice, the material binding action of the substances contained in the water It discharges pollutants such as aggregated sewage sludge, and at the same time, it accelerates the material acceleration, material scavenging, material decomposition, material flotation, and naturally cleans the polluted water. A small amount of water that floats on top of the water by discharging some of the incoming water The materials and the number sikyeojum purifying contaminated by using a method that is diluted and stained with heavy clean water specific gravity is discharged through the bottom contact is the most preferred.

However, in the case of general floodgates, the support shaft of the floodgates is fixed to the lower or upper side of the support structure so that the water stored in the reservoir space is discharged to the top or bottom of the floodgates only when the floodgates are opened. There is a limit to this, and when the floodgate is closed, the water stored in the reservoir is forced to stagnate, so that the water quality is suddenly contaminated, such as the generation of sedimentation sludge due to agglomeration of matter. Even if they try to move to, the path is closed, which causes the ecosystem to be destroyed.

In addition, there is a rotatable sluice consisting of a half-moon-type sluice plate and two side plates formed at right angles to both sides thereof, but a power means for driving the sluice is usually a drive motor, a reduction gear group or an operation cylinder, a multi-stage link, a connecting rod, Since the power transmission mechanism is very complicated, it has a lot of energy loss as well as a high possibility of error, and the power means for providing power to the gate and the transmission means are directly connected to the rotating shafts formed on both sides of the gate. Because it is located in position, it is inevitably to be in direct contact with the water stored in the reservoir and the foreign matter contained in the water.

In addition, in the state in which the rotatable floodgate is closed, water stored in the reservoir is stagnated like the general floodgate described above, thereby accelerating pollution of the water, as well as closing the fish passage and destroying the ecosystem. I was doing.

In view of this, the present applicant in patent application No. 2006-118946, withdraws the operation link from the rotating shaft of the rotating hydrology, respectively, fixing the operation cylinder on the upper part of the sealed space between the support structure and the housing, and operating with the piston rod end of the operation cylinder. Each end of the linking member such as a chain is connected between the leading end of the link, and the chain is configured to pass through a support roller directly above the actuating link, so that the power transmission system is provided with a minimum of components such as an actuating cylinder, a chain, and an actuating link. The energy loss is minimized, and there is no possibility of an error, and even if a leak occurs, water and the working cylinder do not come in direct contact, which improves the reliability of the opening and closing operation of the gate, and forms a discharge passage inside the gate. To ensure that the water level is always discharged even when the water gate is closed. It also disclosed a method of constructing a rotating gate that purifies the contaminated river water that can purify the water quality as well as maintaining the water in the reservoir.

However, according to the construction method of the rotating gate to purify the contaminated river water according to the patent application No. 2006-118946, there is no problem in the rotational operation of the gate, the packing between the gate and the bottom of the housing when closing the gate If it is not made properly, water leakage will occur. In the closed state of the gate, the rounded sidewall part of the gate is located at the lowered part of the housing. It was a disadvantage.

In addition, the space between the bottom of the housing and the bottom of the water gate can be pulled out as much as possible, so that the lower water of the reservoir can be discharged a little, but the discharge space is very narrow. .

In addition, in the case of Utility Model Registration No. 0179171 and 0179180 invented by the present applicant, the water gate is opened by using a control system that is simply operated. Because of the large area occupied by the inside, there is a drawback that may cause flooding.

In addition, Patent Application No. 2003-57386, Patent Application No. 2004-38599, Utility Model Registration Application No. 2002-5190, Utility Model Registration Application No. 2002-36293, Utility Model Registration Application No. 2002-36934 Conventional rotating doors, such as the patent application No. 2006-102541, the patent application No. 2006-118946, which is the applicant's prior application, also had a problem in that leakage occurs between the water gate and the housing or the door frame when the door is closed.

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 the above points, and the sluice plate and both side plates of the sluice are asymmetrically configured such that the drainage side is longer, and the packing member is fixed to the outside thereof, and the operation link is drawn out from the rotation shaft of the sluice. Each chain connected with two working cylinders is connected to each other, or the operating link is pulled out from the rotary shaft and the chain connected to the first operating cylinder is connected thereto, and the pressing plate is drawn out from the position next to the operating link position of the rotary shaft, It is fitted with a ring-shaped slider that is fixed to the supporting plate and the operation plate in the shape of “V”. The second operation cylinder is rotatably fixed to the operation plate to open and close the waterway while rotating the water gate by 270 ° according to the operation of each operation cylinder. In this case, when the water gate is closed, the packing member comes into close contact with the bottom of the housing and exhibits exponential characteristics. Since the sluice plate and the side plate boundary of the sluice are located above the bottom of the housing, it is possible to secure a larger reservoir space than the sluice rounded below the bottom of the housing. In order to purify the contaminated water quality, it is combined with a system that purifies the contaminated water quality with clean water, which is discharged between the water gate and the bottom of the housing as the bottom water of the reservoir is discharged at the moment of lifting. I would like to.

In another aspect, the fixed shaft is fixed to the support structure, and both sides of the sluice are rotatably fixed to the fixed shaft, and both sides and the sluice plate are rotated through the cylinder inside or outside the two sides to open or close the channel, The fixed shaft is fixed to the support structure while the fixed shaft and both sides are fixed, and both sides, the hydroplate and the fixed shaft are rotated through the cylinder to open and close the waterway to perform the basic functions as a water gate. In addition, it is possible to improve the bearing capacity of the supporting structure by not having to store the means for rotating the floodgate inside the supporting structure, and also to realize the floodgate having a relatively large size compared to the width of the river. It is to be discharged in a short time to prevent the overflow.

In another aspect, 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. Will not occur.

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.

If the water is confined by using the upper discharge gate to discharge the water flowing from the stream to the upper part, the contamination of the water is aggravated by the material cutting action and the material binding action. The present invention seeks to address these drawbacks.

Tens of thousands of substances are contained in the water, which can be classified into inorganic and organic particulates. The particulates are decomposed by frictional action when they are brought into contact with each other. Other particles are produced, and the particles produced in this process sink to the bottom of the stream, transforming them into particles that are heavier than the weight of water as the material bonds with other inorganic and organic particulates. Water pollution is aggravated by the action, and this action is a material binding action, and this is what happens.

In addition, even if there is no oxygen contained in the water, the friction between the fine particles contained in the water occurs, the material contained in the water is naturally decomposed, the action is the material friction action.

By this material friction action, the fine particles contained in the water are decomposed even more finely.

The material that is decomposed by the mass decomposition action is settled inside the top discharge water storage device as it becomes a substance that is heavier than the specific gravity of the water as the material aggregation action that materially combines with other particles contained in the water. .

In addition, the principle that water confined by material cutting is further contaminated is explained.

If water is trapped inside the water storage device, such as the upper drainage gate or rubber dam, the specific gravity of water confined in water is heavier than the specific gravity of water due to the material binding action of the inorganic and organic particles contained in the water. As it is changed to a true state, organic material river water that flows in from the upstream of the river is stored in the inside of the sluice, so that the gravity does not penetrate into the heavy water but passes through the surface of the water. As it escapes to the downstream of the stream, it will increase the pollution of the water.

In other words, the water trapped inside the reservoir remains stagnant, but the water flowing down from the upstream of the stream flows first through the upper end of the reservoir as it flows through the upper end of the stagnant reservoir because of the high flow rate. It will not be mixed with the stored water because it is going out.

This action is the material cutting action.

In addition, when water is confined using concrete submerged beams, top discharge gates, and top discharge rubber dams, the contamination of the water is aggravated because the water that cannot be mixed with the water flowing from the upstream is left aside. First, the sedimentation sludge storage device generated by the material collapsing action, the material friction action between the fine particles contained in the stored water, and the material binding action that unites or combines the decomposed materials again and again together It is continuously stacked inside the cell and at the same time ① natural decomposition by dissolved oxygen in water ② decomposition by microorganisms ③ decomposition by the friction effect of particles and fine particles ④ Natural decomposition that is decomposed by solar heat and ⑤ aquifer The sedimentary sludges are naturally decomposed by the decomposition of substances decomposed by friction, ⑥ decomposing by osmotic action, ⑦ decomposing by gravity, and ⑧ decomposing by capillary action. As a result of generating other fine particles, water contamination is further increased by continuously generating another fine particles by mass friction, mass decomposition, material binding, and mass aggregation.

In addition, the bottom water discharge device is installed in a part of the rubber dam to discharge a part of the river water, or a siphon passage is installed in the part of the conductive water gate to discharge the inflow water from the upstream of the stream. When the water is confined using the water storage device of the contaminated water, the contaminated water confined in the water storage device is more active in the condensation water by mass cutting action. As it is done, more and more pollution is added.

In other words, waters that are heavy due to the heavy gravity of water, which are separated by light weights, are pushed out first, and the water is contaminated because the binding of water is more active. When a stone is thrown into the water, the principle of pushing out the water and sinking is the material cutting action.

The following explains the principles by which polluted water naturally survives.

Water contains about 60,000 kinds of substances, and all the substances in them have their own mass, and the mass of herpes in the stored water differs according to the mass.

That is, the layers occupy different materials, which is called laminar flow.

Even the same nitrogenous component and phosphorus component have different layers of herpes depending on the size at which the particles are decomposed.

In other words, it is due to the force of gravity that a substance with a specific gravity of 0.99999998 never penetrates into a substance with a specific gravity of 1 or a substance having a specific gravity of 0.99999999. This is the same principle that oil floats on water.

 This is because of Corio's force, or gravity.

When water is stored using the bottom discharge type water storage device, which maintains laminar flow by gravity, it is caused by viscous force that aggregates or combines pollutants with different specific gravity and water molecules. This does not cause agglomeration of substances and binding of substances, so that water pollution is not increased.

In other words, if the water is trapped by installing an upper discharge type storage device that discharges the river water flowing from the upstream of the river to the upper part of the water storage device, the material aggregation and material combination of water molecules and contaminants in water are aggregated. Actions increase water contamination, but confine water using a bottom drainage reservoir configured to discharge a large amount of water from the upstream of the stream through the bottom of the reservoir, i.e., the bottom of the drainage sluice. If it is placed, the inflow of water from the upstream of the stream can be discharged only as much as the inflow of water flowing through the lower part of the bottom discharge type storage device. Natural decomposition by dissolved oxygen in ② Decomposition by microorganisms ③ Substances caused by friction between fine particles and particulates ④ Decomposition by natural heat ④ Natural degradation by solar heat ⑤ Substances decomposed by friction of aquifers These actions, together with the decomposition process, ⑥ decomposes by osmotic action, ⑦ decomposes by gravity pressure, and ⑧ decomposes by capillary action. The microparticles decomposed by are moved to the upper part of the water stored by the action of gravity, and are further decomposed more and more by the eight natural purification actions such as above. The action of the "law of conservation of matter" in water is a natural Contaminated water, which is combined with water molecules or stuck inside the water molecules, is decomposed from the water molecules and moved to the upper part of the bottom drainage water storage device to be naturally decomposed and combined with the contaminated particles. In the clean state, the contaminated particulates are removed and the pure water is clean and the contaminated water is naturally purified as the natural circulation process is carried out downstream of the stream through the lower part of the bottom discharge reservoir. It will be.

  In order for these actions to occur continuously so that contaminated river water is naturally purified, it is desirable to install a multi-stage water storage system across the entire transverse shear plane of the stream and the entire longitudinal section of the stream.

Because of these causes and actions, water pollution is aggravated and polluted waters are raised. Therefore, water pollution is increased and polluted depending on whether the water is stored at the bottom or discharge at the top. The old water comes to life.

The present invention is to recognize the problems and to provide a method for the natural purification of contaminated river water by using a discharge method consisting of a more reliable hydrologic structure.

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

[First Embodiment]

1 is an exploded perspective view of a rotating gate according to a first embodiment of the present invention, Figure 2 is a detailed view of the portion A of Figure 1, Figure 3 is a front sectional view of the rotating gate according to the first embodiment of the present invention, Figure 4 is a side cross-sectional view at the time of opening the rotating gate according to the first embodiment of the present invention, Figure 5 is a side cross-sectional view at the maximum rise of the rotating gate according to the first embodiment of the present invention, Figure 6 is Figure 1 is a side cross-sectional view when closing the rotating gate according to the first embodiment, Figure 7 is a side cross-sectional view during opening operation of the rotating gate according to the first embodiment of the present invention.

As shown, the rotatable water gate according to the first embodiment of the present invention is a channel 11 is formed between the two support structures 10, the housing 20 on the opposite surface of the both support structures 10, respectively A cover 12 is formed between the housing 20 and the support structure 10, and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of the rotation shaft 33 drawn outward from the side plate 32, the rotation shaft 33 of the sluice 30 is inserted into the shaft hole 21 formed in each housing 20.

In this rotational gate, the sluice plate 31 and both side plates 32 in the open position of the sluice 30 are formed asymmetrically longer than the reservoir side around the rotation axis 33, while the sluice plate 31 ) And the shock absorbing packing member 40 is fixed to the outer side of the drainage side boundary portion of both side plates 32 continuously in the longitudinal direction of the sluice 30.

In addition, the operation link 34 is drawn out to the water storage side at the sealed space position of the rotary shaft 33, and the first operation cylinder 51 is installed at the upper water storage side of the sealed space 12, and the operation link 34 is directly connected. A supporting roller 52 is rotatably installed at a position parallel to the upper first operating cylinder, and the support roller 52 and the operating link are connected via the rotating shaft 33 from the piston rod end of the first operating cylinder 51. It is connected to the chain 53 constituted at the distal end of the 34, the pressing plate 35 is pulled out from the side of the operating link position side of the rotary shaft 33 in the opposite direction of the operating link pull-out direction, and is smooth outside the position of the pressing plate 35. A ring-shaped slider 64 in which the support plate 62 and the operation plate 63 are fixed is inserted in a “V” shape having one inclination, and the piston rod of the second operation cylinder 61 is inserted into the operation plate 63. The tip end is rotatably fixed.

In this case, in the first embodiment of the present invention, the chain 53 is applied, but it is apparent that various connection members such as ropes and wires may be used in addition to the chain 53.

In addition, the operation groove 65 is formed so that the pressing plate 35 can be rotated without interference when the water gate 30 rotates from the opposite side of the support plate of the slider 64 to the support plate 62 via the operation plate 63. In addition, the rotary shaft 33 is in close contact with the inner surface of the housing 20, the shock absorbing packing plate 36 is fixed between the shaft hole 21 and the rotary shaft 33 of the housing 20, respectively, The drain side of the bottom portion is formed to be rounded downward to be in sliding contact with the arc-shaped hydrology plate 31.

In addition, two operation links 34 are drawn out from the rotation shaft 33 in the same direction, and the connecting rods 37 are fixed in the horizontal direction between the distal ends thereof, and the chain 53 is rotatably fixed to the connecting rods 37. do.

Reference numeral 38 in the drawings represents a support for supporting the rotating shaft 33 in the closed space 12, such a support 38 can be configured in a variety of shapes, so the illustration is omitted in FIG. In addition, reference numeral 39 in the drawing represents a guide formed to prevent the chain 53 from being separated when the chain 53 is returned to the rotation axis.

In this configuration, the first second operation cylinder 61 is contracted as much as possible so that the first operation cylinder 51 in a state in which the support plate 62 and the operation plate 63 form a "V" shape having a gentle inclination. If the maximum extension of the chain 53 is connected to the piston rod of the first operating cylinder (51) is released as much as possible so that the sluice 30 is rotated by its own weight so that the sluice plate 31 of the sluice 30 is the housing 20 ) Close to the rounded portion in the bottom direction of the bottom portion is in a state that the water gate 30 is completely open.

When the water gate 30 is opened, the upper surface of the water gate plate 31 is in a horizontal state, and the rounded side of the water gate plate 31 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, and thus the water storage space. Water can be smoothly discharged to the upper surface 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.

When the first operation cylinder 51 is contracted while the water gate 30 is open, the chain 53 is pulled, and the operation link 34, the rotation shaft 33, the both side plates 32, and the water plate 31 ) Will begin to rotate counterclockwise.

As described above, when the water gate 30 is rotated in the counterclockwise direction and then rotated 180 ° from the state in which the water gate plate 31 is open, the water gate 30 is counterclockwise due to the weight of the water gate plate 31. It can be sharply rotated and fall (strictly speaking, the water gate according to the present invention is asymmetrical and starts to fall from less than 180 °), and thus, when the water gate 30 falls at a rapid speed, the water gate 30, the housing ( 20), in order to prevent the support structure 10 from being damaged, in the first embodiment of the present invention, the pressing plate 35 is pulled out from the side of the operating link position of the rotary shaft 33 in the opposite direction to the operating link pull-out direction. , Outside the position of the pressing plate 35 is inserted into the ring-shaped slider 64 is fixed to the support plate 62 and the operating plate 63 in the shape of "V" in a gentle inclined form, the operating plate 63 2-piston of operating cylinder (61) The front end portion is rotatably fixed, and when the sluice plate 31 of the sluice 30 is first rotated about 180 °, that is, the sluice 30 rotates counterclockwise, and the sluice plate 31 is rotated. ), The pressing plate 35 is rotated together with the rotary shaft 33 and placed on the supporting plate 62. At the same time, the position detecting sensor (not shown) connected to the integrated control system 100 is connected. It detects that the water gate 30 is rotated by 180 ° through which the second operating cylinder 61 is gradually extended in accordance with the signal.

When the second operation cylinder 61 is gradually extended, the operation plate 63 is rotated while the slider 64 and the support plate 62 are rotated together, and a load is placed on the support plate 62 by the pressing plate 35. 30 is gradually rotated counterclockwise to ensure safety, and when the drain side side plate and both side plate boundary of the water gate 30 is in contact with the bottom of the housing 20 of the water gate 30 The rotation will stop.

At this time, the sluice gate 30 according to the present invention because the drainage side of the sluice plate 31 and both side plates 32 in the open position is formed asymmetrically longer than the reservoir side with respect to the rotation axis 33 the sluice gate 30 ) Is completely rotated at an angle of about 270 °, and the drainage side boundary portions of the sluice plate 31 and both side plates 32 contact the bottom of the housing 20 with the sluice plate 31 and the side plates 32 opened. 31 may be erected in a vertical direction so that the waterway 11 may be closed, and the packing member may be continuously formed in the longitudinal direction of the water gate 30 on the outer side of the drainage side boundary of the water gate plate 31 and both side plates 32. Since 40 is fixed, the packing member 40 is completely packed while absorbing the shock generated between the water gate 30 and the housing 20.

In addition, the bottom part of the housing 20 in contact with the drainage side boundary portion of the sluice plate 31 and both side plates 32 is in a position parallel to the upper surface of the sluice plate 31 when opening the sluice 30 patent application Compared to No. 2006-118946, the water can be made as much as the length of the drainage side asymmetrically increased about the rotating shaft 33 and the height of the drainage side rounded downward from the bottom of the housing 20. In addition, a structure capable of securing a storage space larger than the sum of the thicknesses of the packing members 40 installed between the sluice 30 and the bottom of the housing 20 is completed.

When the first operating cylinder 51 is extended and the second operating cylinder 61 is contracted at the same time as opposed to the closed state of the water gate 30, the water gate 30 starts to rotate in the clockwise direction as opposed to the closing state. A space is generated between the sluice gate 30 and the bottom of the housing 20 so that the lower layer water of the reservoir is discharged through the space, and foreign substances such as sedimentary sludge deposited on the bottom of the stream are discharged like the river water. Acceleration, material scavenging, material releasing, and material flotation occur naturally, resulting in the purification of contaminated water.

Continued elongation of the first actuating cylinder 51 and at the same time the second actuating cylinder 61 continues to contract, the water gate 30 is rotated about the rotation axis 33, the rotation angle is 90 ° from the closing Even though the center of gravity of the water gate 30 is in the direction of closing, the second operation cylinder 61 is contracted as much as possible until the center of gravity of the water gate 30 is in the direction of opening.

However, when the center of gravity of the water gate 30 comes over in the open direction, as in the closing of the water gate 30, the water gate 30 may suddenly rotate clockwise and fall due to the weight of the water gate plate 31. Therefore, when the water gate 30 is rotated to prevent this, when the water gate plate 31 becomes horizontal, the water gate 30 is sensed through a gasoline detection sensor (not shown) connected to the integrated control system 100 to generate the signal according to the signal. By lowering the expansion speed of the first operation cylinder 51, the rotational speed of the water gate 30 is artificially reduced, and thus the water gate 30 can be safely opened.

In addition, the second operating cylinder 61, which has been contracted as much as possible, is stretched slightly to stand by in a state where it is returned to the initial state.

In order to operate by using the water gate configured in this form, a comprehensive control 100 coupled with a computer system is required, and the influent flowing in upstream of the stream is gradually discharged using the integrated control system 100 configured at this time. By adjusting the water gate so that it can be discharged sequentially only the quantity of water flowing through the lower end of the water gate can be contaminated water quality naturally.

At the top of the support plate and the operating plate to be applied to the present invention can be provided with a shock absorber that can absorb the shock, it is natural that such a design change is within the scope of the present invention.

Second Embodiment

8 is an exploded perspective view of a rotating gate according to a second embodiment of the present invention, Figure 9 is a front sectional view of a rotating gate according to a second embodiment of the present invention, Figure 10 is a second embodiment of the present invention Figure 11 is a side cross-sectional view when opening the rotating door, Figure 11 is a side cross-sectional view when closing the rotating door according to a second embodiment of the present invention, Figure 12 is a side cross-sectional view when opening the lower end of the rotating door according to a second embodiment of the present invention to be.

As shown, the waterway 11 according to the second embodiment of the present invention is formed between the two support structures 10, as in the first embodiment of the present invention, On the opposite surface, the housing 20 is covered with each other so that a sealed space 12 is formed between the housing 20 and the support structure 10, and is perpendicular to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of both side plates 32 and rotation shafts 33 drawn outward from both side plates 32, and the shaft shafts of the sluice gates 30 are formed in the respective housings 20. It is inserted into 21.

In this rotational gate, the sluice plate 31 and both side plates 32 in the open position of the sluice 30 are formed asymmetrically longer than the reservoir side around the rotation axis 33, while the sluice plate 31 ) And the packing member 40 is fixed to the outside of the drainage side boundary portion of both side plates 32 in the longitudinal direction of the water gate 30.

In addition, the operation link 34 is drawn out to the water storage side in the sealed space position of the rotary shaft 33, and the first operating cylinder 51 and the second operating cylinder 61 are respectively installed on both upper sides of the sealed space 12, The first support roller 52 ′ and the second support roller 52 ″ are rotatably installed at positions parallel to the operation cylinders 51 and 61 at the upper portion of the operation link 34, respectively. 30) The first end of the actuating link 34 via the first support roller 52 'and the rotating shaft 33 from the piston rod end of the first actuating cylinder 51 positioned on the water storage side with respect to the position. The linkage 53 is connected via the second support roller 52 "from the piston rod end of the second actuating cylinder 61, which is connected to the chain 53 'and positioned on the drainage side with respect to the position of the sluice 30. The second chain (53 ") is connected to the front end of the.

In this case, in the second embodiment of the present invention, the first chain 53 ′ and the second chain 53 ″ are applied, but in addition to the chains 53 ′ and 53 ″, various connection members such as ropes and wires are used. It is obvious that can be used.

In addition, the packing shaft 36 which is in close contact with the inner surface of the housing 20 to absorb the shock generated between the shaft hole 21 and the rotating shaft 33 of the housing 20 is fixed to the rotary shaft 33, respectively, the housing The drainage side of the bottom of the 20 is formed to be rounded downward to be in sliding contact with the arc-shaped watermark plate 31.

In addition, a plurality of operating links 34 are drawn out from the rotation shaft 33 in the same direction so that the first chain 53 'and the second chain 53 "do not interfere with each other during the rotation of the water gate 30. The connecting rod 37 is fixed in the horizontal direction between the tip of the operation link 34 so that the first chain 53 'is rotatably fixed to the adjacent hydrologic plate of the connecting rod 37, and the second chain 53 " Is rotatably fixed to an adjacent portion of the support structure of the connecting rod 37, and each of the operation cylinders 51 and 61 and the respective support rollers 52 'according to the positions of the respective chains 53' and 53 "( 52 ") are positioned so as not to interfere with each other.

Of course, the first operation cylinder 51, the first support roller 52 'and the first chain 53' and the second operation cylinder 61, the second support roller 52 ", the second chain 53 Obviously, the installation positions of ") may be reversed.

In the drawings, reference numeral 38 denotes a support for supporting the rotation shaft 33 in the closed space 12. Since the support 38 may be configured in various shapes, detailed illustration is omitted in FIG. 1. In addition, reference numeral 39 in the drawing represents a guide formed to prevent the departure of the first chain 53 'when the first chain 53' passes through the rotation shaft 33.

The hydrogate configured as described above is operated by the integrated control system 100, and the hydrogate combined with the integrated control system 100 extends the first first operation cylinder 51 as much as possible and the second operation cylinder 61 contracts as much as possible. Then, the first chain 53 'and the second chain 53 "connected to the piston rods of the respective operation cylinders 51 and 61 are released or pulled to make the operation link 34 almost horizontal. Accordingly, the sluice plate 31 of the sluice 30 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20 so that the sluice 30 is completely opened.

When the water gate 30 is opened, the upper surface of the water gate plate 31 is in a horizontal state, and the rounded side of the water gate plate 31 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, and thus the water storage space. Water may be 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.

When the first actuating cylinder 51 is contracted and the second actuating cylinder 61 is extended while the water gate 30 is open, the first chain 53 'is pulled out and the second chain 53 "is pulled out. As the silver is released, the operation link 34 and the rotating shaft 33, and both side plates 32 and the sluice plate 31 begin to rotate counterclockwise.

As described above, from the time when the water gate 30 is rotated counterclockwise and the water plate 30 is rotated about 180 ° from the open state, the water gate 30 is counterclockwise due to the weight of the water plate 31. It can be sharply rotated and fall (strictly speaking, the water gate according to the present invention is asymmetrical and starts to fall from less than 180 °), and thus, when the water gate 30 falls at a rapid speed, the water gate 30 and the housing 20 and the support structure 10 may be damaged, so that when the sluice plate 31 of the sluice 30 is rotated about 180 ° while being initially opened, that is, the sluice 30 is counterclockwise. Rotation in the direction and when the sluice plate 31 is horizontal, it is detected by a position sensor (not shown) coupled with the integrated control system 100 and the expansion speed of the second operation cylinder 61 in accordance with the signal By slowing down the number The speed of rotation of 30 is reduced to give artificially.

At this time, since the water gate according to the present invention is formed asymmetrically longer than the water storage side around the rotation axis of the drain plate 31 and both side plates 32 in the open position of the water gate 30 is about 270 ° When fully rotated at an angle, the water-side plate 31 and the side plate 32 are in contact with the bottom part of the housing 20 with the water-side plate 31 and both side plates 32 contacting the bottom of the housing 20 with respect to the opening of the water-gate 30 in the vertical direction. Since the waterway 11 can be closed by being erected, and the packing member 40 is fixed in the longitudinal direction of the water gate 30 on the outer side of the drainage side boundary of the water gate plate 31 and both side plates 32, The packing member 40 is a perfect packing between the water gate 30 and the housing 20.

In addition, the bottom part of the housing 20 in contact with the drainage side boundary portion of the sluice plate 31 and both side plates 32 is in a position parallel to the upper surface of the sluice plate 31 when opening the sluice 30 patent application Compared to 2006-118946, the length of the drainage side asymmetrically increased about the rotating shaft 33, the height of the drainage side rounded downward from the bottom of the housing 20, and the water gate 30 and As the thickness of the packing member 40 sandwiched between the bottom of the housing 20 and the height of the water gate increases, the storage space may be secured even more.

When the first operating cylinder 51 is extended and the second operating cylinder 61 is contracted at the same time as opposed to the closed state of the water gate 30, the water gate 30 starts to rotate in the clockwise direction as opposed to the closing state. A space is generated between the sluice gate 30 and the bottom of the housing 20 so that the lower layer water of the reservoir is discharged through the space, and foreign substances such as sedimentary sludge deposited on the bottom of the stream are discharged like the river water. The structure that allows the polluted water to be naturally purified by the acceleration action, the material scavenging phenomenon, the material removal action and the material flotation action is completed.

If the first operating cylinder 51 is continuously extended and at the same time the second operating cylinder 61 is continuously contracted, the water gate 30 is rotated about the rotation axis 33, and the rotation angle is 90 ° from the closing time. When the water gate 30 is rapidly rotated clockwise due to the weight of the water gate plate 31 can fall, so that the water gate 30 is rotated to prevent this, the water plate 31 is in a horizontal state If it detects this through a position sensor (not shown) coupled with the integrated control system 100 and slows down the expansion speed of the first operation cylinder 51 in accordance with the signal artificially to reduce the rotational speed of the water gate (30) The water gate 30 can be opened safely by reducing it.

In addition, in the second embodiment of the present invention, the first and second working cylinders 51 and the first support roller 52 'and the second operation cylinder 61 and the second support roller 52 " Although shown as an example, the heights of the respective working cylinders 51 and 61 and the supporting rollers 52 'and 52 "are 1 in the sealed space 12 between the housing 20 and the supporting structure 10. FIG. Since it is possible to install by changing the location above / 2 or anywhere, do not change the installation location or place any special restrictions on the installation height.

In addition, the natural water quality that acts while exiting the lower end of the water gate 30 is installed in multiple stages by installing the river water purification hydrology having a configuration according to the second embodiment of the present invention in an inclined portion of the river in multiple stages It may be configured to be more effectively purified by the improvement actions, it is obvious that such modified embodiment is also within the scope of the present invention.

Third Embodiment

Figure 13 is an exploded perspective view of a rotating gate according to a third embodiment of the present invention, Figure 14 is a front sectional view when opening the rotating gate according to a third embodiment of the present invention, Figure 15 is a third embodiment of the present invention 16 is a side cross-sectional view of the rotating gate according to the opening of the rotating door according to the third embodiment of the present invention, and FIG. 19 is an operation diagram of the rotating gate according to the third embodiment of the present invention. As a closed side cross-sectional view, the illustration of the second actuating cylinder 61 is omitted in FIG.

As shown, the rotatable gate according to the third embodiment of the present invention is a water channel 11 is formed between the two support structures 10, the housing 20 on the opposite surface of the two support structures 10, respectively A cover 12 is formed between the housing 20 and the support structure 10, and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of the rotation shaft 33 drawn outward from the side plate 32, the rotation shaft 33 of the sluice 30 is inserted into the shaft hole 21 formed in each housing 20.

In this rotational door, as in the first embodiment and the second embodiment, the water gate plate 31 and the side plates 32 at the open position of the water gate 30 have their drainage side on the rotation axis 33. While being formed asymmetrically longer, the packing member 40 is fixed to the water discharge plate 31 and the outer side of the drainage side boundary portion of both side plate 32 in the longitudinal direction of the water gate 30 continuously.

In addition, in the closed space position of the rotating shaft 33, the operating link 34, which is formed with the operating rod 34a at the tip end, is drawn out to the water storage side, respectively, and the first operating cylinder 51 is disposed on both sides of the upper portion of the sealed space 12. Are rotatably arranged in the vertical direction, and long holes 57 are formed at the tip of the piston rod 56 of the first operating cylinder 51, and the operating rods 34a are fitted therein, and the first operating cylinder A second operating cylinder 61 is rotatably disposed at the front or rear of the 51, and a long hole 67 is formed at the tip of the piston rod 66 of the second operating cylinder 61, where the first operating cylinder is formed. The body of the 51 or its piston rod 56 is fitted to be configured to open and close the waterway 11 while the water gate 30 is rotated by an angle of about 270 ° by the interlocking operation of the respective working cylinders 51 and 61.

At this time, the long hole 57 formed in the front end portion of the piston rod 56 of the first operating cylinder 51 is fitted with a relatively small diameter operating rod 34a, the piston rod 66 of the second operating cylinder 61 The body of the first operating cylinder 61 or the piston rod 56 thereof having a relatively large diameter is fitted to the long hole 67 formed at the front end portion, so that the piston rod 56 is formed at the front end of the piston rod 56 of the first operating cylinder 51. Obviously, the size and length of the long hole 67 formed at the tip of the piston rod 66 of the second working cylinder 61 is larger and longer than the size and length of the long hole 57. The width and the length of the 67 are each long hole 57 (in the rotation operation of the water gate 30, while providing a slight play so as not to overdo each piston rod 56, 66 during the rotation operation of the water gate 30 ( It is obvious that the member fitted in 67 should provide sufficient length so that it can be operated without interference.

In addition, the packing shaft 36 which is in close contact with the inner surface of the housing 20 to absorb the shock generated between the shaft hole 21 and the rotating shaft 33 of the housing 20 is fixed to the rotary shaft 33, respectively, the housing The drainage side of the bottom of the 20 is formed to be rounded downward to be in sliding contact with the arc-shaped watermark plate 31.

Reference numeral 38 in the drawings denotes a support for supporting the rotation shaft 33 in the closed space 12.

The water gate configured as described above is operated by the integrated control system 100. When the first operating cylinder 51 is extended by about 3/4 during the operation of the water gate 30 combined with the integrated control system 100, the operation link is operated. The 34 is made almost horizontal, so that the sluice plate 31 of the sluice 30 is in close contact with the rounded portion of the bottom of the housing 20 and is in a state in which the sluice 30 is completely opened. .

When the water gate 30 is opened, the upper surface of the water gate plate 31 is in a horizontal state, and the rounded side of the water gate plate 31 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, and thus the water storage space. Water may be 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.

When the piston rod 56 of the first operating cylinder 51 is extended as much as possible while the water gate 30 is open, the water gate 30 is about 90 ° from the opening point. In this state, the first operating cylinder ( 51 can no longer push the actuating link 34 so that the water gate 30 can no longer be rotated.

At this point, the second actuating cylinder 61 begins to contract, and when the actuating second cylinder 61 contracts, the body of the first actuating cylinder 51 is formed in the long hole 67 formed at the tip of the piston rod 66. Alternatively, since the piston rod 56 is fitted, the first operation cylinder 51 may be rotated to continuously rotate the water gate 30. Of course, when the second operation cylinder 61 is contracted and the first operation cylinder 51 is further rotated at the maximum extension position, the water gate 30 is gradually contracted to the position of the operation rod 34a formed in the operation link 34. ) Can be rotated continuously.

As described above, from the time when the water gate 30 is rotated counterclockwise and the water plate 30 is rotated about 180 ° from the open state, the water gate 30 is counterclockwise due to the weight of the water plate 31. It can be sharply rotated and fall (strictly speaking, the water gate according to the present invention is asymmetrical and starts to fall from less than 180 °), and thus, when the water gate 30 falls at a rapid speed, the water gate 30 and the housing 20 and the support structure 10 may be damaged, so that when the sluice plate 31 of the sluice 30 is rotated about 180 ° while being initially opened, that is, the sluice 30 is counterclockwise. Direction when the sluice plate 31 is horizontal, it is detected by a position sensor (not shown) coupled with the integrated control system 100 and according to the signal the first operating cylinder 51 and the first Extending velocity of the working cylinder 61 Delayed by giving the donor is artificially reduces the rotational speed of the sluice (30).

At this time, since the water gate according to the present invention is formed asymmetrically longer than the water storage side around the rotation axis of the drain plate 31 and both side plates 32 in the open position of the water gate 30 is about 270 ° When fully rotated at an angle, the water-side plate 31 and the side plate 32 are in contact with the bottom part of the housing 20 with the water-side plate 31 and both side plates 32 contacting the bottom of the housing 20 with respect to the opening of the water-gate 30 in the vertical direction. Since the waterway 11 can be closed by being erected, and the packing member 40 is fixed in the longitudinal direction of the water gate 30 on the outer side of the drainage side boundary of the water gate plate 31 and both side plates 32, The packing member 40 is a perfect packing between the water gate 30 and the housing 20.

In addition, the bottom part of the housing 20 in contact with the drainage side boundary portion of the sluice plate 31 and both side plates 32 is in a position parallel to the upper surface of the sluice plate 31 when opening the sluice 30 patent application Compared to 2006-118946, the length of the drainage side asymmetrically increased about the rotating shaft 33, the height of the drainage side rounded downward from the bottom of the housing 20, and the water gate 30 and As the thickness of the packing member 40 sandwiched between the bottom of the housing 20 and the height of the water gate increases, the storage space may be secured even more.

In the closed state of the water gate 30, since the first operating cylinder 51 is in the maximum contracted state, in order to rotate the water gate 30, the first operation cylinder 61 is first started to contract and then the first operation cylinder ( When the 51 starts to rotate, the first actuating cylinder 51 can be started to rotate, and the water gate 30 can be rotated in a clockwise direction. When the water gate 30 is slightly lifted from the closed state, the water gate 30 And a space is generated between the bottom of the housing 20 and the lower layer water of the reservoir is discharged through the space so that foreign substances such as sedimentation sludge deposited on the bottom of the stream are discharged together with the stream water, thereby accelerating the material acceleration and material cutting. The structure which naturally cleans up the contaminated water quality by the phenomenon, material removal action, material flotation action, is completed.

When the first operation cylinder 51 is continuously extended, the water gate 30 is rotated about the rotation axis 33, and when the rotation angle exceeds 90 ° from the closing time, the water gate 30 is the hydrology plate 31. Rotating the sluice 30 to prevent it from falling due to rapid rotation in the clockwise direction due to its own weight, the position where the sluice plate 31 becomes horizontal is combined with the integrated control system 100. Detects through a detection sensor (not shown) and slows down the expansion speed of the first operation cylinder 51 according to the signal, thereby artificially reducing the rotational speed of the water gate 30, and of the first operation cylinder 51 When the first operating cylinder 51 is gradually contracted while the second operating cylinder 61 is extended at the maximum elongation time, the water gate 30 may be completely opened.

Here, the positions of the first operation cylinder 51, the second operation cylinder 61, the operation link 34 applied to the third embodiment of the present invention can be changed to any other position, and thus, each of these members Do not change the installation location of the product or place special restrictions on the installation height.

In addition, in each embodiment of the present invention, but the lower end portion of the sluice plate 31 is made of the same horizontal as the upper surface, for example, both sides of the sluice plate 31 may be formed continuously with the same curvature, such deformation It is a matter of course that the disclosed embodiments fall within the scope of the present invention.

In addition, by installing the river water purification hydrology having a configuration according to each embodiment of the present invention in a multi-stage on the inclined portion of the river, the natural water quality to work while exiting the lower end of the water gate 30 is installed in multiple stages It may be configured to be more effectively purified by the actions, it is obvious that such modified embodiments are also within the scope of the present invention.

Fourth Embodiment

FIG. 20 is a front sectional view of the revolving door according to the fourth embodiment of the present invention, and FIG. 21 is a side cross-sectional view of the revolving door according to the fourth embodiment of the present invention. 61 is omitted.

The fourth embodiment of the present invention is a modification of the third embodiment, and all configurations are the same as the third embodiment of the present invention, except that the sluice plate 31, both side plates 32, and the rotation shaft 33 of the sluice gate 30 are provided. ) Is configured to be symmetrical, both side plate 32 is configured in a "ㅗ" shape on the side, the same side to be in sliding contact with the rounded surface of the housing 20 on both sides of the sluice plate 31 The curvature is rounded and fixed by fixing members 80 such as bolt-nuts and lower surfaces of both side plates 32.

In this configuration, since the sluice plate 31 can be assembled to both side plates 32, the sluice 30 can be manufactured very easily, and both side plates 32 do not have to be formed in a triangle shape. The manufacturing cost can be reduced.

In addition, the first operation cylinder 51 and the second operation cylinder 61 has an advantage of opening and closing the waterway 11 while rotating the water gate 30 at an angle of 360 ° through the interlocking operation, the housing 20 and Since only two operation cylinders 51 and 61 need to be positioned in the enclosed space 12 between the support structures 10, the installation is simple and prevents direct contact between water and each operation cylinder 51 and 61. There is an advantage.

In addition, although the first operating cylinder 51 is disposed in the vertical form and the second operating cylinder 61 is disposed in the horizontal form in the drawing, the first embodiment is applied to the fourth embodiment of the present invention. Since the installation positions of the first operation cylinder 51 and the second operation cylinder 61 can be variously configured, such as a horizontal form, a vertical form, and an inclined form, the installation position is not limited.

[Example 5]

Figure 22 is a side cross-sectional view at the time of opening the rotating door according to the fifth embodiment of the present invention, Figure 23 is a side cross-sectional view at the time of maximum operation cylinder of the rotating door according to a fifth embodiment of the present invention, Figure 24 is a present invention A side cross-sectional view at the time of maximum injury of the rotating gate according to the fifth embodiment of the present invention, Figure 25 is a side cross-sectional view at closing of the rotating gate according to the fifth embodiment of the present invention.

As shown, the rotating gate according to the fifth embodiment of the present invention is a channel 11 is formed between the two support structures 10 coupled to the integrated control system (not shown), both support structures 10 The housing 20 is covered on the opposite surface of the) so that a sealed space 12 is formed between the housing 20 and the support structure 10, and is formed at both ends of the arc-shaped hydrograph plate 31 and the hydrograph plate 31. The water gate 30 is composed of both side plates 32 and the rotation shaft 33 drawn outward from both side plates 32 formed at right angles, and the rotation shaft 33 of the water gate 30 is formed in each housing 20. It is inserted into the shaft hole 21.

In such a rotating door, the drain side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates ( 32 is formed symmetrically about the rotation axis 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the surface rounded downward in the housing 20 On the basis of the fully open state of the water gate (30), the heavy material 101 is built in the drain side end of the water gate plate (31).

"의 형상으로 이루어진 작동봉(102)이 회전축(33)에 고정되며, 작동봉(102)의 회전축 고정부위 반대측 단부에는 작동실린더(103)의 피스톤로드(104) 선단부가 회전가능하게 연결된다.In addition, in the closed space position of the rotating shaft 33, the plane "

The actuating rod 102 having a shape of "is fixed to the rotating shaft 33, the end of the piston rod 104 of the actuating cylinder 103 is rotatably connected to the end opposite to the rotating shaft fixed portion of the actuating rod 102.

At this time, the operation cylinder 103 is located in the same direction as the channel opening and closing position of the water gate 30 so that its rear end is rotatably fixed at a position higher than at least the height of the rotation shaft 33, when the water gate 30 is fully opened On the basis of the operating rod 102 is configured to face the direction of the operation cylinder 103 at the same angle as the width direction of the horizontal sluice plate 31.

The rotatable gate according to the fifth embodiment of the present invention configured as described above is rotatably fixed to the rear end of the actuating cylinder 103 higher than the rotation axis 33 of the sluice 30 and the actuating rod 102 is a sluice plate ( 31) the gate 30 is rotated in a counterclockwise direction when the operation cylinder 103 is elongated according to the command of the integrated control system 100 while the gate 30 is fully open. Since the rear end of the operation cylinder 103 is rotatably fixed to a position higher than the position of the rotation shaft 33, the sluice plate 31 does not reach a horizontal state at the maximum extension position of the operation cylinder 103, but the sluice plate 31 Since the center of gravity is moved to the opposite side of the opening by the weight 101 built in the), the water gate 30 starts to rotate in the direction of closing by its own weight.

When the center of gravity of the sluice 30 is crossed in the direction of closing, the sluice 30 is rotated by its own weight, and the operation cylinder 103 starts to contract, so that the sluice plate 30 is not rapidly rotated. When the 31 is rotated 180 °, it detects that the water gate 30 is rotated 180 ° through a position sensor (not shown) and controls the hydraulic pressure applied to the operation cylinder 103 according to the signal to operate the cylinder 103 ), The closing speed of the sluice gate 30 can be adjusted.

If the contraction of the operation cylinder 103 is stopped at the time when the water gate 30 is closed, the water gate plate 31 is erected upright, and the lower surface of the water gate plate 31 of the water gate 30 is in close contact with the housing 20. Water is not discharged and is filled.

When the operation cylinder 103 is contracted in the closed state of the water gate 30, the water gate 30 is rotated in a direction in which the water gate 30 is opened by the self-weight and the contracting force of the operation cylinder 103, and the water is stored according to the rotation of the water gate 30. Water filled in the space starts to discharge upward of the water gate (30).

When the water gate 30 is completely rotated by its own weight, the bottom surface of the water gate 30 is positioned below the drainage side rounded surface of the housing 20, and the bottom surface of the housing 20 and the top surface of the water gate plate 31 are horizontal. The lower surface of the sluice plate 31 and the surface rounded toward the drainage side of the housing 20 are in close contact with each other so that a large amount of foreign matter, such as a twig floating with the water, does not flow between the housing and the sluice. It is discharged at speed.

That is, according to the fifth embodiment of the present invention, only one operating cylinder 103 can open and close the water channel 11 while rotating the water gate 30 by 360 °, so that the water opening and closing operation of the water channel 11 required as the water gate 30 is performed. Means that it can run smoothly, reduce equipment costs and shorten air.

Here, the position of the operating cylinder 103 and the operating rod 102 applied to the fifth embodiment of the present invention can be changed to any other position, and thus, even if the installation position of each of these members is changed It is natural to fall within the scope of rights.

[Sixth Embodiment]

FIG. 26 is a sectional front view of a rotatable hydrograph according to a sixth exemplary embodiment of the present invention, FIG. 27 is a side cross-sectional view of the rotatable hydrographic gate according to a sixth exemplary embodiment of the present invention, and FIG. 28 is a sixth exemplary embodiment of the present disclosure. Fig. 29 is a side cross-sectional view at the time of maximum operation of a rotating door according to a sixth embodiment of the present invention, and Fig. 30 is a rotational speed according to the sixth embodiment of the present invention. Side sectional view of the closing door.

The sixth embodiment of the present invention is a modified embodiment of the fifth embodiment, and like the fifth embodiment, the channel 11 is disposed between the two support structures 10 coupled to the integrated control system (not shown). It is formed, the housing 20 is covered on the opposite surface of the two support structures 10, respectively, a sealed space 12 is formed between the housing 20 and the support structure 10, and the arc-shaped watermark plate 31 and The sluice gate 30 is composed of both side plates 32 formed at right angles in both ends of the sluice plate 31 and a rotation shaft 33 drawn outward from both side plates 32, and the rotation shaft 33 of the sluice gate 30 is formed. It is inserted into the shaft hole 21 formed in each of the housing 20.

In such a rotating door, the drain side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates ( 32 is formed symmetrically about the rotation axis 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the surface rounded downward in the housing 20 On the basis of the fully open state of the water gate (30), the heavy material 101 is built in the drain side end of the water gate plate (31).

"의 형상으로 절곡된 크랭크부(102')가 회전축(33)과 일체로 고정되고, 그 양측이 지지대(38)에 의해 밀폐공간(12)의 바닥부에 회전가능하게 지지되며, 크랭크부(102')의 중앙에는 작동실린더(103)의 피스톤로드(104) 선단부가 회전가능하게 연결된다.In addition, in the closed space position of the rotating shaft 33, "

Crank portion 102 'bent in the shape of "is integrally fixed to the rotary shaft 33, both sides are rotatably supported by the support 38 to the bottom of the sealed space 12, the crank portion ( 102 '), the front end of the piston rod 104 of the operating cylinder 103 is rotatably connected.

At this time, the operation cylinder 103 is located in the same direction as the channel opening and closing position of the water gate 30 so that its rear end is rotatably fixed at a position higher than at least the height of the rotation shaft 33, when the water gate 30 is fully opened On the basis of the crank portion (102 ') is configured to face the direction of the operation cylinder 103 at the same angle as the width direction of the horizontal sluice plate (31).

In the rotating door according to the sixth embodiment of the present invention configured as described above, the rear end of the operation cylinder 103 is rotatably fixed at a position higher than the rotation shaft 33 of the water gate 30 and is fixed integrally with the rotation shaft 33. Since the crank part 102 'is formed at an angle parallel to the sluice plate 31, when the operation cylinder 103 is elongated according to the command of the comprehensive control system 100 while the sluice 30 is fully open, 30 can be rotated counterclockwise, and the rear end of the operation cylinder 103 is rotatably fixed at a position higher than the position of the rotation shaft 33 so that the sluice plate 31 at the maximum extension position of the operation cylinder 103 can be obtained. Although the horizontal state does not reach the horizontal center of gravity due to the weight 101 is built in the sluice plate 31, the water gate 30 starts to rotate in the direction closed by its own weight.

When the center of gravity of the sluice 30 is crossed in the direction of closing, the sluice 30 is rotated by its own weight, and the operation cylinder 103 starts to contract, so that the sluice plate 30 is not rapidly rotated. When the 31 is rotated 180 °, it detects that the water gate 30 is rotated 180 ° through a position sensor (not shown) and controls the hydraulic pressure applied to the operation cylinder 103 according to the signal to operate the cylinder 103 ), The closing speed of the sluice gate 30 can be adjusted.

If the contraction of the operation cylinder 103 is stopped at the time when the water gate 30 is closed, the water gate plate 31 is erected upright, and the lower surface of the water gate plate 31 of the water gate 30 is in close contact with the housing 20. Water is not discharged and is filled.

When the operation cylinder 103 is contracted in the closed state of the water gate 30, the water gate 30 is rotated in the direction of opening by the self-weight and the contraction force of the operation cylinder 103, and according to the rotation of the water gate 30. Water filled in the reservoir begins to discharge upward of the water gate (30).

When the water gate 30 is completely rotated by its own weight, the bottom surface of the water gate 30 is positioned below the drainage side rounded surface of the housing 20, and the bottom surface of the housing 20 and the top surface of the water gate plate 31 are horizontal. The lower surface of the sluice plate 31 and the surface rounded toward the drainage side of the housing 20 are in close contact with each other so that a large amount of foreign matter, such as a twig floating with the water, does not flow between the housing and the sluice. It is discharged at speed.

That is, according to the sixth embodiment of the present invention, since the rotating shaft 33 is rotated in a crank manner, the water channel 11 can be opened and closed while rotating the water gate 30 by 360 ° without any interference with only the operation cylinder 103. The opening and closing operation of the water channel 11 required as the water gate 30 means that the equipment cost can be reduced and the air can be shortened while performing smoothly.

Here, the positions of the operation cylinder 103 and the crank portion 102 'applied to the sixth embodiment of the present invention can be changed to any other position, and thus, even if the installation position of each of these members is changed, the present invention It is natural that they fall within the scope of their rights.

[Seventh Embodiment]

Figure 31a is a side cross-sectional view when opening the rotating gate according to the seventh embodiment of the present invention, Figure 31b is a perspective view of the water gate operating portion when opening the rotating gate according to the seventh embodiment of the present invention, Figure 32a is a FIG. 32B is a perspective view of a sluice door operating part when the sluice door is closed according to the seventh embodiment of the present invention, and FIG. 33A is a perspective view of the sluice door operating part according to the seventh embodiment of the present invention. Side cross-sectional view when discharging the lower end of the rotating door, Figure 33b is a perspective view of the sluice operating part when discharging the lower end of the rotating door according to the seventh embodiment of the present invention.

As shown, the rotatable gate according to the seventh embodiment of the present invention is a channel 11 is formed between the two support structures 10 coupled to the integrated control system (not shown), both support structures 10 The opposite surface of the housing 20 is covered with each other, such a sealed space 12 is formed between the housing 20 and the support structure 10, the right angles at both ends of the hydrological plate 31 and the hydrological plate 31 The sluice gate 30 is composed of both side plates 32 and rotation shafts 33 drawn outward from both side plates 32, and the shaft shafts of the sluice gates 30 are formed in the respective housings 20. It is inserted into 21.

In such a rotating door, the drain side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates ( 32 is formed symmetrically about the rotating shaft 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing (20) .

In addition, a pair of operation links 34 are fixed to the rotation shaft 33 at a closed space position of the rotation shaft 33, and a piston rod of the operation cylinder 103 ′ between opposite sides of the rotation shaft fixing portion of the operation link 34. 104 ') The tip is rotatably connected.

At this time, the operation cylinder 103 'is located in the same direction as the waterway opening and closing position of the water gate 30, the operation link 34 is fixed to the rotating shaft 33 in the operation cylinder 103' installation direction, the operation cylinder ( 103 ') and the actuating link 34 may be installed at any position such that the lower side angle therebetween is less than 180 ° based on the full opening of the water gate 30.

In the rotary door according to the seventh embodiment of the present invention configured as described above, since the lower angle between the operation cylinder 103 'and the operation link 34 is less than 180 ° based on the full opening of the water gate 30, the water gate ( When the operation cylinder 103 'is elongated according to the command of the comprehensive control system 100 in the fully open state 30, the water gate 30 can be rotated clockwise, and the water gate plate 31 can be rotated in the vertical direction. When built up, the lower surface of the sluice plate 31 of the sluice 30 and the housing 20 are in close contact with each other, and the sluice plate 31 has the highest height to achieve a completely closed state. It is filled.

When the operation cylinder 103 'is further extended in the closed state of the water gate 30, a space is generated between the water gate plate 31 and the housing 20, and the lower layer water of the reservoir space is discharged through the space, Foreign substances such as sewage sludge deposited on the floor will escape like river water, which causes natural acceleration, mass cutting, material desorption, and material flotation.

On the other hand, when the actuating cylinder 103 'is contracted in the closed state or the lower water discharge state of the water gate 30, the water gate 30 is rotated in the direction opened by its own weight and the contracting force of the actuating cylinder 103', As the water gate 30 rotates, the water filled in the reservoir starts to be discharged upward of the water gate 30.

When the water gate 30 is completely rotated by its own weight, the bottom surface of the water gate 30 is positioned below the drainage side rounded surface of the housing 20, and the bottom surface of the housing 20 and the top surface of the water gate plate 31 are horizontal. The lower surface of the sluice plate 31 and the surface rounded toward the drainage side of the housing 20 are in close contact with each other so that a large amount of foreign matter, such as a twig floating with the water, does not flow between the housing and the sluice. It is discharged at speed.

That is, according to the seventh embodiment of the present invention, the water channel 11 can be opened and closed with only one operation cylinder 103 ', and the lower water of the storage space is discharged through the space between the water gate 30 and the housing 20. It is possible to purify the water quality, to reduce the equipment cost and at the same time shorten the air.

Here, the positions of the operation cylinder 103 'and the operation link 34 applied to the seventh embodiment of the present invention can be changed to any other position, and thus, even if the installation position of each of these members is changed, the present invention It is natural that they fall within the scope of their rights.

[Eighth Embodiment]

34 is a sectional front view of a rotating gate according to an eighth embodiment of the present invention.

As shown, the rotating gate according to the eighth embodiment of the present invention is a channel 11 is formed between the two support structures 10 coupled to the integrated control system (not shown), both support structures 10 The opposing surfaces of the housings 20 are respectively covered with a sealed space 12 is formed between the housing 20 and the support structure 10, the right angles at both ends of the sluice plate 31 and the sluice plate 31 The sluice gate 30 is composed of both side plates 32 and rotation shafts 33 drawn outward from both side plates 32, and the shaft shafts of the sluice gates 30 are formed in the respective housings 20. It is inserted into 21.

In this rotation gate, the rotation shaft 33 is rotatably connected to the reducer 105 in the closed space position, the drive motor 106 is connected to the reducer 105 so as to transmit power.

At this time, the reduction gear 105 is a bevel gear, a worm gear, a helical gear, a ring gear if the gear ratio of the driving side is relatively small compared to the gear ratio of the driven side so that the power of the driving side can be decelerated and transmitted to the driven side. All the reduction gears of any type can be applied, so specific examples thereof are omitted.

In addition, the driving motor 106 may also apply a general electric motor, or may apply a hydraulic motor is not particularly limited to the type of motor.

Reference numeral 38 in the drawings denotes a support for supporting the rotating shaft 33 in the sealed space 12, and 36 denotes a packing plate for preventing leakage through the shaft hole 21 of the housing 20.

The rotating gate according to the eighth embodiment of the present invention configured as described above, when the driving motor 106 is driven in accordance with the command of the comprehensive control system 100 in the state in which the gate 30 is completely open, the rotational force of the speed reducer ( Slowly transmitted to the rotating shaft 33 through the 105, the rotating shaft 33 receives such a driving force to be able to open and close the waterway 11 while rotating the water gate 30 in the 360 ° direction.

Therefore, it is possible to keep the water gate 30 in an open state, the closed state, or the bottom discharge state by stopping the water gate 30 at a desired position by the command of the integrated control system 100. Do.

When the water gate 30 is rotated, the speed is not fast but a large force is required. When the rotational force of the driving motor 106 is transmitted to the rotating shaft through the reducer 105 as in the eighth embodiment of the present invention, the speed is increased. Is decelerated, but as much as the corresponding force is exerted, it is possible to provide an appropriate speed and force to drive the gate (30).

[Example 9]

35 is a sectional front view of a rotating water gate according to a ninth embodiment of the present invention.

As shown, the rotating gate according to the ninth embodiment of the present invention has a water channel 11 formed between the two support structures 10 coupled with the integrated control system (not shown). The opposing surfaces are respectively covered with housings 20 so that a sealed space 12 is formed between the housing 20 and the supporting structure 10, and the arcuate hydrology plates 31 and the hydrology plates 31 are perpendicular to both ends. The water gate 30 is composed of both side plates 32 and the rotating shaft 33 drawn outward from both side plates 32, the shaft shaft of the water gate 30 is formed in each housing 20 ( 21) is made.

In this rotational gate, the rotating shaft 33 is directly connected to the hydraulic actuator 106 'to adjust the flow rate of the oil supplied to the hydraulic actuator 106' to control the rotational speed.

Reference numeral 38 in the drawings denotes a support for supporting the rotating shaft 33 in the sealed space 12, and 36 denotes a packing plate for preventing leakage through the shaft hole 21 of the housing 20.

The sluice gate according to the ninth embodiment of the present invention configured as described above has a hydraulic actuator when oil is introduced into the hydraulic actuator 106 'according to the command of the comprehensive control system 100 while the sluice 30 is completely open. 106 'is rotated, and the rotational force is transmitted directly to the rotation shaft 33 to open and close the waterway 11 while rotating the water gate 30 in the 360 ° direction.

Therefore, it is possible to keep the water gate 30 in an open state, the closed state, or the bottom discharge state by stopping the water gate 30 at a desired position by the command of the integrated control system 100. Do.

However, since the speed should not be fast when the water gate 30 is rotated, when the oil is introduced into the hydraulic actuator 106 ', the oil inflow rate is adjusted to control the hydraulic actuator 106' to be rotated at an appropriate speed. The water gate 30 can be rotated at an appropriate speed.

[Example 10]

36 is a sectional front view of a rotating gate according to a tenth embodiment of the present invention.

As shown, the rotating gate according to the tenth embodiment of the present invention is a water channel 11 is formed between the two support structures 10 coupled to the integrated control system (not shown), both support structures 10 The opposite surface of the housing 20 is covered with each other, such a sealed space 12 is formed between the housing 20 and the support structure 10, the right angles at both ends of the hydrological plate 31 and the hydrological plate 31 The sluice gate 30 is composed of both side plates 32 and rotation shafts 33 drawn outward from both side plates 32, and the shaft shafts of the sluice gates 30 are formed in the respective housings 20. It is inserted into 21.

In this rotational gate, the winding roll 33a is fixed to the closed space position of the rotating shaft 33, the drive motor 106 is fixed to the closed space 12, and the rotating shaft 33 is fixed to the axis of the drive motor 106. The winding roll 33a and the winding roll 106a corresponding to the winding roll 33a are fixed, and the wire rope 107 is connected between the winding rolls 33a and 106a.

At this time, the position of the drive motor 106 can be fixed regardless of any position in the closed space 12 can be rotated in the direction opposite to the rotation direction of the water gate 30, each winding roll (33a) ( It is obvious that the position of 106a) should be the same vertical position.

Reference numeral 38 in the drawings denotes a support for supporting the rotation shaft 33 in the closed space 12.

The rotating gate according to the tenth embodiment of the present invention configured as described above has the winding roll 106a when the driving motor 106 is driven in accordance with the command of the comprehensive control system 100 in a state in which the gate 30 is completely open. Winding the wire rope 107 through), the winding roll (33a) is relatively fixed to the rotating shaft 33, the wire rope 107 is naturally loosened while the wire rope 107 is released to rotate the rotating shaft 33, Accordingly, the water gate 30 starts to rotate.

If the drive motor 106 is continuously driven to rotate the water gate 30 and the driving motor 106 stops driving at the position where the water gate plate 31 of the water gate 30 becomes vertical, the water gate 30 is completely closed. When the water is not discharged and filled in the storage space, and the driving motor 106 in this state to rotate the water gate 30 a little more, the 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 are discharged like the river water. The polluted water quality is generated and naturally purified.

At this time, when the water gate 30 is excessively rotated so that the center of gravity of the water gate 30 is crossed in the opposite direction of the opening and closing position based on the rotation shaft 33, the center of gravity of the water gate 30 is rotated ( It is preferable to limit the length of the wire rope 107 so as not to fall in the opposite direction of the opening and closing position based on 33).

On the other hand, when the drive motor 106 is rotated in the reverse direction in the closed position or the bottom discharge position of the water gate 30, the wire rope 107 is released from the winding roll 106a fixed to the shaft of the drive motor 106, At the same time, as the water gate 30 becomes free, the winding roll 33a fixed to the rotating shaft is rotated by its own weight to rewind the wire rope 107, until the water gate 30 is completely opened. The descent stops, and at this point, the driving of the driving motor 106 is also controlled to stop. When the water gate 30 is opened in this way, the water in the reservoir space can be discharged at a high speed to the upper portion of the water gate plate 31. It is.

Accordingly, according to the tenth embodiment of the present invention, the rotational force of the driving motor 106 is transmitted to the water gate 30 through the wire rope 107 to rotate the water gate 30, or by the weight of the water gate 30. Rotation is made to be able to open and close the water gate (30).

[Eleventh embodiment]

FIG. 37 is a side cross-sectional view of the revolving door according to the eleventh embodiment of the present invention, and FIG. 38 is a side cross-sectional view of discharging lower water in the closed state of the revolving door according to the eleventh embodiment of the present invention. 39 is a side cross-sectional view when opening the rotating gate according to the eleventh embodiment of the present invention.

The eleventh embodiment of the present invention is configured to purify the contaminated river water by discharging the lower layer water in the reservoir space without manipulating the water gate 30 in the state in which the water gate 30 is closed. The variable operating plate installed on the water storage side to expand and contract the third operation cylinder 71 to the drainage side, and in the middle of the rounded portion in the bottom direction of the bottom of the housing 20 in accordance with the expansion and contraction of the third operation cylinder 71 ( 72) is fixed to the tip of the piston rod of the third operating cylinder (71). And the rest of the configuration is the same as the first to eighth embodiments of the present invention.

In the drawings, for the sake of convenience, the tenth embodiment is applied to the rotating door according to the first embodiment of the present invention.

When the water gate 30 is closed in this configuration, the third operation cylinder 71 is extended to remove the variable operation plate 72 from the housing 20 and the packing attached to the water gate 30 on the upper surface thereof. By making the member 40 contact, it is possible to prevent the water in the reservoir space from leaking.

However, in the first to tenth embodiments of the present invention, the insecure first working cylinder 51 and the second working cylinder 61 are discharged in order to discharge the lower layer water in the storage space while the water gate 30 is closed. Since it was necessary to lift the gate 30 by driving, driving the operating cylinder, or driving the driving motor, as much fuel or power consumption was required as the corresponding bar, in the eleventh embodiment of the present invention, as described above, ) Is configured to discharge the lower layer water in the storage space with a simple operation even when the) is closed. When the third operation cylinder 71 is contracted in the state where the water gate 30 is closed, the piston rod is fixed to the end of the piston rod. The variable operation plate 72 may be retracted to be received inside the housing 20, and the water gate 30 may be connected to the first operation cylinder 51, the second operation cylinder 61, and a connecting member such as a chain. To maintain state Therefore, a space is generated between the sluice gate 30 and the housing 20 so that the lower layer water of the reservoir can be discharged through the space, and foreign substances such as sedimentary sludge deposited on the bottom of the river are generated by the action. Together, the polluted water can be purged by the acceleration of the material, the crushing of the material, the release of the material, and the floating of the material.

Of course, when the water gate 30 is rotated to the open position again when the water gate 30 is closed, the third operation cylinder 71 is extended to draw out the variable operation plate 72 to the outside of the housing 21. The front end portion may be in close contact with the arc-shaped side wall of the sluice plate 31 to prevent foreign matter from being caught between the sluice 30 and the variable operating plate 72.

In addition, in the eleventh embodiment of the present invention, the variable operation plate 72 is lifted out through the cylinder method as an example, but in addition to the cylinder method, the rope traction type, the screw method, the rack-pinion method, and the crank method may be used for various methods. By virtue of being able to linearly reciprocate the variable operating plate 72, this modified embodiment is naturally within the scope of the present invention.

In addition, although the packing structure between the housing 20 and the variable operating plate 72 has not been described in the eleventh embodiment of the present invention, the variable operating plate entrance and exit of the housing 20 is independent of the appearance of the variable operating plate 72. And a flexible packing member may be provided around the entrance and exit of the variable operation plate of the housing 20 so that the packing can be always made between the variable operation plate 72 and the housing 20 and the variable operation plate 72. Any configuration may be applicable as long as it can be packed to prevent leakage. In addition, these embodiments are naturally within the scope of the present invention.

In addition, the structure of the base plate and the operating plate applied to the present invention is different in shape or position, or the configuration of the change in the operation order is possible as many modifications can be made by those skilled in the art it is natural that these design changes should be punished immediately.

In addition, it can be configured to replace the function by using another form of shape to show the function of the support plate and the operating plate applied to the present invention, it is natural that the modification of the function also falls within the scope of the present invention.

In addition, it is natural that such a design change also falls within the scope of the present invention because the pulling or contracting device configured as a cylinder can be configured by using a variable shrinking member such as a reducer.

In addition, the structure of the comprehensive control system 100 is configured to operate properly when the program is applied to the structure of the control system that is known and used in accordance with the drive device combined with the water gate applied to the present invention suitably operates It is natural that the control system combined with the structure of the hydrology applied to the present invention falls within the scope of the present invention in order to smoothly operate the hydrology applied to the present invention.

In addition, the first operating cylinder 51 to change the direction of the long hole 67 constituted at the tip of the piston rod 66 of the second operating cylinder 61 of the present invention or to limit the movement of the long hole 67 to a certain distance. It is natural that such a design change is within the scope of the present invention as it is possible to constitute an apparatus for preventing the separation of the hole 67 in the above.

In addition, the bolt coupling method between the sluice plate 31 and the side plates 32 to be applied to the eleventh embodiment of the present invention can be changed by any number using various known members, such a design change also the present invention It is natural that they fall within the scope of their rights.

[Twelfth Example]

FIG. 40 is a detailed perspective view of the sluice operating part of the sluice door according to the twelfth embodiment of the present invention, FIG. 41 is a sectional view of the sluice operating part of the sluice door according to the twelfth embodiment of the present invention, and FIG. FIG. 43 is a side cross-sectional view at the time of closing the rotating gate according to the twelfth embodiment, and FIG. 43 is a side cross-sectional view at the bottom discharge of the rotating gate according to the twelfth exemplary embodiment of the present invention.

As shown, the sluice gate according to the twelfth embodiment of the present invention, the sluice gate 30, the rotating shaft 33, the sluice gate 30 in the rotation gate according to the first to eleventh embodiments of the present invention Lifting the rotating members at a time to space between the lower end of the water gate 30 and the bottom of the housing 20 even in the state that the water gate 30 is closed to discharge the bottom water of the reservoir through this space contaminated river water To purify.

To this end, the overall configuration of the rotating door is selected from the first to eleventh embodiments of the present invention, the rotary shaft 33 in the sealed space 12 between the support structure 10 and the housing 20 It is installed to rotatably penetrate the center of the elevating block (90), and the elevating pipe (91) is fixed to each of the lower sides of the elevating block (90), each elevating pipe (91) is the bottom of the sealed space (12) The lift cylinders 93 are rotatably inserted into the bottom of the sealed space 12 in the inner spaces of the fixed pipes 92 and the lift pipes 91, respectively. While fixing each of the piston rod 94, the front end to the lower end of the elevating block 90, respectively rotatably fixed, the elevating block 90, each member for opening and closing the water gate 30 by rotating the rotary shaft 33 Fixing the respective gates according to the expansion and contraction of the lifting cylinder 93 in the state that the water gate 30 is closed ( To form a space between the 30 and the housing 20, it is configured to discharge the lower layer water in the reservoir space through this space to clean the contaminated river water. In the drawings, a twelfth embodiment of the present invention is shown as an example of a complex application with the third or fourth embodiment of the present invention.

In addition, the guide groove 22 is formed in the up-and-down direction at the rotation shaft insertion portion of the housing 20, and has a width larger than the width of the guide groove of the housing 20 at the adjacent portion of the housing of the rotation shaft 33 It is configured to fix the packing plate 23 having a length of more than twice to maintain the state in close contact with the wall surface of the housing 20, the packing plate guide groove of the housing 20 24 is formed so that the packing plate 23 can be moved forward and backward in the direction of the guide groove 22 and is always positioned at a predetermined position regardless of the rotation of the rotation shaft 33.

In this configuration, since all members such as cylinders for rotating the rotating shaft 33 to open and close the water gate 30 are fixed to the lifting block 90, the lifting block 90 does not move. When driving the members for the rotation of the water gate according to the low water level, flow rate, pollution degree, etc. while the water gate 30 is rotated at a predetermined angle to open and close the waterway 11 to discharge water or to store water.

When the lifting cylinder 93 is extended in the state in which the water gate 30 is closed during the opening and closing process of the water gate 30, the piston rod 94 of the lifting cylinder 93 is extended to raise the lifting block 90. The rotation shaft 33 is rotatably fixed to the elevating block 90, and a member such as an operation cylinder for rotating the rotation shaft 33 is fixed so that the elevating block 90 raises the rotation shaft 33. ) And the operating member is raised together, the water gate 30 is also raised.

When the water gate 30 is raised, a space is formed between the lower end of the water gate 30 and the bottom of the housing 20, and through this space, the lower layer water of the reservoir can be discharged, and the bottom of the river can be discharged by this action. Foreign substances such as sewage sludge deposited on the surface of the sediment can flow out like river water, and contaminated water quality can be purified by material acceleration, material scavenging, material releasing, and material flotation.

Of course, although the bottom water discharge operation is not shown, the sensor can measure the level of water level, the flow rate, and the pollution of the stored water and automatically control it under the control of the integrated control system. If the water gate is closed after performing the water discharge operation, it is possible to maintain an appropriate level in the reservoir.

In addition, when the low water level is rapidly increased, the water gate 30 is opened from the bulky foreign matter by rotating the water gate 30 to the open position to fully open the water passage 11 while returning the lifting block 90 to the original position. ) Can be protected.

At this time, the guide groove 22 is formed in the rotation shaft insertion portion of the housing 20 in the up and down direction so that the rotation shaft 33 and the water gate 30 operate naturally without any interference, and the water gate 30 is raised. Even when the lowering operation, the packing plate 23 moves up and down along the packing plate guide groove 24 of the housing 20, so that the packing plate 23 always covers the guide groove 22 of the housing 20, so that water may cover the guide groove 22. There is no fear to flow into the inside of the housing 20, and even if the rotating shaft 33 is rotated, because the packing plate 23 is seated in the packing plate guide groove 24, it does not rotate like the rotating shaft 33 You can always keep a fixed position.

In addition, when the elevating block 90 ascends and descends according to the expansion and contraction of the elevating cylinder 93, the elevating pipe 91 is raised and lowered like the elevating block 90, but the elevating pipe 91 slides inside the fixed tube 92. Since the lifting block 90 and the elevating pipe 91 are moved up and down, the elevating pipe 91 and the fixed pipe 92 cover the elevating cylinder 93 at all times, so that foreign substances such as dust are lifted up and down. (93) can be prevented from entering.

In addition, in the twelfth embodiment of the present invention, the lifting block 90 is configured as a hexahedral shape as an example, but the lifting block 90 has a shape according to the position of the member for rotating the rotation shaft 33. Since any shape can be changed, it is a matter of course that all the configurations made by changing the shape belong to the scope of the present invention.

In addition, the modified embodiment is a right of the present invention because it is possible to purify the contaminated water in multiple stages by using the method of installing the rotary gate according to the first to twelfth embodiments of the present invention in a multi-stage stream. It is natural to fall within the scope.

[Thirteenth Embodiment]

FIG. 44 is a perspective view of a sluice door according to a thirteenth embodiment of the present invention, FIG. 45 is a side cross-sectional view when the sluice door is closed according to a thirteenth embodiment of the present invention, and FIG. 46 is a thirteenth embodiment of the present invention. As a cross-sectional side view of the rotating gate according to the present invention, the members for rotating the gate 30 are according to the first to twelfth embodiments of the present invention, and thus the members for rotating the gate 30 in FIGS. 44 to 46. The illustration is omitted.

"형상의 지지틀(111)을 위치시키고, 지지틀(111)의 양측 상부에는 회전축(112)을 각각 구비하여 각 회전축(112)이 하우징(20)의 측벽을 관통하도록 하며, 하우징(20)과 지지구조체(10) 사이의 밀폐공간(12)에서 회전축(112)에는 작동링크(116)를 고정하여 여기에 지지틀 작동실린더(113)의 피스톤로드(114) 선단부를 회전가능하게 각각 연결하고, 지지틀 작동실린더(113)의 후단부는 밀폐공간(12)에서 하우징(20)의 내측벽 배수측에 회전가능하게 연결하며, 지지틀(111)의 배수측면에는 "

"형상의 패킹부재(115)를 부착하여 구성한 것이다.As shown, the rotating gate according to the thirteenth embodiment of the present invention, the border of the lower surface of the sluice plate 31 of the sluice 30 when closing the sluice 30 without interfering with the rotation operation of the sluice 30 In order to prevent the leakage between the three parts of the housing 20, and constitutes a rotating gate according to the first to twelfth embodiments of the present invention, the sluice plate 31 of the sluice 30 Three corners of the lower surface of the sluice plate 31 of the sluice gate 30 and the housing 20 on the basis of the state in which the sluice 30 is completely closed so that no leakage occurs between the three lower surfaces of the rim and the housing 20. Face to face to prevent position between

"Position the support frame 111 of the shape, the upper side of each side of the support frame 111 is provided with a rotating shaft 112 so that each rotating shaft 112 penetrates the side wall of the housing 20, the housing 20 In the enclosed space 12 between the support structure 10 and the rotating shaft 112 is fixed to the operation link 116 to connect the ends of the piston rod 114 of the support frame operating cylinder 113 to each other rotatably. , The rear end of the support frame operation cylinder 113 is rotatably connected to the inner wall drainage side of the housing 20 in the closed space 12, the drainage side of the support frame 111;

"The packing member 115 of the shape is attached and configured.

At this time, since the sluice plate 31 of the sluice 30 applied to the thirteenth embodiment of the present invention is formed in an arc shape centering on the rotating shaft 33, both sides of the support frame 111 and the packing member 115 are formed. The part is made of the same curvature as the sluice plate 31 on the side, the portion connecting between the lower portion of both sides of these support frame 111 is composed of a straight shape.

In addition, since the support frame 111 and the packing member 115 are located at the storage space side, the packing member 115 is preferably fixed to the support frame 111 by a plurality of fixing pins. The position between the sluice plate 31 and the housing 20 is expanded or contracted by the pressure of the support frame 111, and a circular or air layer is formed therein so as to smoothly pack the gap between the sluice plate 31 and the housing 20. It is composed of elliptical shape and the rest part is composed of straight shape.

According to the command of the integrated control system 100 in the state configured as described above to drive the operation cylinder according to the first to twelfth embodiments of the present invention to rotate the water gate 30 to the closed position, in this state each support When the frame operation cylinder 113 is extended, the piston rod 114 of the support frame operation cylinder 113 pushes the operation link 116. As a result, the support shaft 111 rotates while the rotation shaft 112 rotates. It rotates about the rotation shaft 112 until it stops by the lower surface of the sluice plate 31 of 30.

At this time, since the packing member 115 is attached to the drainage side of the support frame 111, when the support frame 111 is stopped by the lower surface of the sluice plate 31 of the sluice 30, the packing member 115 is disposed in the housing ( 20) and the seal between the sluice plate 31 is completely packed, so that the water filled in the reservoir does not leak between the sluice 30 and the housing 20, so that the sluice 30 is completely closed. Can be implemented.

When the support frame actuating cylinder 113 is contracted in the closed state of the water gate 30, the actuating link 116 is pulled and the support frame 111 is rotated to the water storage side about the rotating shaft 112, and the packing member 115 is closed. ) Is separated from the lower surface of the sluice plate 31 of the sluice 30 so as not to interfere with the rotation operation of the sluice 30, and thus the sluice 30 can be rotated and opened smoothly without any interference.

That is, according to the thirteenth embodiment of the present invention, when the water gate 30 is closed, the packing member 115 descends to completely seal the gap between the water gate 30 and the housing 20 to prevent water leakage. The water gate 30 can be completely closed, and when the water gate 30 is opened, the packing member 115 is separated from the water gate 30 so as not to interfere with the rotation operation of the water gate 30 at all.

In addition, the support frame operating cylinder 113 for operating the support frame 111 is located in the sealed space 12 between the housing 20 and the support structure 10, so that it is not in direct contact with water can extend the life. Of course, the reliability of the operation can be improved.

The rotating gate according to the thirteenth embodiment of the present invention is a patent application No. 2003-57386, Patent Application No. 2004-38599, Utility Model Registration Application No. 2002-5190, Utility Model Registration Application No. 2002-36293, Utility It is possible to apply to rotating doors such as Patent Application No. 2002-36934 as well as Patent Application No. 2006-102541 and Patent Application No. 2006-118946, which are the applicants of the present applicant. (30) It is possible to completely solve the leakage problem at the time of closing.

In addition, the support frame 111 applied to the thirteenth embodiment of the present invention may be made of any material such as stainless steel, non-ferrous metal, synthetic resin, etc., if the material does not corrode in a state of being immersed in water. Since it can be configured in any shape, such as rods, pipes, even if the material or shape of the support frame 111 is changed, it is natural that it belongs to the scope of the present invention.

In addition, the packing member 115 to be applied to the thirteenth embodiment of the present invention can be made of any material such as rubber, synthetic rubber, flexible synthetic resin, if the packing ability can be exhibited, in the thirteenth embodiment of the present invention Although the shape of the packing member 115 is illustrated as an example in which an air layer is formed on the packing part, the material or shape of the packing member 115 is changed since the packing part 115 can exhibit the same packing capacity even when a wing is put on the packing part. Even if it belongs to the scope of the present invention is natural.

In addition, in the thirteenth embodiment of the present invention, the support frame operating cylinder 113 is described as an example of being installed on the inner wall drainage side of the housing 20, but the support frame operating cylinder 113 is disposed in the housing 20. Since the support frame 111 can be operated in the same manner even if the side wall is installed on the water storage side and the operation is reversed to the above, the installation position of the support frame operation cylinder 113 can be changed as much as possible, and thus the support frame operation cylinder Even if the installation position of (113) is changed, it is natural that it belongs to the scope of the present invention.

[Example 14]

FIG. 47 is a perspective view of a rotational door according to a fourteenth embodiment of the present invention, FIG. 48 is a side cross-sectional view when closing the rotational door according to a fourteenth embodiment of the present invention, and FIG. 49 is a fourteenth embodiment of the present invention. A cross-sectional side view at the time of rotation of the rotating gate.

"형상의 지지틀(111)을 위치시키고, 지지틀(111)의 저수측에는 "

"형상의 패킹부재(115)를 부착하여 구성하며, 지지틀(111) 양측부의 저수측 중앙에는 "L"자 형상의 연결링크(117)를 회전가능하게 각각 고정하고, 각 연결링크(117)의 상부에는 회전축(112)을 각각 구비하여 이러한 각 회전축(112)이 하우징(20)의 측벽을 관통하도록 하며, 하우징(20)과 지지구조체(10) 사이의 밀폐공간(12)에서 회전축(112)에는 작동링크(116)를 고정하여 여기에 지지틀 작동실린더(113)의 피스톤로드(114) 선단부를 회전가능하게 각각 연결하고, 지지틀 작동실린더(113)의 후단부는 밀폐공간(12)에서 하우징(20)의 내측벽 배수측에 회전가능하게 연결하여 구성한 것이다.As shown, the sluice gate according to the fourteenth embodiment of the present invention is modified from the thirteenth embodiment of the present invention so as not to interfere with the rotational operation of the sluice gate 30, and the sluice gate when the sluice gate 30 is closed. When the packing member 115 and the water gate 30 are in close contact with each other while smoothly performing the basic function of preventing leakage between the three parts of the lower surface of the water gate plate 31 and the housing 20, the pressure is increased. To ensure uniform packing performance by acting uniformly to the packing member 115, as well as to prevent uneven wear of the packing member 115, to constitute a rotating water gate according to the first to twelfth embodiments of the present invention, The sluice plate 31 of the sluice 30 on the basis of the state in which the sluice 30 is completely closed so that no leakage occurs between the three edges of the sluice plate 31 lower surface of the sluice plate 30 and the housing 20. In the position that prevents the position between the three corners of the lower surface and the housing 20 Face "

"Position the support frame 111 of the shape, and on the reservoir side of the support frame 111"

It is configured by attaching a "shaped packing member 115, and each of the link links 117 is rotatably fixed to the" L "shaped connection links 117 at the center of the water storage side of both sides of the support frame 111. Rotating shafts 112 are provided at upper portions of the rotating shafts 112 so that each of the rotating shafts 112 penetrates the side wall of the housing 20, and the rotating shafts 112 are closed in the sealed space 12 between the housing 20 and the support structure 10. ) Is fixed to the operation link 116 to connect the front end of the piston rod 114 of the support frame operation cylinder 113 to each other, and the rear end of the support frame operation cylinder 113 in the closed space (12) It is configured to be rotatably connected to the inner wall drain side of the housing 20.

At this time, since the sluice plate 31 of the sluice 30 applied to the fourteenth embodiment of the present invention is formed in the shape of an arc centered on the rotating shaft 33, the support frame 111 and the packing as in the thirteenth embodiment. Both sides of the member 115 are made of the same curvature as the sluice plate 31 on the side, the portion connecting the lower portion of both sides of these support frame 111 is configured in a straight shape.

In addition, since the support frame 111 and the packing member 115 are located at the storage space side, the packing member 115 is preferably fixed to the support frame 111 by a plurality of fixing pins. The position between the sluice plate 31 and the housing 20 is expanded or contracted by the pressure of the support frame 111, and a circular or air layer is formed therein so as to smoothly pack the gap between the sluice plate 31 and the housing 20. It is composed of elliptical shape and the rest of the area is composed of straight shape.

According to the command of the integrated control system 100 in the state configured as described above to drive the operation cylinder according to the first to twelfth embodiments of the present invention to rotate the water gate 30 to the closed position, in this state each support When the frame actuating cylinder 113 is extended, the piston rod 114 of the support frame actuating cylinder 113 pushes the actuating link 116. Accordingly, the rotating shaft 112 rotates to drain the connecting link 117. It is rotated to the side, the support frame 111 that is rotatably fixed to the connecting link 117 is in close contact with the lower surface of the sluice plate 31 of the sluice 30 to the center around the rotating shaft 112 Is rotated.

At this time, since the packing member 115 is attached to the drainage side of the support frame 111, when the support frame 111 is stopped by the lower surface of the sluice plate 31 of the sluice 30, the packing member 115 is disposed in the housing ( 20) and the seal between the sluice plate 31 is completely packed, so that the water filled in the reservoir does not leak between the sluice 30 and the housing 20, so that the sluice 30 is completely closed. Can be implemented.

In addition, the connection link 117 is rotatably fixed to the center of the water storage side of the support frame 111 so that the support frame 111 rotates to the water storage side about the rotation shaft 112 of the connection link 117. Even if the bottom portion of the support frame 111 and the interference of the support frame 111 is slightly interfered with the rotational motion by the fluidity of the support frame 111, the support frame 111 is rotated to the drainage side of the sluice plate 31 of the sluice 30 1) When one side of the support frame 111 first touches the bottom surface and then the support frame 111 flows, the entire packing member 115 is in close contact with the lower surface of the sluice plate 31 of the sluice 30 and is supported. Since the connection link 117 is connected to the central portion of the water storage side of the mold 111, the pressure is uniformly applied to the entire support frame 111 through the connection link 117, and thus, between the water gate 30 and the housing 20. Not only the perfect packing is made in every gap but also the pressure applied to the packing member 115 becomes uniform. It is capable of preventing the imbalanced abrasion of 115.

When the support frame actuating cylinder 113 is contracted in the closed state of the water gate 30, the actuating link 116 is pulled and the rotating shaft 112, the connecting link 117, and the supporting frame 111 are centered on the rotating shaft 112. Is rotated to the water storage side, the packing member 115 is separated from the lower surface of the sluice plate 31 of the sluice 30 so as not to interfere with the rotation operation of the sluice 30, thus the sluice 30 is smooth without any interference It can be rotated to open.

That is, according to the fourteenth embodiment of the present invention, when the water gate 30 is closed, the packing member 115 is uniformly in close contact with the gap between the water gate 30 and the housing 20 to completely pack the water leakage. When the opening of the water gate 30 can be prevented, the packing member 115 is separated from the water gate 30 so as not to interfere with the rotation of the water gate 30 at all, and the water gate 30 and the housing ( 20) When the packing member 115 is in close contact with the gap therebetween, the pressure is uniform to realize perfect packing performance, and uniform wear is prevented by the uniform pressure applied to the packing member, thereby ensuring a long service life. It is.

In addition, the fourteenth embodiment of the present invention is similar to the twelfth embodiment of the Patent Application No. 2003-57386, Patent Application No. 2004-38599, Utility Model Registration Application No. 2002-5190, Utility Model Registration Application No. 2002- 36293, Utility Model Registration Application No. 2002-36934, of course, can completely solve the problem of leakage of the rotating gate, such as patent application No. 2006-102541, patent application No. 2006-118946.

In addition, the support frame 111 applied to the fourteenth embodiment of the present invention may be made of any material such as stainless steel, nonferrous metal, synthetic resin, etc., if the material does not corrode in a state of being immersed in water. Since it can be configured in any shape, such as rods, pipes, even if the material or shape of the support frame 111 is changed, it is natural that it belongs to the scope of the present invention.

In addition, the packing member 115 to be applied to the fourteenth embodiment of the present invention can be made of any material such as rubber, synthetic rubber, flexible synthetic resin as long as it can exhibit the packing capacity, in the fourteenth embodiment of the present invention Although the shape of the packing member 115 is shown as an example in which an air layer is formed on the packing part, even if a wing is put on the packing part, it is possible to exhibit the same packing capacity even if the material or shape of the packing member 115 is changed. Naturally, it belongs to the scope of the present invention.

In addition, in the fourteenth embodiment of the present invention, the supporting frame operating cylinder 113 is installed on the inner wall drain side of the housing 20 as an example, but the supporting frame operating cylinder 113 is disposed in the housing 20. Since the support frame 111 can be operated in the same manner even if the side wall is installed on the water storage side and the operation is reversed to the above, the installation position of the support frame operation cylinder 113 can be changed as much as possible, and thus the support frame operation cylinder Even if the installation position of (113) is changed, it is natural that it belongs to the scope of the present invention.

[Example 15]

FIG. 50 is a perspective view of a sluice door according to a fifteenth embodiment of the present invention, FIG. 51 is a sectional side view of the swivel door according to a fifteenth embodiment of the present invention, and FIG. 52 is a fifteenth embodiment of the present invention. Side cross-sectional view when discharging the bottom of the rotating door according to Figure 53 is a side cross-sectional view when opening the rotating door according to the fifteenth embodiment of the present invention.

The rotating gate according to the fifteenth embodiment of the present invention, by modifying the thirteenth or fourteenth embodiments of the present invention to seal the gap between the gate 30 and the housing 20 as well as to perform the bottom discharge operation In order to improve the water quality, all the rotating gates according to the first to twelfth embodiments of the present invention are applicable, and in the drawings, the seventh embodiment of the present invention is illustrated as an example.

In the rotational gate to which the fifteenth embodiment of the present invention is applied, a channel 11 is formed between both support structures 10 coupled to a comprehensive control system (not shown), and the opposite surfaces of both support structures 10 Each of the housings 20 is covered so that a sealed space 12 is formed between the housing 20 and the support structure 10, and formed at right angles at both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of the side plate 32 and the rotating shaft 33 drawn outward from both side plates 32, the rotating shaft 33 of the sluice 30 is inserted into each housing 20, the housing The drainage side of the bottom of the 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates 32 of the rotating shaft 33 Is formed symmetrically with respect to, the lower surface of both sides of the sluice plate 31 may be in close contact with the surface rounded downward of the housing 20 So as to be rounded at the same curvature.

"형상의 지지돌출부(111')를 위치시키고, 지지돌출부(111')의 배수측면에는 "

"형상의 패킹부재(115)를 부착하되, 지지돌출부(111')와 패킹부재(115)의 양측부는 수문(30)의 수문판(31) 곡률과 동일한 곡률로 형성하며, 하우징(20)의 수문 회전축 삽입위치에는 수평방향으로 긴 형상의 가이드홈(22')을 형성하여 여기에 수문(30)의 회전축(33)을 삽입한다. 이때, 회전축(33)의 하우징 인접부위에는 하우징(20)의 가이드홈(22') 폭보다는 더 큰 폭을 가지면서 그 길이보다는 2배 이상의 길이를 갖는 패킹판(23')을 회전가능하게 고정하여 상시 하우징(20)의 벽면과 밀착된 상태를 유지할 수 있도록 구성하고, 하우징(20)의 패킹판 접촉부위에는 패킹판가이드홈(24')을 형성하여 패킹판(23')이 가이드홈(22') 방향으로 전후진은 가능하면서 회전축(33)의 회전과 관계없이 항상 정해진 위치에 위치되도록 구성하게 된다.In this rotational door, the front door is located at a position close to the rim of the sluice plate of the housing 20 with respect to the state in which the sluice door 30 is completely closed.

&Quot; Position the support protrusion 111 'in the shape, and on the drain side of the support protrusion 111 "

"A shape of the packing member 115 is attached, but both sides of the support protrusion 111 'and the packing member 115 are formed to have the same curvature as the curvature of the sluice plate 31 of the sluice 30, and of the housing 20 At the insertion position of the water shaft rotation shaft, a guide groove 22 'having a horizontal shape is formed in the horizontal direction to insert the rotation shaft 33 of the water gate 30. At this time, the housing 20 is adjacent to the housing of the rotation shaft 33. It can be maintained in close contact with the wall surface of the housing 20 by rotatably fixing the packing plate 23 'having a width larger than the guide groove 22' of the width of the guide groove 22 'and more than twice its length. And a packing plate guide groove 24 'in the packing plate contact portion of the housing 20 so that the packing plate 23' can be moved back and forth in the direction of the guide groove 22 ', Regardless of rotation, it is always configured to be located in a fixed position.

In the sealed space 12, the rotating shaft 33 is rotatably supported by a pair of supporting brackets 125, and an operation link 34 is provided at a position between the supporting brackets of the rotating shaft 33 positioned in the sealed space. The end of the piston rod 104 'of the actuating cylinder 103' is rotatably fixed to the opposite end of the rotating shaft fixing portion of the actuating link 34, and the rear end of the actuating cylinder 103 'is fixed to the housing 20. It is fixed to the inner wall to be rotatable.

Further, guide brackets 125a are formed in the support bracket 125 in the same shape as the guide grooves 22 'formed in the housing 20, and the front and rear forward cylinders 123 are located at positions between the support brackets of the rotation shaft 22. The front end of the piston rod 124 is rotatably fixed, and the rear end of the forward and backward cylinder 123 is rotatably fixed to the inner wall surface of the housing 20.

In this configuration, when the operation cylinder 103 'is driven in response to the command of the integrated control system 100, the water gate 30 is rotated to the closed position. When the piston rod 124 of the cylinder 123 pushes the rotation shaft 33 to push the sluice plate 31 in the water storage side direction, and the sluice plate 31 is pushed in the water storage side direction to the housing 20. The packing member 115 attached to the supporting protrusion 111 'and the lower surface of the sluice plate 31 of the sluice 30 are strongly adhered to each other so that the gap between the sluice 30 and the housing 20 is perfectly. It can be packed.

In this case, the rotation shaft 30 of the water gate 30 may move along each guide groove 22 'and 125a formed in the housing 20 and the support bracket 125, and the guide groove of the housing 20 22 ') is covered by the packing plate 23' so that water can be prevented from leaking through the guide groove 22 'of the housing 20.

When the operation cylinder 103 'and the forward and backward cylinder 123 are simultaneously contracted in the closed state of the water gate 30, the water gate plate 31, the both side plates 32, and the rotating shaft 33 forming the water gate 30 are As it is rotated to the closed position, it is reversed to the drainage side, and the packing position between the water gate 30 and the housing 20 is released and at the same time, a space is generated between the portion rounded downward of the housing 20 and the water gate 30. As the subsurface water of the reservoir is discharged through these spaces, foreign substances such as sedimentary sludge deposited on the bottom of the river are released like the stream water, which causes natural acceleration, mass cutting, material desorption and material injury. As a result, polluted water is naturally purified.

On the other hand, when the inflow water suddenly increases and the water level increases, such as flooding, the water gate 30 must be completely opened. For this purpose, the front and rear cylinders 123 are extended to close the rotation shaft 33 of the water gate 3 originally. After returning to the position, the actuating cylinder 103 'is contracted and rotated so that the sluice plate 31 of the sluice 30 comes into close contact with the rounded portion of the housing 20 in the downward direction. The water in the reservoir space can be discharged to the upper portion of the sluice plate 31 in a fast time to stabilize the water level, and since the bottom surface of the sluice plate 31 and the housing 20 is horizontal, the branches having large particles Foreign substances such as can be discharged as it is without being caught between the bottom surface of the sluice plate 31 and the housing 20 to prevent the failure of the sluice (30).

In addition, the support protrusion 111 ′ applied to the fifteenth embodiment of the present invention may be integrally manufactured at the time of manufacturing the housing 20, or the support protrusion 111 ′ may be separately manufactured to be welded to the housing 20. As can be attached, even if the material or manufacturing method of the support protrusion 111 'is changed, it is natural that it belongs to the scope of the present invention.

In addition, the packing member 115 to be applied to the fifteenth embodiment of the present invention can be made of any material such as rubber, synthetic rubber, flexible synthetic resin as long as it can exhibit the packing capacity, in the fifteenth embodiment of the present invention Although the shape of the packing member 115 is illustrated as an example in which an air layer is formed on the packing part, the material or shape of the packing member 115 is changed since the packing part 115 can exhibit the same packing ability even by applying a wing to the packing part. Even if it belongs to the scope of the present invention is natural.

In addition, in the fifteenth embodiment of the present invention, the operation cylinder 103 'and the front and rear cylinders 123 are described as an example in which the inner wall drainage side of the housing 20 is installed as an example. Since the true cylinder 123 is installed on the inner wall storage side of the housing 20, and the operation is reversed to the above, the rotary cylinder and the forward and backward operation of the water gate 30 can be performed in the same manner, so that the operation cylinder 103 ') And the installation position of the forward and backward cylinder 123 can be changed as much, and therefore, even if the installation position of the operation cylinder 103' and the forward and backward cylinder 123 is changed, it is obvious that it belongs to the scope of the present invention. .

[Example 16]

54 is a side sectional view at the start of the rotational door according to the sixteenth embodiment of the present invention, and FIG. 55 is a side cross-sectional view when the rotational door is closed in accordance with the sixteenth embodiment of the present invention.

As shown, the rotating door according to the sixteenth embodiment of the present invention modified the seventh embodiment of the present invention door frame 127 in close contact with the lower surface of the sluice plate 31 of the sluice 30 to the housing 20 ), And to contact the lower surface of the sluice plate 31 of the sluice 30, the rotating sluice to which the sixteenth embodiment of the present invention is applied is supported by both sides combined with a comprehensive control system (not shown) A water channel 11 is formed between the structures 10, and the housings 20 are respectively covered on opposite surfaces of the support structures 10, so that the enclosed space 12 is disposed between the housings 20 and the support structures 10. The water gate 30 is formed by the rotational shaft 33 drawn outward from both side plates 32 and both side plates 32 formed at right angles to both end portions of the arc-shaped gate plate 31 and the gate plate 31. This configuration, the rotation shaft 33 of the water gate 30 is inserted into the shaft hole 21 formed in each housing 20.

The drainage side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates 32 of the rotating shaft 33 It is formed symmetrically with respect to the center, both lower surfaces of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing (20).

In addition, a pair of operation links 34 are fixed to the rotation shaft 33 at a closed space position of the rotation shaft 33, and a piston rod of the operation cylinder 103 ′ between opposite sides of the rotation shaft fixing portion of the operation link 34. 104 ') The tip is rotatably connected.

At this time, the operation cylinder 103 'is located in the same direction as the waterway opening and closing position of the water gate 30, the operation link 34 is fixed to the rotating shaft 33 in the operation cylinder 103' installation direction, the operation cylinder ( 103 ') and the actuating link 34 may be installed at any position such that the lower side angle therebetween is less than 180 ° based on the full opening of the water gate 30.

In such a rotating door, the door frame 127 is formed on both side walls of the housing 20 with the same curvature as that of the lower surface of the sluice plate 31 of the sluice 30, and the rotating shaft 33 of the sluice 30 is formed. Drainage side bottom portion of the support bracket 125 to support the support wood 125 is supported so that the support bracket 125 is inclined at an angle to the water storage side, the rotation shaft 33 of the water gate 30 is the support bracket 125 According to the position of the door frame 127 is configured to be positioned above the reservoir side rather than the center of rotation.

When the operation cylinder 103 'is extended by the command of the integrated control system in this configuration and the operation link 34, the rotation shaft 33, both side plates 32, and the sluice plate 31 are rotated, the sluice 30 is Since the center of rotation is located above the water storage side than the center of rotation of the door frame 127, there is a little play between the gate plate 31 and the door frame 127 of the water gate 30 at the beginning of the rotation of the water gate 30 If the freeway or the sluice 30 continues to rotate in the closing direction, the sluice plate 31 of the sluice 30 and the door frame 127 are in contact with each other and the sluice plate of the sluice 30 at the time when the sluice 30 is closed. The 31 and the door frame 127 may be tightly adhered to each other, and thus, the water of the reservoir space may be prevented from leaking between the water gate 30 and the door frame 127, thereby enabling a perfect closure.

That is, in the rotating gate, the gate 30 and the door frame 127 is designed to have a certain amount of play in consideration of the rotation of the gate 30, but if designed in this way, the gate 30 and the door frame Since water in the reservoir space is leaked through the clearance between the 127 and 15, the center of the rotation center of the water gate 30 and the center of the door frame 127 are eccentric to the water frame 30 while the door frame ( By tightly contacting the 127, when the water gate 30 is closed, a gap may not be generated between the water gate 30 and the door frame 127 to prevent leakage.

Here, the position of the operation cylinder 103 'and the operation link 34 applied to the sixteenth embodiment of the present invention can be changed to any other position, and thus, even if the installation position of each of these members is changed It is natural that they fall within the scope of their rights.

In addition, the door frame 127 may be manufactured integrally at the time of manufacturing the housing 20, or may be attached to the housing 20 after being manufactured as a separate structure, and having stainless steel, nonferrous metal, and synthetic resin having water resistance. It can be made of any material, and therefore, it is natural that even if the manufacturing method, material, etc. of the door frame 127 is changed, it belongs to the scope of the present invention.

[Example 17]

56 is a perspective view of a sluice gate of a rotating gate according to a seventeenth exemplary embodiment of the present invention.

As shown, the seventeenth embodiment of the present invention relates to the shape of the sluice 30, the sluice plate 31 of the sluice 30 is composed of a flat plate, both sides fixed to both sides of the sluice plate 31 The plate 32 is formed in a triangular shape as a whole, the lower end of the rounded shape, but the rounded portion is configured to be located at least lower than the sluice plate 31, respectively from the upper one side of both side plates in the outward direction, respectively It has a rotating shaft.

"형상의 지지틀이나 지지돌출부를 구비하고, 지지틀 또는 지지돌출부의 배수측면에는 "

"형상의 패킹부재를 부착하여 구성하게 된다.In addition, although not shown in the drawings, according to the thirteenth to fifteenth embodiments of the present invention together with the gate 30 having the above-described structure,

"With a support frame or support protrusion in the shape, on the drain side of the support frame or support protrusion"

It is configured by attaching a "shaped packing member.

Applying the water gate 30 configured as described above can be produced using a general flat plate without processing the lower surface of the water gate plate 31 during the production of the water gate 30, accordingly, the production of the water gate 30 is very Easier, it is possible to reduce the manufacturing cost, the weight of the gate 30 is reduced, there is an advantage that can save the energy required to drive the gate (30).

"형상을 이루게 되므로 수문(30)의 폐쇄시 양측판(32)과 수문판(31)의 일측 단부가 패킹부재와 밀착될 수 있어 저수공간의 물이 누수되는 것을 방지할 수 있는 이점이 있는 것이다.In addition, one end of both side plate 32 and the hydrologic plate 31 is "

"Because it forms a shape, one side end of both side plates 32 and the sluice plate 31 may be in close contact with the packing member when the sluice 30 is closed, so that water in the reservoir space may be prevented from leaking. .

In addition, the sluice 30 according to the seventeenth exemplary embodiment of the present invention may be manufactured by separately manufacturing the sluice plate 31, the two side plates 32, and the rotation shaft 33, and then join the members to each other by welding. It can be made very easily.

[Example 18]

Fig. 57 is a side sectional view of a rotating water gate according to an eighteenth embodiment of the present invention.

As shown, the sluice door according to the eighteenth embodiment of the present invention is to prevent leakage due to a gap between the sluice 30 and the housing 20 when the sluice 30 rotates. All the rotating gates according to the first to twelfth embodiments are applicable, and in the drawings, the seventh embodiment of the present invention is applied as an example.

In the rotating gate to which the eighteenth embodiment of the present invention is applied, a channel 11 is formed between both support structures 10 coupled with a comprehensive control system (not shown), and the opposite surfaces of both support structures 10 Each of the housings 20 is covered so that a sealed space 12 is formed between the housing 20 and the support structure 10, and formed at right angles at both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the side plate 32 and the rotation shaft 33 drawn outward from both side plates 32, and the shaft hole 21 in which the rotation shaft 33 of the water gate 30 is formed in each housing 20. The drainage side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 is formed of the sluice plate 31 and both side plates ( 32 is formed symmetrically about the rotation shaft 33, and both lower surfaces of the sluice plate 31 are rounded downward of the housing 20. Rounded to the same curvature so as to be in close contact with the surface.

"형상의 지지돌출부(111')를 위치시키고, 지지돌출부(111')의 배수측면에는 "

"형상의 패킹부재(115)를 부착하되, 지지돌출부(111')와 패킹부재(115)의 양측부는 수문(30)의 수문판(31) 곡률과 동일한 곡률로 형성하고, 밀폐공간(12) 내에서 회전축(33)은 쌍으로 된 지지브라켓(125)에 의해 회전가능하게 지지되도록 하고, 밀폐공간(12)에 위치된 회전축(33)의 지지브라켓 사이 위치에는 작동링크(34)를 고정하며, 작동링크(34)의 회전축 고정부위 반대측 단부에는 작동실린더(103')의 피스톤로드(104') 선단부를 회전가능하게 고정하고, 작동실린더(103')의 후단부는 하우징(20)의 내벽면에 회전가능하도록 고정하게 된다.In this rotational door, the front door is located at a position close to the rim of the sluice plate of the housing 20 with respect to the state in which the sluice door 30 is completely closed.

&Quot; Position the support protrusion 111 'in the shape, and on the drain side of the support protrusion 111 "

Attached to the "shaped packing member 115, the support protrusion 111 'and both sides of the packing member 115 is formed with the same curvature as the curvature of the hydrological plate 31 of the water gate 30, the closed space 12 The rotating shaft 33 is rotatably supported by a pair of support brackets 125, and the operating link 34 is fixed to a position between the support brackets of the rotating shaft 33 located in the sealed space 12. The end of the piston rod 104 'of the actuating cylinder 103' is rotatably fixed to an end opposite to the rotating shaft fixing part of the actuating link 34, and the rear end of the actuating cylinder 103 'is formed on the inner wall surface of the housing 20. It is fixed to the rotatable.

At this time, the outer end of the packing member 115 is the edge of both sides of the water gate 30 on the basis of the closing of the water gate 30 so as to contact the both side edges and the lower edge of the water gate 30 when the water gate 30 is rotated. And it is located in the position 5 ~ 10mm advanced to the drainage side rather than the lower edge portion, the pointed boundary between the lower end and the upper side of the two side plate 32, the packing member 115 during the rotation of the water gate 30 is this pointed portion The guides 128 are formed to sweep the parts interfering with the lower end of the water gate 30 so as not to be directly torn and torn.

"형상의 틈새를 완벽하게 패킹해줄 수 있어 저수공간의 물이 누수되는 것을 방지할 수 있는 것이다.In this configuration, when operating the operation cylinder 103 'in accordance with the command of the integrated control system 100 to rotate the water gate 30 to the closed position between the lower end and the upper portion of the side plate 32 of the water gate 30 The guide 128 provided at the pointed boundary portion is rotated while sweeping the packing member 115, and thus the packing member 115 exerts elasticity while its advanced portion is pressed, and the packing member 115 is Since both sides of the sluice 30 are in contact with the side plate 32, the elasticity of the packing member 115 allows the side plate 32 and the housing 20 to be completely packed, and the sluice 30 is in the closed position. When fully rotated until the bottom edge of the sluice plate 31 and the packing member 115 is in close contact with the "between the sluice 30 and the housing 20"

"The gaps in the shape can be completely packed to prevent leakage of water in the reservoir.

In this case, the support protrusion 111 ′ applied to the eighteenth embodiment of the present invention may be integrally manufactured during the manufacture of the housing 20, or the support protrusion 111 ′ may be separately manufactured to be welded to the housing 20. As can be attached, even if the material or manufacturing method of the support protrusion 111 'is changed, it is natural that it belongs to the scope of the present invention.

In addition, the packing member 115 applied to the eighteenth embodiment of the present invention can be made of any material, such as rubber, synthetic rubber, flexible synthetic resin, if the packing ability can be exhibited, the eighteenth embodiment of the present invention The packing member 115 to be applied may be formed by forming an air layer on the packing part or by adding a wing to the packing part, and may be configured in various shapes, even if the material or shape of the packing member 115 is changed. Naturally, it belongs to the scope of the present invention.

In addition, in the eighteenth embodiment of the present invention, the operation cylinder 103 'is installed on the inner wall drain side of the housing 20 as an example, but the operation cylinder 103' is installed on the inner wall bottom of the housing 20. It is possible to change the installation position of the actuating cylinder 103 'as it can be installed on the water side, and even if the operation is reversed to that described above, the actuating cylinder 103' can be changed. Even if you change the installation position of the) is naturally within the scope of the present invention.

[Example 19]

FIG. 58 is a sectional front view of a rotatable gate according to a nineteenth embodiment of the present invention, FIG. 59 is a side sectional view of the rotary gate according to a nineteenth embodiment of the present invention when activated in an open state, and FIG. 19 is a side cross-sectional view when closing the rotating gate according to the nineteenth embodiment, and FIG. 61 is a side cross-sectional view when a foreign substance is caught in the rotating gate according to the nineteenth exemplary embodiment of the present invention.

As shown, the nineteenth embodiment of the present invention is to manufacture a water gate according to the first to twelfth embodiments of the present invention, the rotation shaft 33 of the water gate 30 is the upper side of the two side plates (32) In the direction of closing the water gate 30 by fixing the push rod 33b at the space portion of the rotating shaft 33, respectively, and rotatably fixed to the inner side of the side plate 32. Rotating the water gate plate 31 and the both side plate 32 from the point that the push rod 33b is in close contact with the one side wall of the space 32a, and when the push rod 33b rotates in the opposite direction, 31) and both side plates 32 are to be opened by its own weight.

In this configuration, when operating the operation cylinder (not shown) for operating the water gate 30 in accordance with the command of the integrated control system (not shown) to rotate the water gate 30 to the closed position, both the sluice plate 31 and both sides The plate 32 rotates only the rotary shaft 33 while maintaining the original state, and the push rod 33b is rotated together with the rotation of the rotary shaft 33, and the push rod 33b is connected to one wall of the space part 32a. From the point of contact, both side plate 32 and the sluice plate 31 is rotated to close the waterway.

Of course, when the water gate 30 is rotated a little more in the closed position, a space is generated between the bottom of the housing 20 and the water gate 30, and the lower water of the reservoir space is discharged through the space to the bottom of the river. Foreign matters such as sedimentation sludge that have been deposited are discharged like river water, and natural acceleration, mass cutting, material desorption, and material flotation occur naturally.

When the water gate 30 is opened in the closed position, the rotary shaft 33 is rotated in the opposite direction to the above to rotate the push rod 33b supporting the space 32a of the two side plates 32, As 33b) is rotated in a direction opposite to that of closing, the force supporting the two side plates 32 is released so that both the side plates 32 and the sluice plate 31 are returned to their original positions by their own weight so that the water gate 30 It is possible to open, so that the water in the reservoir can be discharged at high speed.

By the way, since a large foreign matter is floated with water into the storage space, such foreign matter may be caught between the water gate 30 and the housing 20 when the water gate 30 is opened, and in the case of a general water gate, between the water gate and the housing When the foreign material is caught in the water gate is stopped, while the operation means for operating it is driven continuously, so the operation means is overdriven, there was a problem that the failure or damage of the operation means occurs, in the eighteenth embodiment of the present invention Since both side plates 30 and the rotation shaft of the 30 are rotatably connected to each other, foreign matter is caught between the water gate 30 and the housing 20, and thus the operation means is stopped while the water gate 30 does not return to the open position. Even if the drive continues, since only the rotation shaft 33 is rotated separately from both side plates 32 and the sluice plate 31 of the sluice 30, the operation means can be smoothly protected, and the sluice 30 is later Removing the foreign matter between the sluice 30 and the housing 20 rotate in a direction that chain will be fixed state.

In addition, the push rod 33b applied to the nineteenth embodiment of the present invention may be configured by pressing or welding the rotary shaft 33, and the rotary shaft 33 is rotated in a state where the rotary shaft 33 is fitted to both side plates 32. It is possible to combine through a member such as a coupling so as not to fall back, and in addition to the specific configuration of each of the above-described members can be sufficiently changed design, even if the design of the coupling structure of each of the above-described member of the scope of the present invention It is natural to belong.

[Example 20]

62 is a perspective view taken from a packing member installation portion of a rotating hydrologic gate according to a twentieth embodiment of the present invention, and FIG. 63 is a side cross-sectional view of a closed state of the rotating hydrostatic gate according to a twentieth embodiment of the present invention.

As shown, the sluice door according to the twentieth embodiment of the present invention is modified by the eighteenth embodiment of the present invention is leaked by a gap between the sluice 30 and the housing 20 during rotation of the sluice 30 In order to prevent this, all the rotating gates according to the first to ninth embodiments of the present invention can be applied, it is shown in the drawings by applying the seventh embodiment of the present invention as an example.

In the rotating gate to which the twentieth embodiment of the present invention is applied, a channel 11 is formed between both supporting structures 10 coupled to a comprehensive control system (not shown), and the opposite surfaces of both supporting structures 10 Each of the housings 20 is covered so that a sealed space 12 is formed between the housing 20 and the support structure 10, and formed at right angles at both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the side plate 32 and the rotating shaft 33 drawn out from both side plates 32, and the rotating shaft 33 of the water gate 30 is formed in the shaft hole 21 formed in each housing 20. The drainage side of the bottom of the housing 20 is formed to be rounded downward so as to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 is the sluice plate 31 and both side plates 32. ) Is formed symmetrically about the rotation axis 33, and both lower surfaces of the sluice plate 31 is rounded downward of the housing 20 Rounded to the same curvature so as to be in close contact with the surface.

"형상의 지지돌출부(111')를 위치 시키고, 지지돌출부(111')의 양측부 배수측면에는 일측이 불룩한 형상의 패킹부재(115)를 부착하고, 지지돌출부(111')의 하변부 배수측면에는 중앙부가 불룩한 대칭형상의 패킹부재(115')를 부착하며, 밀폐공간(12) 내에서 회전축(33)은 쌍으로 된 지지브라켓(125)에 의해 회전가능하게 지지되도록 하고, 밀폐공간(12)에 위치된 회전축(33)의 지지브라켓 사이 위치에는 작동링크(34)를 고정하며, 작동링크(34)의 회전축 고정부위 반대측 단부에는 작동실린더(103')의 피스톤로드(104') 선단부를 회전가능하게 고정하고, 작동실린더(103')의 후단부는 하우징(20)의 내벽면에 회전가능하도록 고정하게 된다.In this rotational door, the front door is located at a position close to the rim of the sluice plate of the housing 20 with respect to the state in which the sluice door 30 is completely closed.

"The shape of the support protrusion 111 'is positioned, and the packing member 115 of which one side is bulging is attached to the both sides drain side surfaces of the support protrusion 111', and the bottom side drain side of the support protrusion 111 'is attached. A centrally bulging symmetrical packing member 115 'is attached, and the rotating shaft 33 is rotatably supported by the pair of support brackets 125 in the sealed space 12, and the sealed space 12 The actuating link 34 is fixed to a position between the support brackets of the rotating shaft 33 positioned at the rotating shaft, and the end of the piston rod 104 'of the actuating cylinder 103' is rotated at an end opposite to the rotating shaft fixing portion of the actuating link 34. It is possible to fix, and the rear end of the operation cylinder (103 ') is rotatably fixed to the inner wall surface of the housing (20).

At this time, it is apparent that both sides of the support protrusion 111 'and the packing member 115 attached thereto are formed to have the same curvature as the curvature of the sluice plate 31 of the sluice 30 so as not to interfere with the rotation of the sluice. .

In addition, the outer end of each of the packing members 115 and 115 ′ may be in contact with both side edges and the bottom edge of the water gate 30 when the water gate 30 rotates. Rather than the position of both sides of the edge and the bottom edge of the edge) to be located in the position 5 ~ 10mm advanced to the drainage side, the pointed boundary between the lower end and the upper side of the side plate 32, the packing member 115 during rotation of the water gate (30) The guides 128 are formed to sweep each of the parts interfering with the lower end of the water gate (30) so that they do not come into direct contact with the pointed area.

"형상의 틈새를 완벽하게 패킹해줄 수 있어 저수공간의 물이 누수되는 것을 방지할 수 있는 것이다.In this configuration, when operating the operation cylinder 103 'in accordance with the command of the integrated control system 100 to rotate the water gate 30 to the closed position between the lower end and the upper portion of the two sides 32 of the water gate 30 The guide 128 provided at the pointed boundary portion is rotated while pushing the packing member 115 attached to both sides of the support protrusion 111 ', and the bottom surface of the water guard plate 31 is lower than the support protrusion 111'. Rotating while sweeping the packing member (115 ') attached to each, and thus, each packing member (115, 115') is exerted elastically while the portion is advanced, and each of the packing member (115) ( 115 ') is in constant contact with the lower surface of both side plate 32 and the sluice plate 31 of the sluice 30, and when the sluice 30 is completely rotated to the closed position, both side plate 31 and the sluice The lower edge of the plate 31 and each of the packing members 115 and 115 ′ are in close contact with each other to form a gap between the water gate 30 and the housing 20. "

"The gaps in the shape can be completely packed to prevent leakage of water in the reservoir.

When the water gate 30 is rotated in the open direction in the closed state of the water gate 30, the packing member 115 ′ in close contact with the lower surface of the water gate plate 31 is swept in the opposite direction as when the water gate 30 is closed. Since the packing member 115 'has a bulging symmetrical shape at the center, the packing member 115' can smoothly cope with the stress even when the direction of rotation changes depending on the rotational direction of the sluice plate 31 so that the packing performance can always be exhibited at the correct position. do.

In addition, the packing member 115 which is in contact with the lower surface of the both side plate 32 is made of a bulging shape on one side, but the installation direction is the same as the direction of the both side plate 32, regardless of which direction the water gate 30 is rotated Its shape and performance can be maintained without.

Each of the packing members 115 and 115 'may be attached to the support protrusion 111' by various methods such as a bolt tightening method or an adhesive method or an adhesive method by heat fusion. Even if the attachment method of the 115 'is changed, it is natural that it belongs to the scope of the invention.

In this case, the support protrusion 111 ′ applied to the twentieth embodiment of the present invention may be manufactured integrally when the housing 20 is manufactured, as in the eighteenth embodiment, or the support protrusion 111 ′ may be manufactured separately and the housing ( 20) can be attached by welding or the like, even if the material or manufacturing method of the support protrusion 111 'is changed is naturally within the scope of the present invention.

In addition, each packing member 115, 115 'applied to the twentieth embodiment of the present invention can be made of any material, such as rubber, synthetic rubber, flexible synthetic resin, if the packing ability can be exhibited, Each of the packing members 115 and 115 'applied to the twentieth embodiment may be formed by forming an air layer on the packing part or by adding a wing to the packing part, or in addition to the packing member. Even if the material or shape of the 115) 115 'is changed, it is natural to fall within the scope of the present invention.

[Example 21]

64 is a side cross-sectional view of a rotation shaft connecting portion of the rotating gate according to the twenty-first embodiment of the present invention.

As shown, the twenty-first embodiment of the present invention relates to a structure for rotatably supporting the rotating shaft 33 of the water gate 30 in the sealed space 12, the water gate 30 in the sealed space 12 The rotating shaft 33 of the stainless steel or copper protection plate (33c) is wound at least two to three times, as it is to be rotatably fitted to the support bracket 125 without a separate bearing in this state.

In this configuration, since the rotation shaft 33 and the support bracket 125 of the water gate 30 made of steel are not in direct contact with each other, the protection plate 33c is positioned in the middle thereof, so that the water gate 30 is rotated when the rotation shaft 33 is rotated. Even if the centrifugal force due to its own weight or rotation is applied, it is possible to prevent wear of the rotation shaft 33 and the support bracket 125 of the water gate 30, as well as to enable smooth rotation without a separate bearing.

At this time, the protective plate 33c applied to the twenty-first embodiment of the present invention may be made of various materials such as synthetic resin, in addition to stainless steel or copper, and the number of times the protective plate 33c is wound on the rotating shaft 33. It is also apparent that the material may vary depending on the material of the protection plate 33c, the water pressure, the weight of the water gate 30, and the rotational speed of the water gate 30, and thus the present invention may be changed even if the material or the number of windings of the protection plate 33c is different. It is natural that they fall within the scope of their rights.

[Example 22]

65 is a state diagram when the rotary door is closed according to the twenty-second embodiment of the present invention.

"형상의 지지돌출부(111')를 위치시키고, 지지돌출부(111')의 양측부 배수측면에는 일측이 불룩한 형상의 패킹부재(115)를 부착하고, 지지돌출부(111')의 하변부 배수측면에는 중앙부가 불룩한 대칭형상의 패킹부재(115')를 부착한 상태에서 수문판(31)의 하면에 사이펀판(129)을 고정하여 수문판(31)과 사이펀판(129)의 사이에 사이펀통로(130)를 구성한 것이다.As shown, the twenty-second embodiment of the present invention manufactures a rotating gate as in the first to twelfth embodiments, and as shown in the twentieth embodiment, the housing is based on a completely closed state of the gate 30. 20, close to the sluice plate border in the front "

"The shape of the support protrusion 111 'is located, and the packing member 115 of which one side is bulging is attached to the both sides drain side of the support protrusion 111', and the lower side drain side of the support protrusion 111 '. The siphon plate 129 is fixed to the lower surface of the sluice plate 31 in a state in which a symmetrical packing member 115 ′ having a central portion is attached thereto, and a siphon passage between the sluice plate 31 and the siphon plate 129. 130).

At this time, the lower end portion of the siphon plate 129 is fixed at a position higher than the lower end portion of the sluice plate 31 on the basis of the closing of the water gate 30 so as not to interfere with the packing member 115 ', the siphon plate It is apparent that the upper end of the 129 is located at a higher position than the sluice plate 31 so that water can be discharged through it.

In addition, the siphon passage 130 is configured to prevent the filtration member 131 such as a non-woven fabric to prevent the large sand or gravel from entering the siphon passage 130.

When the water gate 30 is closed by rotating in the state configured as described above, as shown in the nineteenth embodiment of the present invention, both side plates 32 of the water gate 30 are packing members attached to both sides of the support protrusion 111 '. 115 is in close contact, and the lower edge of the sluice plate 31 of the sluice 30 is in close contact with the packing member 115 ′ attached to the lower side of the support protrusion 111 ′, so that the sluice 30 and the housing 20 are closed. It completely packs the space between them, and the water fills up the reservoir.

When the low water level in the reservoir space is over the upper end of the watermark plate 31 in the state that the water gate 30 is closed, the siphon passage between the water gate plate 31 and the siphon plate 129 according to the principle of siphon ( 130 is introduced through the top of the sluice plate (31) while being discharged through the pollutants such as sedimentation sludge located in the lower layer of the stream is to maintain a stable water level and to purify the contaminated water quality.

However, since the sand or gravel having large particles are shrouded in the lower portion of the stream, when the sand or gravel flows into the siphon passage 130 together with water when the lower layer water is discharged, the siphon passage 130 may be easily blocked. As such, when the siphon passage 130 is blocked, the lower layer water of the storage space may not be discharged unless the water gate 30 is driven while the water gate 30 is closed.

Accordingly, in the present invention, the siphon passage 130 is provided with a filtering member 131 such as a nonwoven fabric. The filtering member 131 can pass foreign substances of water and fine size, but has large particles such as sand or gravel. Foreign material can be filtered to prevent the siphon passage 131 is blocked.

That is, according to the twenty-second embodiment of the present invention, the water level can be stably maintained by discharging water in the reservoir space through the siphon passage even in the state in which the water gate 30 is closed, and of course, the contaminated water is discharged in the reservoir space. It can purify the water quality.

In addition, the shape of the sluice or sluice elements exemplified in the first to twenty-second embodiments of the present invention can be changed as much as possible, and therefore the first embodiment of the invention even if the shape of the sluice or sluice elements is changed. It is a matter of course that all of the operation and efficacy effects equivalent to those of the twenty-second embodiment belong to the scope of the present invention.

In addition, by forming a space between the water gate and the housing by rotating the water gate about the rotation axis of the water gate can be implemented in a variety of ways to discharge the lower layer water in the reservoir space, for example by rotating the water gate by a hydraulic cylinder Or, it is possible to discharge the bottom water of the reservoir by rotating the water gate through the hydraulic rotary actuator, and thus techniques for discharging the bottom water of the reservoir by rotating the water gate through another power means not illustrated in the present invention Naturally, all belong to the scope of the present invention.

[Example 23]

FIG. 66 is a side view of a support structure according to a twenty-third embodiment of the present invention, and FIG. 67 is a hydraulic circuit diagram of a rotating gate according to the twenty-third embodiment of the present invention.

The twenty-third embodiment of the present invention relates to a hydraulic piping system for automatically opening the gate 30 when the floodgate is closed and the floodgate 30 is closed. , Oil containing the oil discharged from the closing pipe 141 and the opening pipe 142 and the closing pipe 141 or the opening pipe 142 respectively connected to the operation cylinder 103 for rotating the water gate (30) The oil pump 144 for supplying the tank 143 and the oil collected in the oil tank 143 to the closed pipe 141 or the open pipe 142 and the oil pumped through the oil pump 144 may be supplied. The control valve 145 for selecting the pipes 141 and 142, and the check valves 146 and 147 installed in the closed pipe 141 and the open pipe 142, respectively, to prevent backflow, are configured. In the twenty-third embodiment of the present invention, the bypass pipe 148 is provided at the front and rear ends of the check valve 146 of the closed pipe 141. Therefore, the emergency valve 149 is interposed between these bypass pipes 148, so that the emergency valve 149 is positioned just below the upper end of the supporting structure 10, and the emergency valve 149 can be operated. It is to install a hydraulic plate 150 on the upper end of the support structure (10).

At this time, the hydraulic plate 150 is installed so as to be inclined slightly to the drain side of the support structure 10 is configured to be inclined to rotate to the drain side by the water pressure when the water is overflowed and the hydraulic pressure acts on the drain side, It is preferable to fix the guard net 151 around the 150 so that water can pass through and protect it from external impact or artificial manipulation.

In addition, the upper end of the support structure 10 is preferably positioned to be lower than the height of the surrounding embankment to be configured to overflow from the support structure 10 when the water begins to overflow.

In the state configured as described above, the emergency valve 149 normally waits in a disconnected state so as not to communicate with each other, and the oil pump 144 and the control valve 145 are operated by an unillustrated hydraulic control system to open the piping 142. When oil is supplied to one of the pipes 141 and the closed pipe 141, the oil is discharged from the remaining pipes so that the operation cylinder 103 can be expanded and contracted, and the water gate 30 rotates according to the expansion and contraction of the operation cylinder 103. Thus, the channel 11 is opened and closed.

By the way, when the power outage is not supplied to the hydraulic control system, the oil pump 144 and the control valve 145 does not work, the oil is filled in the closed pipe 141 and the open pipe 142 is stagnant, If this state is a state in which the water gate 30 is closed and the water level is gradually increasing, the water in the reservoir space overflows to the dike, which inevitably causes great damage.

In the twenty-third embodiment of the present invention, when water in the storage space overflows the support structure 10 in an emergency as described above, the hydraulic pressure is applied to the hydraulic plate 150 to rotate the hydraulic plate 150 toward the drainage side. As the hydraulic plate 150 rotates, the emergency valve 149 is operated to connect the bypass pipes 148 to each other, and the oil filled in the closed pipe 141 is stagnant in the bypass pipe. The operation cylinder 103 is discharged to the oil tank 143 through the free state 148, and the closing position in the rotating water gate according to the present invention is always operated because the self-weight acts in the direction in which the water gate 30 is opened. When the 103 is in a free state, the water gate 30 is rotated in the opening direction by its own weight so that the water channel 11 can be opened. Thus, when the water channel 11 is opened, the water in the reservoir space has a high speed. To keep the water level stable And it can, thus be capable of restricting the water from overflowing the banks of the water storage space.

Of course, even if a power failure occurs and the water gate 30 is in a closed state, a dangerous situation is not caused unless the water level is rapidly increased. In this case, the cause of the power failure is found and recovered while maintaining the state of the water gate 30 as it is. Will be.

As described above, in the twenty-third embodiment of the present invention, when water in the storage space overflows the support structure 10 without an artificial manipulation in a worst case state such as a flood, a power failure, or a closed state of the sluice 30, the water pressure automatically By allowing the water gate 30 to be opened, it is possible to prevent the water in the reservoir from overflowing into the dike, thereby protecting valuable lives and property.

And, since the hydraulic circuit applied to the twenty-third embodiment of the present invention can be applied to any hydraulic circuit can be performed the same function, it is configured by different members such as the control valve 145 for controlling the hydraulic piping, or Even if the configuration of the hydraulic piping line slightly different, it is a matter of course within the scope of the present invention.

In addition, a single-acting cylinder is used as the operation cylinder 103 applied to the twenty-third embodiment of the present invention, and the hydraulic pipe may also be provided with only the closed pipe 141, which is also within the scope of the present invention. It is natural.

Meanwhile, in the first to twenty-third embodiments of the present invention, the sluice gate 30 is composed of the sluice plate 31, both side plates 32, and the rotation shaft 33 to rotate the rotation shaft 33 so that the water gate ( 30) It is to clean the contaminated river water by opening and closing the waterway 11 while rotating the whole, but the sluice consists of the sluice plate and both side plates, and the shaft portion that forms the center of rotation is fixed to the supporting structure to center the fixed shaft portion. As the water gate may be rotated, this embodiment will be described below.

[Example 24]

FIG. 68 is a perspective view of a rotating gate according to a twenty-fourth exemplary embodiment of the present invention, FIG. 69 is a sectional front view of a rotating gate according to a twenty-fourth exemplary embodiment of the present invention, and FIG. 70 is a rotating diagram according to a twenty-fourth exemplary embodiment of the present invention. Fig. 71 is a side cross-sectional view at the time of closing the rotating gate according to the twenty-fourth embodiment of the present invention, and Fig. 72 is a side cross-sectional view at the bottom discharge of the rotating gate according to the twenty-fourth exemplary embodiment of the present invention. .

As shown, the rotating gate according to the twenty-fourth embodiment of the present invention, the water channel 211 is formed between the two support structures 210, the housing 220 on the opposite surface of the both support structures 210 Covered respectively, the fixed shaft 233 is fixed to the inner side of the support structure 210 through the housing 220, respectively, both sides of the arc-shaped sluice plate 231, both sides of the plate 232 is fixed to the water gate 230 is provided so that both side plates 232 are rotatably fixed to the fixed shaft 233, respectively.

In addition, a space portion 232a is formed inside the two side plates 232, and a rear end portion of the operation cylinder 240 is fixed to one wall surface of the space portion 232a, and is located at a space portion of the fixed shaft 233. The actuating link 234 is fixed, and the tip of the piston rod 241 of the actuating cylinder 240 is rotatably fixed to the actuating link 234.

When the working cylinder 240 is contracted in this configuration, the fixed shaft 233 and the operating link 234 are fixed, so that the rear end portions of the working cylinder 240 are rotatably fixed between the side plates 232 and between them. When the sluice plate 231 starts to rotate, and when the rotation angle reaches 90 °, the sluice plate 231 is erected in a vertical direction to form a closed state so that water is filled in the reservoir.

When the water gate 230 is further rotated in a state where water is stored in the reservoir, a space is generated between the gate 230 and the housing 220, and the lower layer water of the reservoir 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 low water level rapidly increases, such as flooding, the operation cylinder 240 is extended as much as possible, and the water gate 230 is rotated according to the extension of the operation cylinder 240 such that the water gate plate 231 is the housing 220. The water gate 230 is in a state of being completely opened by being in close contact with the rounded portion of the bottom, and when the water gate 230 is opened, the top surface of the water gate plate 231 and the bottom surface of the housing 220 are in a horizontal state. Since the rounded side surface of the sluice plate 231 is in close contact with the rounded portion of the bottom of the housing 220, the water in the reservoir space can be smoothly discharged to the top of the sluice plate 231 of the sluice gate 230. When the water is discharged, foreign matters are not caught between the housing 220 and the water gate 230.

That is, according to the twenty-fourth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the supporting cylinder 240 for rotating the gate 230 is housed inside both side plates of the gate 230 so that the supporting structure is supported. If the separate storage space is not formed on the 210, workability can be improved, and the water gate 230 can be constructed with a relatively large size 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.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that the water in the storage space is provided on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

[Example 25]

73 is a perspective view of a rotating gate according to a twenty-fifth embodiment of the present invention, FIG. 74 is a front sectional view of a rotating gate according to a twenty fifth embodiment of the present invention, and FIG. 75 is a fixed view according to a twenty-fifth embodiment of the present invention. A cross section of the shaft.

As shown, the twenty-fifth embodiment of the present invention relates to a hydraulic piping system when the operation cylinder 240 is located inside the two side plates 232 of the water gate 230, and the two side plates of the water gate 230 At the rim of the fixed shaft 233 rotatably fixed to the 232, the hydraulic pipes 243 are respectively accommodated so as to pass through the space portion 232a of the two side plates 232, and each of the hydraulic pipes 243 are both side plates ( It is to be withdrawn from each of the operation cylinder installation position adjacent to the location of the space portion 232a of the 232 and to connect with the operation cylinder 240, respectively.

In this case, a plurality of hydraulic pipe receiving grooves 233a may be formed at the edge of the fixed shaft 233 to accommodate the hydraulic pipes 243 therein, and the inner diameter of the fixed shaft 233 may be accommodated. The protective tube 235 and the fixed shaft (235) larger than the diameter of the fixed shaft 233 are inserted, and the hydraulic pipes 243 are installed between the fixed shaft 233 and the protective tube 235. The filling material 236 may be filled in the space between the 233, and any structure may be applied as long as it can accommodate each of the hydraulic pipes 243 at the edge of the fixed shaft 233.

When the water gate 230 is closed in the state configured as described above, the water is filled into the reservoir space, and when the water level is above a certain level, the water gate 230 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 240 accommodated in the space portion 232a of the side plate 232 of the water gate 230, the operation cylinder 240 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 operation cylinder 240 is required.

The present invention accommodates the hydraulic pipe (243) at the edge of the fixed shaft 233 so as to communicate with the space portion of the side plate 232 for this purpose, and close to the cylinder connection position of the space portion (232a) of the side plate (232) By drawing through and connected to the operation cylinder 240, in this way the hydraulic pipes 243 to the outside of the sluice 230 is not cluttered, the appearance of the sluice 230 is very neat, the hydraulic pipe 243 Since the twisting phenomenon does not occur between the two does not affect the operation of the operation cylinder 240 can improve the reliability of the operation.

In addition, since most of the hydraulic pipe 243 is accommodated in the fixed portion 233 and the space portion 232a of both side plates 232 to be cut off from the outside, it is possible to minimize the probability that the hydraulic pipe 243 is damaged by external force. The foreign matter is not caught in the hydraulic pipe (243) is no fear of causing environmental pollution.

At this time, when forming a plurality of hydraulic pipe receiving grooves (233a) on the rim of the fixed shaft 233 to accommodate the hydraulic pipe 243 here, the hydraulic pipe 243 is very easy to receive instead of the hydraulic pipe (243) and When the hydraulic pipe receiving groove 233a is not tight, and the protective pipe 235 is covered on the outside of the fixed shaft 233, and the filling material 236 is filled while the hydraulic pipe 243 is accommodated therebetween. There is an advantage that the hydraulic pipe 243 does not flow, but the operation of accommodating the hydraulic pipe 243 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 240, since the hydraulic pipe 243 is made of the inlet pipe and the discharge pipe, it is obvious that the hydraulic pipe 243 is an even number, and therefore, the hydraulic pipe accommodation groove 233a on the fixed shaft 233. Of course, when forming the 2, 4, 6, 8 ... it is natural to form an even number.

In addition, the hydraulic pipe 243 according to the second embodiment of the present invention may be made of any material such as metal, synthetic resin, rubber, and the like, and the scope thereof is not limited. As described above, both sides of the water gate 230 may be 232. The number of hydraulic pipes 243 may also be increased or decreased to suit the number of operation cylinders 240 or hydraulic mechanisms accommodated in the space portion 232a of the hydraulic pipe 243.

[Example 26]

76 is a side sectional view of the revolving door according to the twenty-sixth embodiment of the present invention, FIG. 77 is a side sectional view of the revolving door according to a twenty-sixth embodiment of the present invention, and FIG. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the waterway 211 is formed between the two support structures 210, the rotating door according to the twenty-sixth embodiment of the present invention, the housing 220 on the opposite surface of the two support structures 210, respectively Covered through the housing 220, the fixed shaft 233 is fixed to the inside of the support structure 210, respectively, and both sides plate 232 is fixed to the both ends of the arc-shaped sluice plate 231 at a right angle ( 230 is provided so that both side plates 232 are rotatably fixed to the fixed shaft 233, respectively.

In addition, a first operation cylinder 244 is installed at the upper wall storage side of the housing 220, and a first support roller 251 is rotatably installed at a horizontal side of the first operation cylinder 244. The first chain 252 is connected to the reservoir side of both side plates 232 from the distal end of the piston rod 245 of the first operation cylinder 244 via the first support roller 251, and the middle part of the wall of the housing 220 is connected. The second operation cylinder 246 is installed on the drain side, the second support roller 253 is rotatably installed on the water storage side horizontal position of the second operation cylinder 246, and the piston rod of the second operation cylinder 246 The second chain 254 is connected to the drain side of both side plates 232 via the second support roller 253 from the tip portion.

In this case, in the third embodiment of the present invention, the first chain 252 and the second chain 254 are applied, but various connection members such as ropes and wires may be used in addition to the chains.

In this configuration, when the first operating cylinder 244 is contracted and the second operating cylinder 246 is elongated, the water gate 230 is rotated in a closing direction, and when the rotation angle reaches 90 °, the water plate 231 is erected in a vertical direction to form a closed state where water is filled in the reservoir.

When the first operating cylinder 244 is contracted as much as possible while the water is stored in the storage space and the second operating cylinder 246 is extended as much as possible, a space is generated between the water gate 230 and the housing 220. 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 244 is extended as much as possible, and the second operating cylinder 246 is contracted as much as possible, and the driving of the respective operating cylinders 244 and 246 is performed. Accordingly, the sluice gate 230 is rotated in the opening direction so that the sluice plate 231 comes into close contact with the rounded portion of the bottom of the housing 220 in a downward direction, so that the sluice gate 230 is completely opened. At the time of opening, the top surface of the sluice plate 231 and the bottom surface of the housing 220 form a horizontal state, and the rounded side of the sluice plate 231 adheres closely to the rounded portion in the downward direction of the bottom of the housing 220. Therefore, the water in the reservoir space can be smoothly discharged to the top of the sluice plate 231 of the sluice gate 230, and foreign matters are not caught between the housing 220 and the sluice gate 230 when water is discharged.

That is, according to the third embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the supporting structure is provided in each of the housing cylinders 244 and 246 for rotating the gate 230. If the separate storage space is not formed on the 210, workability can be improved, and the water gate 230 can be constructed with a relatively large size 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.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that the water in the storage space is provided on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the twenty-sixth exemplary embodiment of the present invention may be configured to supply power generated from the photovoltaic system 260 applied to the twenty-fourth exemplary embodiment of the present invention. Is self explanatory.

[Example 27]

79 is a side sectional view of the revolving door according to the twenty-seventh embodiment of the present invention, FIG. 80 is a side sectional view of the revolving door according to a twenty-seventh embodiment of the present invention, and FIG. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the rotatable gate according to the twenty-seventh embodiment of the present invention has a water channel 211 formed between the two support structures 210, and housings 220 are provided on opposite surfaces of the two support structures 210, respectively. Covered through the housing 220, the fixed shaft 233 is fixed to the inside of the support structure 210, respectively, and both sides plate 232 is fixed to the both ends of the arc-shaped sluice plate 231 at a right angle ( 230 is provided so that both side plates 232 are rotatably fixed to the fixed shaft 233, respectively.

In addition, an operation cylinder 240 ′ is rotatably installed at one side of the wall 220 of the housing 220 such that the piston rod 241 ′ is rotatably connected to the drain side of both side plates 232.

When the operating cylinder 240 'is configured to extend in this manner, the water gate 230 rotates in the closing direction, and when the rotation angle reaches 90 °, the water plate 231 stands in a vertical direction to form a closed state. Water fills up the reservoir.

When the working cylinder 240 'is extended as much as possible in a state where water is stored in the storage space, a space is generated between the water gate 230 and the housing 220, and the bottom water of the storage space is discharged through the space, thereby 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 240 'is contracted as much as possible, and the water gate 230 is rotated in the direction in which the water gate 230 is opened in accordance with the operation of the operation cylinder 240', so that the watermark plate 231 is rotated. The door 220 is in a state of being in close contact with the rounded portion of the bottom of the housing 220 in a downward direction, and when the water gate 230 is opened, the top surface of the water gate plate 231 and the bottom surface of the housing are closed. A horizontal state is formed, and the rounded side of the sluice plate 231 is in close contact with the rounded portion of the bottom of the housing 220 so that the water in the reservoir space is smoothly discharged to the top of the sluice plate 231 of the sluice 230. When the water is discharged, foreign matters are not caught between the housing 220 and the water gate 230.

That is, according to the twenty-seventh embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and since the operation cylinder 230 ′ for rotating the gate 230 is installed in the housing 220, the supporting structure 210 is provided. It is possible to improve the workability without having to form a separate storage space in the water, and to build a relatively large size of the sluice gate 230 compared to the width of the river to discharge faster than when the water level increases rapidly, such as flood This makes it possible to prevent the occurrence of crisis situations such as flooding.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that water in the storage space is stored on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the twenty-seventh embodiment of the present invention may be configured to supply power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention. Is self-explanatory.

[Example 28]

FIG. 82 is a sectional front view of a sluice door according to a twenty-eighth embodiment of the present invention, FIG. 83 is a side sectional view of opening the swivel door according to a twenty-eighth embodiment of the present invention, and FIG. Side cross-sectional view when closing the rotating gate according to Figure 85 is a side cross-sectional view when discharging the lower end of the rotating gate according to the 28th embodiment of the present invention.

As shown, the rotatable water gate according to the twenty-eighth embodiment of the present invention has a water channel 211 formed between the two support structures 210, and housings 220 are provided on opposite surfaces of the two support structures 210, respectively. Covered through the housing 220, the fixed shaft 233 is fixed to the inside of the support structure 210, respectively, and both sides plate 232 is fixed to the both ends of the arc-shaped sluice plate 231 at a right angle ( 230 is provided so that both side plates 232 are rotatably fixed to the fixed shaft 233, respectively.

In addition, a sealed space 214 is formed between the housing 220 and the support structure 210, and the operation tube 246 is inserted into the fixed shaft connection portions of both side plates 232 to the outside to form the operation tube ( 246 is located in the sealed space 214, the operation link 234 'is fixed to the sealed space position of the operating pipe 246, the operating cylinder 240' is rotatable on one side of the sealed space 214. It is fixed so as to, the front end of the piston rod 241 'of the operating cylinder 240' is made to be rotatably connected to the front end of the operating link (234 ').

When the working cylinder 240 'is contracted in this configuration, the working tube 246 is rotated by the operating link 234', so that the water pipe 230 fixed with the working tube 246 is closed. When the rotation angle is 90 °, the watermark plate 231 is vertically erected in a closed state, and water is filled in the reservoir space.

When the operation cylinder 240 'is contracted as much as possible in the state where water is stored in the reservoir, a space is generated between the water gate 230 and the housing 220, 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 240 'is extended as much as possible, and the water gate 230 is rotated in the direction in which the water gate 230 is opened in accordance with the operation of the operation cylinder 240', so that the watermark plate 231 is rotated. The door 220 is in a state of being in close contact with the rounded portion of the bottom of the housing 220 in a downward direction, and when the water gate 230 is opened, the top surface of the water gate plate 231 and the bottom surface of the housing are closed. A horizontal state is formed, and the rounded side of the sluice plate 231 is in close contact with the rounded portion of the bottom of the housing 220 so that the water in the reservoir space is smoothly discharged to the top of the sluice plate 231 of the sluice 230. When the water is discharged, foreign matters are not caught between the housing 220 and the water gate 230.

That is, according to the twenty-eighth embodiment of the present invention, the basic function as the rotating gate can be perfectly performed, and since the fixed shaft 233 is fixed to the support structure 210, a support bracket for supporting the fixed shaft 233 is provided. Since there is no need for such a member, the size of the enclosed space 214 can be minimized, and as the size of the enclosed space 214 is minimized, the floodgate 230 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.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that the water in the storage space is provided on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the twenty-eighth embodiment of the present invention may be configured to supply power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention. Is self-explanatory.

[Example 29]

86 is a side sectional view of the revolving door according to the twenty-ninth embodiment of the present invention, FIG. 87 is a side sectional view of the revolving door according to a twenty-ninth embodiment of the present invention, and FIG. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the rotatable gate according to the twenty-ninth exemplary embodiment of the present invention has a water channel 211 formed between the two support structures 210, and the housing 220 is provided on the opposite surface of the two support structures 210, respectively. Covered through the housing 220, the fixed shaft 233 is fixed to the inside of the support structure 210, respectively, and both sides plate 232 is fixed to the both ends of the arc-shaped sluice plate 231 at a right angle ( 230 is provided so that both side plates 232 are rotatably fixed to the fixed shaft 233, respectively.

In addition, a space portion 232a is formed in both side plates 232, and an operation link 234 is fixed at the space portion position of the fixed shaft 233, and an opposite side that is horizontal to the front end of the operation link of the space portion 232a. The idle roller 237 is located at the site, and the other idle roller 237 'is rotatably positioned inside the fixed shaft 233, and the idle roller 237 is idle from the distal end of the operation link 234. The operation cable 238 is connected to the outside through the inside of the fixed shaft 233 via the roller 237 'is connected.

In addition, although not shown in the drawings, the outer side of the gate of the operation cable 238 can be configured to connect the winding roll connected to the winch to wound or loosen the operation cable 238, in addition to pulling the operation cable 238 Naturally, the release device should be connected to the position outside the water gate of the operation cable 238.

Pulling the operation cable 238 in the state configured as described above, the position of the operation link 234 and the idle roller 237 is close, the operation link 234 is fixed, so that the water gate 230 is rotated in the direction of closing When the rotation angle is 90 °, the sluice plate 231 is erected in a vertical direction to form a closed state so that water is filled in the reservoir.

When the operation cable 38 is further pulled while the water is stored in the storage space, the water gate 230 is further rotated to generate a space between the water gate 230 and the housing 220, and through this space, the lower layer of the storage space. 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 rapidly increases, such as flooding, the operation cable 238 is released, and the water gate 230 begins to rotate in the opening direction by its own weight, and the water plate 231 is bottomed out of the housing 220. When close contact with the rounded portion of the negative direction, the water gate is completely open, and when the water gate 230 is opened, the top surface of the water gate plate 231 and the bottom surface of the housing form a horizontal state and at the same time the water gate plate ( Since the rounded side of the 231 is in close contact with the rounded portion of the bottom of the housing 220, the water in the reservoir space can be smoothly discharged to the top of the sluice plate 231 of the sluice 230, and foreign substances are discharged when the water is discharged. It is not caught between the housing 220 and the sluice 230.

That is, according to the twenty-ninth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the actuating cable 238 for rotating the gate 230 is the gate 230 through the inside of the fixed shaft 233. Since it is drawn to the outside of the support structure 210 does not need to form a separate storage space to improve the workability, it is possible to build a floodgate 230 of a relatively large size compared to the width of the river and Likewise, when the water level increases rapidly, faster discharge is possible, which can prevent occurrence of crisis such as flooding.

In addition, although not shown in the drawings, the upper side of the side plate 232 is formed with a slit-type operation cable withdrawal groove to pull the operation cable 238, the operation cable 238 and the side plate when the water gate 230 is rotated Obviously, the 232 should not interfere with each other, and the packing member is provided on the outside of the slit-type working cable lead-out groove to prevent water from entering the space portion 232a inside the side plates 232. do.

In addition, a packing member is provided between the both side plates 232 and the housing 220, and between the fixed shaft 233 and the both side plates 232, respectively, so that water in the reservoir space is stored in both the side plates 232 and the housing 220. It is prevented from leaking into a gap between the gap or between the fixed shaft 233 and the side plate 232.

In addition, the device for winding or releasing the operation cable 238 to rotate the rotating gate according to the twenty-ninth embodiment of the present invention power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention It is obvious that this can be configured to be supplied.

30th Example

89 is a perspective view of a sluice gate of a sluice gate according to a thirtieth embodiment of the present invention, and FIG. 90 is a front sectional view of the sluice gate to which the sluice gate according to the thirtieth embodiment of the present invention is applied.

As shown, the thirtieth embodiment of the present invention relates to the structure of a sluice applied to a rotating sluice according to each of the above-described embodiments, and each of the side plates 32 and 232 of the sluice supports in a direction facing each other. The protruding portion 232b is formed, and the sluice plates 31 and 231 are fixed by the bolts 239 in a state in which the protruding portions 232b are mounted.

At this time, the sluice plates 31 and 231 may be made of any material as long as the material can withstand the water pressure of the storage space such as metal, rubber, and synthetic resin.

In addition, the coupling grooves 232c are formed in the middle of the support protrusions 232b so as to improve the convenience and coupling force in the work when the watermark plates 31 and 231 and the support protrusions 232b are coupled to each other. 31) Both sides of the coupling groove corresponding position of the coupling groove (232c) to form a coupling projection (231a) to be fitted to the coupling groove (232c) bolts 239 in the state fitted to the coupling groove (232c) Will be assembled.

In this configuration, the assembling of the sluice plates 31 and 231 and the two side plates 32 and 232 becomes very simple when the sluice plates 30 and 230 are formed, and also the sluice plates 31 and 231. Both side plates (32, 232) can be made of different materials according to their functional characteristics can reduce the manufacturing cost, and the sluice plates (31) (231) and both side plate ( When any one of the members 32) 232 is damaged, only the member can be replaced so that the entire gate 30 and 230 do not need to be discarded.

Of course, it is a matter of course that the water gates 30 and 230 of this structure are applicable to all embodiments of the present invention.

[Example 31]

91 is a cross-sectional view of the sluice plate of the rotating gate according to the thirty-first embodiment of the present invention.

As shown, the thirty-first embodiment of the present invention relates to a structure and a manufacturing method of a sluice plate applied to a rotating sluice, and the sluice plates 31 and 231 have a rounded bottom surface, and the top surface is flat. Therefore, to this end, both ends of the middle plate 231c and the top plate 231d having a flat shape are fixed to the bottom plate 231b rounded with a constant curvature, so that the middle plate 231c and the top plate 231d do not cry or bend. The H-shaped reinforcing table 231e is fixed to the center portions of the 231d, the intermediate plate 231c, and the lower plate 231b.

At this time, the upper plate 231d, the intermediate plate 231c, the lower plate 231b, and the reinforcing rod 231e constituting the sluice plates 31 and 231 may be formed by welding or soldering, or connecting members such as bolts and nuts. It may be configured by assembling, and the material may be composed of a metal material such that welding or soldering or joining through a connecting member may be possible, or a rubber or synthetic resin material that can be joined using a connecting member. can do.

In this configuration, the sluice plates 31 and 231 can be light in weight while having both a shape and rigidity that can be applied to the rotating sluice according to the present invention. There is an advantage that can greatly reduce the.

Of course, the hydroplates 31 and 231 of this structure are also applicable to all embodiments of the present invention.

[Example 32]

92 is an exploded perspective view of a hydrological gate of a rotating gate according to a thirty-second embodiment of the present invention.

As shown, the water gate according to the thirty-second embodiment of the present invention has a side plate 232 so as to easily replace or repair the members housed therein when the space portion 232a is formed inside the side plate 232. To configure one side of the prefabricated, one side of both sides of the plate 232 is open to communicate with the space portion 232a, and has a lid (232d) to seal such an open portion, the lid 232d It is configured to fasten with the bolt (239) against the open portion.

In this case, a power means such as an operation cylinder is accommodated in the side plate 232 to operate the water gate 230 to drive the water gate 230, and when a failure occurs or becomes obsolete, the bolt 239 needs to be replaced. When the lid 232d is removed to remove the space 232a, the space 232a can be opened so that the power means or the member can be easily repaired or replaced.

Of course, in the application of the ninth embodiment of the present invention, although not shown, the inner edge surface of the lid 232b or the space portion of both side plates 232 is provided with a packing member at the lid portion 232d and the space portion. It is obvious that the gap between (232a) should not cause leakage.

Further, the thirty-second embodiment of the present invention is applied to the rotating gate according to the nineteenth embodiment, the twenty-fourth embodiment, and the twenty-ninth embodiment in which the space portions 32a and 232a are formed on both side plates 32 and 232. This is preferable.

[Example 33]

93 is a side sectional view of the revolving door according to the 33rd embodiment of the present invention, FIG. 94 is a side sectional view of the revolving door according to the 33rd embodiment of the present invention, and FIG. 95 is a 33 of the present invention Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the thirty-third embodiment of the present invention is to adjust the distance between the water gate 30, 230 and the bottom of the housing 220, 220 according to the water level, inflow water, inflow rate, Selecting each of the embodiments of the invention to configure the rotation door, the sensing rod 271 is fixed to the reservoir side of the two side plates (32, 232), the plurality of proximity sensors sequentially on top of the housing (20, 220) (272a to 272e), the control box (273) for controlling the gates (30, 230) by forming the proximity sensor control buttons (274a to 274e) to match the number of each of the proximity sensors (272a to 272e) will be.

At this time, the position of the proximity sensor (272a ~ 272e) is the gate (30, 230) so that the detection rod 271 is close when the detection rod 271 is rotated together with the gate (30, 230) Obviously, it should be arranged in a position that can share the rotation center of the, and the number of installation of the proximity sensor (272a ~ 272e) may vary depending on the size of the water gate (30) (230), the average inflow of water, weather conditions, etc. In the drawings, five proximity sensors 272a to 272e are illustrated as an example.

In addition, the position of the proximity sensor (272a ~ 272e) may also vary depending on the size of the water gate (30, 230), the average amount of water inflow, weather conditions, for example, the number of the proximity sensor (272a ~ 272e) consists of five While configuring the proximity sensor (272a ~ 272e) spacing 5cm intervals can be adjusted to the gap between the water gate 30, 230 and the bottom of the housing 20, 220 up to 20cm difference will be.

The first proximity sensor control button 274a of the control box 273 in the state configured as described above is set by pressing and when the water gates 30 and 230 rotate to the closed position, the first proximity sensor 272a is operated to detect the rod ( When 271 is approached to the position of the first proximity sensor 272a, it detects the signal and transmits the detection signal to the integrated control system (not shown), and the integrated control system controls the oil supply according to the detected signal. By stopping the 30 and 230, the water gates 30 and 230 can be stopped in the closed state, and in this state, the water is filled in the reservoir space.

When a lot of water is filled in the reservoir, the first proximity sensor 272a is turned off and the second proximity sensor control button to the fifth proximity sensor control button 274b to 274e according to the water level of the reservoir, water inflow or inflow rate. If you select any one to rotate the gate (30, 230) in the setting state by pressing it when the sensing rod 271 is close to the corresponding proximity sensor (272b ~ 272e) as the above proximity sensor ( 272b to 272e) to detect the position and transmit it to the integrated control system, and the integrated control system controls the oil supply according to the detected signal to stop the floodgates 30 and 230 to stop the floodgates 30 and 230. And a space may be formed at the bottom of the housing (20, 220), the foreign material such as sedimentation sludge deposited on the bottom of the river is discharged through the space, such that the sedimentary sludge deposited on the bottom of the stream materialPolluted water is naturally purified by acceleration, mass cutting, material releasing, and material flotation.

Of course, according to the proximity sensor control buttons (274a ~ 274e) selected by the operator can control the distance between the bottom of the water gate (30) 230 and the housing 20, 220, such proximity sensor control buttons (274a ~) The selection criteria of 274e) should naturally take into account the current weather conditions, the inflow or inflow rate of water, and the water level in the reservoir. For example, if the inflow rate of the water is not very fast, select the second proximity sensor control button 274b. The distance between the water gates 30 and 230 and the bottom of the housing 20 and 220 can be adjusted to 5 cm, and if it is determined that the inflow rate of water is fast and the water level rises quickly due to rain, the fifth proximity sensor control button ( 274e) to adjust the distance between the gates 30, 230 and the housing 20, 220 to 20 cm.

In addition, the operation of each of the proximity sensor control buttons (274a ~ 274e) can be arbitrarily selected by the operator, based on the signals detected through various sensors such as water level sensor, flow rate sensor, and calculated automatically by the integrated control system for 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 thirty-third embodiment of the present invention, in performing the basic function as the rotating gate, between the gates 30 and 230 and the bottom of the housing 20 and 220 according to the current weather condition, low water level, inflow rate or inflow rate. Since it is possible to adjust the spacing of the water level will have the advantage that can be finely adjusted.

[Example 34]

FIG. 96 is a cross-sectional view of the revolving door according to the thirty-fourth embodiment of the present invention, and FIG. 97 is a cross-sectional view of the revolving door according to a thirty-fourth embodiment of the present invention.

As shown, the thirty-fourth embodiment of the present invention relates to a construction method of a rotating gate, and in the case of the rotating gate according to the present invention, the support structure (Rotating around the rotating shaft 33 or the fixed shaft 233) is rotated. 10) In the state of constructing both side walls in the first construction of the water gate (30) 230 is installed on the support structure (10) (210), just below the lower surface of the water gate (30) (230) Curing the concrete in the state of installing the formwork (212) is installed after disassembly of the formwork (212) bar, the water gate (30) (230) when building the concrete of the lower surface of the water gate (30) ( When the 230 moves arbitrarily, the formwork 212 is damaged and a concrete structure having a desired shape cannot be obtained, so that the formwork 212 is installed on the lower surface of the water gate 30 and 230 and the water gate 30 and 230 are formed. Connecting the connection member 213 such as bolt-nut between the 212, so that the water gate 30, 230 does not rotate Integrates with the lock formwork 212, and after the concrete is poured and cured, is completed by dismantling the connection member 213 together when dismantling the formwork 212.

In this way, it is possible to form a rounded bottom portion of a clean shape without any jamming when the water gates 30 and 230 rotate.

Of course, it will be apparent that the thirty-fourth embodiment of the present invention can be applied to the manufacture of any type of rotating gate according to each embodiment of the present invention.

In addition, before installing the civil engineering facilities, arranging the reinforcing bar in the formwork for building the wall for supporting the water gate (30, 230) of the support structure (10, 210) and placing concrete therebetween. After curing, it is obvious that the water gates 30 and 230 are rotatably fixed to the walls of the support structures 10 and 210.

[Example 35]

FIG. 98 is a cross-sectional view of the revolving door according to the thirty-fifth embodiment of the present invention, and FIG. 99 is a cross-sectional view of the revolving door according to a thirty-fifth embodiment of the present invention.

As shown, the thirty-fifth embodiment of the present invention also relates to a construction method of the rotating gate, and in the state in which both side walls are first constructed when the support structures 10 and 210 are constructed, as in the thirty-fourth embodiment of the present invention. The water gates 30 and 230 are installed in the support structures 10 and 210, and the formwork 212 ′ having the same curvature is installed directly below the lower surface of the water gates 30 and 230, and the water gate 30 is provided. Placing concrete in an integrated state with the formwork 212 'so that the water gates 30 and 230 are not rotated by connecting a connection member 213' such as a bolt-nut between the 230 and the formwork 212 '. In this case, a plurality of coupling pins 212a are formed at the bottom of the formwork 212 'so that the coupling pins 212a are embedded in the bottom of the support structure 210 that is a concrete structure. When the bottom of the structure (10, 210) is cured, the connecting member (213 ') that was connected between the water gate (30) 230 and the form (212') To complete the demolition.

That is, when constructing the bottom of the support structure (10, 210) with concrete, the formwork (212 ') is to be integrated with the bottom of the support structure (10, 210) of the concrete structure, after the formwork (212') ) Forms the bottom of the channel, which is always fixed to the bottom of the support structure.

Therefore, since the bottom portion of the waterway is always in contact with water, the formwork 212 '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 212a is also illustrated as an example of a shape that is gradually sharpened toward the lower end in the drawing, it is obvious that the form 212 'may be formed in various shapes such as a tooth shape so that the formwork 212' is not detached from the buried state. .

In this way, it is possible to form a rounded bottom portion of a clean shape without any locking at the time of rotation of the water gate (30) 230, as well as to dismantle only the connecting member 213 'after curing of the concrete structure construction is very easy And, since the formwork (212 ') at the bottom of the waterway is also an advantage that can strengthen the rigidity of this area.

Of course, it will be apparent that the thirty-fifth embodiment of the present invention can be applied to the production of a rotating gate of any shape according to each embodiment of the present invention.

In addition, before installing the civil engineering facilities, arranging the reinforcing bar in the formwork for building the wall for supporting the water gate (30, 230) of the support structure (10, 210) and placing concrete therebetween. After curing, it is obvious that the water gates 30 and 230 are rotatably fixed to the walls of the support structures 10 and 210.

[Example 36]

100 is a side cross-sectional view at the time of opening the rotating gate according to the 36th embodiment of the present invention, FIG. 101 is a side cross-sectional view at the closing time of the rotating door according to the 36th embodiment of the present invention, and FIG. 102 is a 36th view of the present invention. Side cross-sectional view when discharging the lower end of the rotating door according to the embodiment, Figure 103 is a cross-sectional view taken along the line AA of Figure 100, Figure 104 is a cross-sectional view taken along the line BB of FIG.

As shown, in the thirty-sixth embodiment of the present invention, the channel 211 is formed between the two support structures 210, and the housings 220 are covered with the opposite surfaces of the two support structures 210, respectively. The sealed space 214 is formed, and the semi-circular guide rails 280 are formed in the water storage side direction from the bottom to the side portions of the housing 220 facing each other, and the water gates having the semi-circular guide protrusions 231f formed on both sides, respectively. The sluice gate 230 is composed of a plate 231 so that the guide protrusions 231f are slidably positioned on the guide rails 280, respectively, and the first and second towing cables are provided at the upper and lower ends of the guide rails of the sluice plate 231. The first and second towing cables 282a and 282b are connected to the inside of each guide rail 280 so as to be movable along the guide rail 280 while the first and second towing cables 282a and 282b are connected to each other. Ends of the two-stranded cables 282a and 282b rotatably penetrate the housing 220. The first and second winding rolls 283a and 283b are respectively wound around the first and second winding rolls 283a and 283b, and the first and second winding rolls 283a and 283b are rotated in the closed space positions. The first and second actuation cables 284a and 284b are wound, respectively, and the piston rods of the first and second actuation cylinders 285a and 285b are formed at free ends of the first and second actuation cables 284a and 284b. 286a) and 286b.

At this time, the guide rail 280 is formed in the "c" shape opened in the direction facing each other in the cross-sectional direction so that the guide projections (231f) do not fall outwards to be configured in a shape extending further in the direction facing from the end, the sluice plate The lower surface of the 231 is formed to be rounded with the same curvature as the guide protrusion 231f, the upper surface is made flat to withstand hydraulic pressure.

In addition, although not shown in the drawings, the guide rail 280 or the guide protrusion 231f may be provided with a guide roller or a rolling bearing to configure the guide rail 280 and the guide protrusion 231f in contact with the cloud.

Of course, when the first and second actuating cables 284a and 284b are wound or unwound, it is obvious that the first and second towing cables 282a and 282b should be reversed to each other so as to be reversed or unwound.

When the first actuating cylinder 285a located in the above configuration is contracted to pull the first actuating cable 284a, the first winding roll 283a connected thereto is rotated to pull the first towing cable 282a. It is given to raise the sluice plate 231, at the same time the second operation cylinder (285b) located on the lower side is extended to release the second winding (283b) in a free state, the sluice plate (231) forming a sluice 230 ) Is pulled upward so that the second towing cable 282b fixed thereto is naturally pulled and rotates the second winding roll 283b to wind the second actuating cable 284b onto the winding roll 283b. .

At this time, since the semicircular guide protrusions 231f on both sides of the sluice plate 231 are fitted in the guide rails 280 on both sides of the housing 220, the sluice plate 231 is formed by the first towing cable 282a. When pulled in the direction, the guide protrusion 231f moves along the guide rail 280 so that the sluice plate 231 rotates.

 When the sluice plate 231 is pulled by the first towing cable 282a and its turning angle is 90 ° from the initial position, the sluice plate 231 is erected in the vertical direction to close the waterway 211 and the water reservoir from this time. The water fills up.

When the first operation cylinder 285a is further contracted while the second operation cylinder 285b is further elongated while the water is stored in the water storage space, the sluice plate 231 forming the water gate 230 is further upward. As it is pulled, it is pivoted along the guide rail 280, and a space is generated between the sluice plate 231 and the housing 220, 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 sludge are released like river water, and the polluted water is naturally purified by material acceleration, material scavenging, material releasing, and material flotation.

On the contrary, when the second actuating cylinder 285b is contracted and the first actuating cylinder 285a is extended, the hydroplate 231 pivots downward along the guide rail 280 as opposed to the above. When the sluice plate 231 is in close contact with the rounded portion of the bottom of the housing 220, the sluice gate 230 is completely opened, and when the sluice plate 230 is opened, the upper surface and the housing of the sluice plate 231 are opened. The bottom surface of the 220 is in a horizontal state and at the same time the rounded side of the sluice plate 231 is in close contact with the rounded portion in the downward direction of the bottom of the housing 220, the water in the reservoir space to the top of the sluice plate 231 It can be discharged smoothly, foreign matters are not caught between the housing 220 and the sluice plate 231 during the discharge of water.

That is, according to the thirty-sixth embodiment of the present invention, the structure of the sluice gate 230 can be very simply configured in a plate shape, but the basic function as the sluice gate can be performed perfectly, thus reducing the time and cost required for the hydrological work. You can do it.

In addition, although not shown in the drawings, it is natural that a packing member is provided between the guide protrusions 231f and the guide rails 280 to prevent leakage from occurring through these gaps.

In addition, a packing member must also be provided at the housing connection portion of each of the winding rolls 283a and 283b to prevent leakage.

In addition, in the hydraulic control system for driving each of the operation cylinders 285a and 285b to rotate the rotating gate according to the 36th embodiment of the present invention, the solar power generation system 260 applied to the 24th embodiment of the present invention. It is obvious that the power generated from the power supply can be configured to be supplied.

37th Example

105 is a side cross-sectional view of the revolving door according to the thirty-seventh embodiment of the present invention, FIG. 106 is a side cross-sectional view of the revolving door according to a thirty-seventh embodiment of the present invention, and FIG. Side cross-sectional view when discharging the lower end of the rotating door according to an embodiment, Figure 108 is a cross-sectional view taken along the line AA of Figure 105, Figure 109 is a detailed cross-sectional view of the bent portion of the guide rail according to the 37th embodiment of the present invention.

As shown, the thirty-seventh embodiment of the present invention is a modification of the thirty-sixth embodiment, wherein a channel 211 is formed between the two support structures 210, and a housing is provided on the opposite surface of the support structures 210. Each of the 220 is covered with a closed space 214 is formed therebetween, the semicircular guide rails 280 are formed in the water storage side direction from the lower side of the housing 220 facing the side wall, respectively, semicircular on both sides The sluice gate 230 is composed of a sluice plate 231 formed with guide protrusions 231f so that the guiding protrusions 231f are slidably positioned on the guide rails 280, respectively, to guide the sluice plate 231. The tow cable 282 is connected to the upper end of the rail, and the tow cable 282 is positioned inside the guide rails 280 to be movable along the guide rails 280, even when pushing the tow cable 282. Empowering you, A plurality of donut-shaped guide pieces 281 are fitted to the traction cable 282 so as to be bent along the guide rail 280 to be in close contact with each other, and are slidably positioned inside the guide rail 280, and the traction cable 282. ) End is connected to the tip of the piston rod (286) of the working cylinder (285).

At this time, the guide rail 280 has a "c" shape open in the direction facing each other in the cross-sectional direction so that the guide projections (231f) and the guide piece (281) does not fall outwards in a shape extending further in the direction facing from the end The lower surface of the sluice plate 231 is formed to be rounded with the same curvature as the guide protrusion 231, the upper surface is made flat to withstand the water pressure.

In addition, the upper end of the guide rail 280 is further extended in a straight shape so that the piston rod 286 of the operation cylinder 285 can be inserted.

In addition, although not shown in the drawings, the guide rails 280 or the guide protrusions 231f may be provided with guide rollers or rolling bearings so that the guide rails 280 and the guide protrusions 231f may be configured to be in contact with the clouds.

When the working cylinder 285 is contracted in the state configured as described above, the traction cable 282 is pulled, and the hydroplate 231 constituting the sluice 230 is pulled upward by the force, and the sluice plate ( 231) Since the semicircular guide protrusions 231f on both sides are fitted in the guide rails 280 on both sides of the housing 220, the guide protrusions are pulled upward by the traction cable 282. 231f moves along the guide rail 280 so that the sluice plate 231 pivots.

 When the sluice plate 231 is pulled by the traction cable 282 and its turn angle is 90 ° from the initial position, the sluice plate 231 is erected in the vertical direction and closes the waterway 211 so that water is stored in the reservoir space. This is filled.

When the operation cylinder 285 is further contracted in a state where water is stored in the storage space, the water gate 230 is further pulled upward and pivoted along the guide rail 280, and the water plate 231 and the housing ( 220) A space is generated between these, and the lower layer water of the reservoir is discharged through this space, so that foreign substances such as sediment sludge deposited on the bottom of the stream are discharged together with the stream water. In other words, polluted water is naturally purified by material flotation.

On the contrary, when the operation cylinder 285 is extended to push the traction cable 282, a plurality of guide pieces 281 fitted to the traction cable 282 slide with the inner wall surface of the guide rail 280 and the traction cable 282 By preventing the bending and by the pushing force and the weight of the sluice plate 231, the sluice plate 231 is rotated downward along the guide rail 280 as opposed to the above, and the sluice plate 231 When the close contact with the rounded portion of the bottom of the housing 220 in the downward direction, the sluice gate 230 is completely opened. When the sluice gate 230 is opened, the top surface of the sluice plate 231 and the bottom of the housing 220 are closed. At the same time, the surface is in a horizontal state, and the rounded side of the sluice plate 231 is in close contact with the rounded portion in the downward direction of the bottom of the housing 220, so that water in the storage space can be smoothly discharged to the top of the sluice plate 231. , Foreign substances are discharged from the housing 220 and the sluice plate It is not caught between 231.

In addition, when the traction cable 282 passes through the bent portion of the guide rail 280, the guide pieces 281 are gathered inward of the bent portion and the guide rails 281 are separated from the outside of the guide rail 280. It can be naturally curved along the curved portion of the (280) to ensure the reliability of the pushing operation.

That is, according to the thirty-seventh embodiment of the present invention, the basic structure as the rotating gate can be perfectly performed while the structure of the gate 230 is very simple, and the means for operating the gate 230 is an operation cylinder. (285) Because it is made of only one, it is possible to reduce the time and cost of manual work.

In addition, although not shown in the drawings, it is natural that a packing member is provided between the guide protrusions 231f and the guide rails 280 to prevent leakage from occurring through these gaps.

In addition, the housing connecting portion of the winding roll 283 should also be provided with a packing member to prevent leakage.

In addition, the electric power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention in the hydraulic control system for driving the operation cylinder 285 to rotate the rotating gate according to the thirty-seventh embodiment of the present invention It is obvious that this can be configured to be supplied.

38th Example

FIG. 110 is a side cross-sectional view of the revolving door according to the 38th embodiment of the present invention, and FIG. 111 is a side cross-sectional view of the revolving door according to the 38th embodiment of the present invention.

As shown, the thirty-eighth embodiment of the present invention selects each of the embodiments of the present invention to configure the rotational door, the latching jaw 291 is formed and the hinge member 290 having an axial rotation portion 292 thereon ) And installed on both sides of the upper end on the basis that the sluice plates 31 and 231 are closed, and the plate-shaped leg plate 293 is rotatably fitted to the axial rotation part 292 of the hinge member 290. It is configured to be mounted on the locking jaw 291.

At this time, the leg plate (293) is applicable to any material as long as it has a degree of corrosion resistance and robust enough to withstand the load of a person, the upper surface to form a concave-convex portion 294 to prevent slipping Will be constructed.

In addition, the latching jaw 291 for supporting the leg plate 293 is preferably formed to a width sufficient to support the people when climbing on the leg plate (293).

In the state configured as described above, opening and closing the waterways 11 and 211 while rotating the water gates 30 and 230 by driving a power means such as an operation cylinder applied to each embodiment of the present invention, and the water gates 30 and 230. ) To form a space between the housing and the housing 220 to discharge the lower layer water of the reservoir through such a space to allow foreign substances such as sedimentation sludge deposited on the bottom of the river to escape like the river water, causing material acceleration In this way, the polluted water is naturally purified by the substance removal, flotation, and the like.

By the way, when the water gate (30) 230 is installed in the river, the support structure (10, 210) can be up to the position of the person, but the waterway (11) (211) part is disconnected, so that the person can not cross the river, You will need to make a leg or leg separately to cross the river will have the disadvantage.

To this end, in the thirty-seventh embodiment of the present invention, when the water gates 30 and 230 are in the closed position, the leg plate 293 is naturally supported by the locking jaw 291 in a horizontal state. You can walk on (293).

In addition, the uneven portion 294 is formed on the upper surface of the leg member 293, there is also an advantage that can prevent the slip when crossing over.

In addition, when the water gates 30 and 230 are rotated to the open position, the leg plate 293 is rotated together, and the tip is in contact with the bottom of the water channels 11 and 211, and naturally rotates about the axial rotation unit 292. Since it is parallel to the bottom of the water channels (11, 211), there is no interference when the water in the reservoir is discharged.

On the other hand, even when the leg plate 293 is rotated to the opposite side in the state in which the leg plate 293 is horizontal, or when the leg plate 293 is rotated to the opposite side by the water pressure as the water in the reservoir is discharged, the leg plate 229 Since the upper surface of the 293 is turned upside down and is no longer rotated by the locking jaw 291, it is not difficult to return to the original state, and it is natural that the leg plate 293 can cross the river while stepping on it.

[Example 39]

112 is a side cross-sectional view of the revolving door according to the thirty-ninth embodiment of the present invention, FIG. 113 is a side cross-sectional view of the revolving door according to a thirty-ninth embodiment of the present invention, and FIG. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the rotatable gate according to the thirty-ninth embodiment of the present invention has a water channel 211 formed between the two support structures 210, and housings 220 are provided on opposite surfaces of the two support structures 210, respectively. The sealing space 214 is formed therebetween, and the fixing shaft 233 is fixed to the inside of the support structure 210 through the housing 220, and is perpendicular to both ends of the arc-shaped hydroplate 231. Both sides of the plate 232 is provided with a sluice gate 230 is fixed to the two side plate 232 is rotatably fixed to the fixed shaft 233, respectively.

In addition, the guide projection 231f 'is drawn out from the water storage side of both side plates 232 in the direction of the fixed shaft 233 to extend to the sealed space 214, and the driven link 249 having a long hole-shaped guide groove 249a. The guide protrusion 231f 'is inserted into the guide groove 249a in the inside of the sealed space 214, and the operating shaft in the same direction at a position different from the fixed shaft 233 in the sealed space 214. 257 is rotatably fixed, and the opposite end of the guide groove of the driven link 249 is fixed to the actuating shaft 257, and the drive link 248 is drawn out from one side of the actuating shaft 257 and actuated therein. The tip of the piston rod 241 of the cylinder 240 is rotatably connected.

In addition, the bottom of the housing 220 is formed to be rounded with a curvature similar to the curvature of the sluice plate 231 so as not to interfere with the round bottom surface of the sluice plate 231 during rotation of the sluice gate 230.

At this time, the operating shaft 257 should be located below the position of the fixed shaft 233 so that interference does not occur between the driven link 249 and the fixed shaft 233 when the water gate 230 is closed or the bottom discharge, Although not shown in the drawings, the housing 220 should be formed with a round hole corresponding to the rotational trajectory of the guide protrusion 231f 'so that the guide protrusion 231f' may be rotated during the rotation of the water gate 230. Self-explanatory

In the drawings, the illustration of the closed space 214 is omitted for convenience.

When the operating cylinder 240 is elongated in this configuration, the driving link 248 is pushed toward the reservoir side to rotate the operating shaft 257 and is fixed to the operating shaft 257 according to the rotation of the operating shaft 257. The driven link 249 is rotated, and the guide link 231f 'drawn out from both side plates 232 of the sluice gate 230 is inserted into the guide groove 249a of the driven link 249. When the guide protrusion 231f 'is rotated along the guide groove 249a and rotates in the direction in which the sluice 230 is closed, and the sluice plate 231 is rotated by 90 ° in the direction in which the sluice 230 is closed. Standing vertically, it is closed and water is filled in the reservoir.

When the operation cylinder 240 is extended as much as possible in a state where water is stored in the storage space, a space is generated between the water gate 230 and the housing 220 while the water door is further rotated, and the lower layer water of the storage space is discharged through the space. As a result, foreign substances such as sedimentation sludge deposited on the bottom of the river are discharged like the river water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material releasing, and material floating.

In addition, when the low water level rapidly increases, such as flooding, the operation cylinder 240 is contracted as much as possible, and the driving link 248 and the driven link 249 move the operation shaft 257 according to the operation of the operation cylinder 240. When the center is rotated in the opposite direction as when closed, the water gate 230 is rotated in the opposite direction as when closed, and when the sluice plate 231 is in close contact with the rounded portion of the bottom of the housing 220, the water gate ( 230 is in a fully open state, and when the water gate 230 is opened, the upper surface of the watermark plate 231 and the bottom surface of the housing 220 become horizontal and at the same time the round bottom surface of the watermark plate 231 Since the close contact with the rounded portion of the bottom of the housing 220, water in the reservoir space can be smoothly discharged to the top of the sluice plate 231 of the sluice 230, and foreign matters are discharged from the housing 220 and the sluice 230 when water is discharged. You won't get caught between.

That is, according to the thirty-ninth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the operating gate 240 can open and close the gate 230 to reduce the installation cost.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that the water in the storage space is provided on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the thirty-ninth embodiment of the present invention can be configured to supply power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention. Is self explanatory.

In the thirty-ninth embodiment of the present invention, the means for rotating the gate 230 are all described in the closed space 214 as an example. However, the means for rotating the gate 230 is referred to as the means for rotating the gate 230. It may be located on the outside, that is, the channel 211 side, there is an advantage that does not need to form a separate closed space, this modified embodiment is also within the scope of the present invention is natural.

[Example 40]

115 is a side cross-sectional view of the revolving door according to the 40th embodiment of the present invention, FIG. 116 is a side cross-sectional view of the revolving door according to the 40th embodiment of the present invention, and FIG. Figure 118 is a side cross-sectional view when discharging the bottom of the rotating door according to the embodiment, Figure 118 is a side cross-sectional view when closing the opposite side of the rotating door according to a 40th embodiment of the present invention, Figure 119 is a rotation speed according to the 40th embodiment of the present invention Side cross-sectional view of the lower side discharge of the opposite side of the door

As shown, the waterway 211 is formed between the both sides of the support structure 210, the rotating door according to the 40th embodiment of the present invention, the housing 220 on the opposite surface of the support structure 210 Each of the cover spaces 214 are formed therebetween, and fixed shafts 233 are fixed to the inside of the support structure 210 through the housing 220, respectively, and are perpendicular to both ends of the arc-shaped sluice plate 231. As the two-side plate 232 is fixed to the water gate 230 is provided, the two side plate 232 is rotatably fixed to the fixed shaft 233, respectively.

In addition, the first guide protrusions 231g and the second guide protrusions 231h are respectively drawn out in the fixed axis direction from both sides of the outer side plates 232 and extend to the closed space 214, and the respective guide protrusions 231g. The first guide rollers 231i and the second guide rollers 231j are fitted in 231h, respectively, and the first driven link 249 'and the second driven link are in rolling contact with each of the guide rollers 231i and 231j. 249 "is provided inside the sealed space 214, and inside the sealed space 214, the first operating shaft 257 'and the second operating shaft ( 257 ") are rotatably fixed to each other so that each driven link 249 'and 249" is fixed thereto, and the first drive link 248' and the first drive link 248 ' The second drive link 248 " is drawn out so that the front end portions of the piston rods 245 and 247 of the first actuating cylinder 244 and the second actuating cylinder 246 are rotatably connected.

In addition, the bottom portion of the housing 220 is formed to be rounded at a curvature similar to the curvature of the sluice plate so as not to interfere with the round bottom surface of the sluice plate 231 during rotation of the sluice gate 230.

At this time, each of the operating shaft (257 ') (257 ") is fixed shaft so that interference does not occur between the driven link (249') 249" and the fixed shaft 233 at the closing or discharge of the water gate 230 It should be located below the position of 233, and although not shown in the drawings, each guide protrusion 231g and 231h in the housing 220 so that each guide protrusion 231g and 231h can be rotated during the rotation of the water gate 230. Obviously, the rounded holes corresponding to the rotational trajectory of 231h should be formed.

In the drawings, the illustration of the closed space 214 is omitted for convenience.

When the first actuating cylinder 244 is elongated in this configuration, the first actuating link 248 'is pushed to the reservoir side to rotate the first actuating shaft 257', and the first actuating shaft 257 '. The first driven link 249 ', which is fixed to the first operating shaft 257', is rotated according to the rotation of the first driven link 249 ', and the first driven link 249' is positioned in the rolling contact with the first guide roller 231i. Therefore, when the first driven link 249 'is rotated, the water gate 230 is rotated by pushing the water gate 230 to the water storage side by the first guide protrusion 231g while being in contact with the first guide roller 231i. When the water gate 230 is rotated 90 °, the water gate plate 231 is erected in a vertical direction, and the water is filled in the reservoir space.

When the first operation cylinder 244 is extended as much as possible in a state where water is stored in the storage space, the water gate 230 is further rotated, and a space is generated between the water gate 230 and the housing 220. As the bottom layer of the space is discharged, foreign substances such as sedimentation sludge deposited on the bottom of the stream are released like the stream water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material desorption, and material flotation. will be.

On the contrary, when the second actuating cylinder 246 is extended while the water gate 230 is open, the second actuating link 248 "is pushed toward the reservoir side to rotate the second actuating shaft 257". As the second operating shaft 257 "rotates, the second driven link 249" fixed to the second operating shaft 257 "is rotated, and the second driven link 249" is rotated by the second guide roller ( Since the second driven link (249 ") is rotated in contact with the second guide roller (231j) and the second guide projection (231h) by the second guide protrusion (231h) to the water discharge side so that the rolling contact with the 231j. Thus, the water gate 230 is rotated, and even in this case, when the water gate 230 is rotated 90 °, the water gate plate 231 is erected in a vertical direction to form a closed state so that water is filled in the reservoir space.

When the second operation cylinder 246 is extended as much as possible in a state where water is stored in the storage space, the water gate 230 is further rotated to generate a space between the water gate 230 and the housing 220. As the bottom layer of the space is discharged, foreign substances such as sedimentation sludge deposited on the bottom of the stream are released like the stream water, and the contaminated water quality is naturally purified by material acceleration, material scavenging, material desorption, and material flotation. will be.

When the low water level rapidly increases, such as a flood, in the state in which the water gate 230 is closed, the first operation cylinder 244 or the second operation cylinder 246 is contracted as much as possible, and each operation cylinder 244 (246) When the first driving link 248 'or the second driving link 248 "connected thereto is closed about the first operating shaft 257' or the second operating shaft 257", The water gate 230 is rotated in the opposite direction as it is rotated in the opposite direction, and when the water gate plate 231 is in close contact with the rounded portion of the bottom of the housing 220, the water gate 230 is fully opened. At the time of opening the water gate 230, the top surface of the water gate plate 231 and the bottom surface of the housing form a horizontal state, and at the same time, the round bottom surface of the water gate plate 231 is rounded at the bottom of the housing 220. Close contact with the water is smoothly drained to the top of the sluice plate 231 of the sluice gate 230 It may be, as well as when the water discharge foreign matters are not pinched between the housing 220 and the water gate 230.

That is, according to the forty-eighth embodiment of the present invention, the basic function as the rotating gate can be perfectly performed, and the gate 230 can be opened and closed in any direction according to the expansion and contraction of the respective operation cylinders 244 and 246. When the lower surface of the hydrological plate 231 is closed toward the water storage side, the hydraulic pressure may be dispersed to have a sense of stability, and when the upper surface of the hydrological plate 231 is closed toward the water storage side, the hydraulic pressure may be applied to the hydrological plate 231. This relatively large point, but there is an advantage that can secure more water storage.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 232 and the housing 220, and between the fixed shaft 233 and the two side plates 232, respectively, so that the water in the storage space is provided on both sides of the plate 232. ) And a gap between the housing 220 or a gap between the fixed shaft 233 and both side plates 232 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the 40th embodiment of the present invention can also be configured to supply power generated from the photovoltaic system 260 applied to the 24th embodiment of the present invention. Is self explanatory.

In the 40th embodiment of the present invention, the means for rotating the water gate 230 are all described in the example of being located in the sealed space 214. However, the means for rotating the water gate 230 are referred to as the water gate 230. It is also possible to be located outside, that is, the channel 211 side, there is an advantage that does not need to form a separate closed space, this modified embodiment is also within the scope of the present invention is natural.

[Example 41]

FIG. 120 is a side sectional view of the revolving door according to the forty-first embodiment of the present invention, FIG. 121 is a side sectional view of the revolving door according to the forty-first embodiment of the present invention, and FIG. 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 forty-first embodiment of the present invention, the housing 20 on the opposite surface of the both support structures 10, respectively A sealing space 14 is formed therebetween, and an actuating rod 34 'is drawn out upward in an eccentric manner toward one side of the sluice plate 31 having an asymmetrical round shape, and an upper end portion of the actuating rod 34'. It is provided with a sluice gate 30 is fixed to the rotating shaft 33, the rotating shaft 33 is rotatably fixed to the inside of the support structure 10 through the housing 20.

In addition, the operation link 34 is drawn out from the rotation shaft 33 located in the sealed space 12 so that the tip of the piston rod 241 of the operation cylinder 240 is rotatably fixed to the bottom of the housing 20. It is formed to be rounded downward with a curvature similar to the curvature of the sluice plate 31 so as not to interfere with the rounded bottom surface of the sluice plate 31 during rotation of the sluice gate 30.

At this time, the sluice 30 is operated as the hammer (34 ') as if the hammer is rotated because the sluice plate 31 is positioned at its end, the operation link 34 is the sluice (30) so that the rotation operation is made smoothly The opening cylinder is fixed inclined upward from the rotating shaft 33 toward the water storage side, and the operating cylinder 240 connected to the operating link 34 is installed in the horizontal direction. Of course, the installation direction of the operation link 34 and the operation cylinder 240 may be any position as long as it can rotate the water gate 30.

In the drawings, the illustration of the closed space 214 is omitted for convenience.

When the actuating cylinder 240 is contracted in such a configuration, the actuating link 34 is pulled toward the drainage side, and the rotating shaft 33 is rotated in the clockwise direction, and the sluice constituting the water gate 30 according to the rotation of the rotating shaft 33. When the plate 31 is rotated in the direction of closing, and when the water gate 30 is rotated 90 ° in the direction of closing the water gate plate 31 in the vertical direction to form a closed state is filled with water in the reservoir.

When the operating cylinder 240 is contracted as much as possible in a state where water is stored in the reservoir, the water gate 30 is further rotated, and a space is generated between the water gate 30 and the housing 20, and through the space, As the lower layer water is discharged, foreign substances such as sewage sludge deposited on the bottom of the stream are discharged like the stream water, and the contaminated water quality is naturally purified by the acceleration of the material, the scavenging phenomenon, the material removal, and the floating of the material.

In addition, when the low water level rapidly increases, such as flooding, the hydraulic pressure applied to the operation cylinder 240 is released to be free. Then, since the sluice plate 31 is in an elevated state, it is lowered and closed by its own weight. When the sluice plate 31 is in close contact with the rounded portion in the downward direction of the bottom of the housing 20, the sluice plate 30 is completely opened, and the sluice plate 30 is opened. The upper surface of the sluice plate 31 and the bottom surface of the housing 20 are in a horizontal state, and the round bottom surface of the sluice plate 31 is in close contact with the rounded portion of the bottom of the housing 20 so that water in the reservoir space The watermark plate 31 of the 30 can be smoothly discharged, as well as foreign matters are not caught between the housing 20 and the water gate 30 when the water is discharged.

That is, according to the forty-first embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the opening and closing of the gate 30 can be performed with one operation cylinder 240, thereby reducing the equipment cost.

In addition, although not shown in the drawings, a packing member is provided between the two side plates 32 and the housing 20, and between the rotation shaft 33 and the housing 20, respectively, so that water in the reservoir space may be formed between the two side plates 32 and The leakage between the gap between the housing 20 or the gap between the rotation shaft 33 and the housing 20 is prevented.

In addition, the hydraulic control system 264 for controlling the rotating gate according to the forty-first embodiment of the present invention can be configured to supply power generated from the photovoltaic system 260 applied to the twenty-fourth embodiment of the present invention. Is self explanatory.

[Example 42]

123 is a perspective view of a sluice plate according to a forty-second embodiment of the present invention, and 124 is a cross-sectional view of the sluice plate according to a forty-second embodiment of the present invention.

As shown, the forty-second embodiment of the present invention relates to a structure and a manufacturing method of the sluice gates 30 and 230 applied to the rotating gate, and the sluice gates 30 and 230 to which the forty-second embodiment of the present invention is applied. The triangular bilateral plates 32 and 232 of which the lower surface is rounded on both sides of the flat plate of the sluice plate 31 and 231 are integrated by welding or the like. In each direction, the rotating shafts 33 are drawn out, or the fixed shafts 233 fixed to the support structure 10 are rotatably inserted into both side plates 232. In the water gates 30 and 230, The sluice plates 31 and 231 are fastened with a bolt 31d and a nut 31e with a reinforcing rod 31c placed on the plate support plate 31a with a waterproof plate 31b for preventing leakage. To configure.

In this case, the support plate 31a is made of a metal material such as stainless steel in consideration of structural stability, the waterproof plate 31b is made of a rubber material or a flexible synthetic resin material, and the reinforcing table 31c is made of a metal material. Of course, it is obvious that the material of each of these members can be replaced with other materials as long as they can satisfy their respective properties.

The sluices 30 and 230 configured as described above can be made light in weight while having both shape and rigidity applicable to the rotating sluice, and are easy to handle, and can be manufactured in a prefabricated manner, thereby achieving convenience of production. There is an advantage that can greatly reduce the manufacturing cost.

In addition, it is a matter of course that the hydrological structure of this structure is applicable to all embodiments of the present invention.

[Example 43]

125 is a sectional front view of the rotatable gate according to a 43rd embodiment of the present invention, FIG. 126 is a side sectional view of the rotatable gate according to a 43rd embodiment of the present invention, and FIG. 127 is a 43th embodiment of the present invention; Side cross-sectional view when closing the rotating gate according to Figure 128 is a side cross-sectional view when discharging the bottom of the rotating gate according to the 43rd embodiment of the present invention.

As shown, the rotatable gate according to the 43rd embodiment of the present invention has a water channel 211 formed between the two support structures 210, the housing 220 on the opposite surface of the two support structures 210, respectively The sealing space 214 is formed therebetween, and the fixing shaft 233 is fixed to the inside of the support structure 210 through the housing 220, and is perpendicular to both ends of the arc-shaped hydroplate 231. A sluice gate 230 having both side plates 232 fixed thereto is provided, and both side plates 232 are integrally formed with a rotary tube 233b inserted into the fixed shaft 233 so that the rotary tube 233b is fixed shaft. It is made rotatably inserted into (233).

In such a rotating gate, the driven gear 256 is integrally press-fitted to the sealed space position of the rotary tube 233b, and the driving screw 255 having a smaller diameter than the driven gear 256 on one side of the driven gear 256. ) Is meshed with the driven gear 256 in a worm gear shape, and the drive screw 255 is fixed to the axis of the drive motor 106 so that the rotational force of the drive motor 106 drives the drive screw 255 and the driven gear 256. Is transmitted to the rotary tube 233b through it is configured to open and close the waterway 211 while rotating the water gate 230.

At this time, the drive motor 106 applied to the 43rd embodiment of the present invention may be applied to a general electric motor, it may be applied to a hydraulic motor is not particularly limited to the type of motor.

In the rotational gate according to the 43rd embodiment of the present invention configured as described above, when the driving motor 106 is driven while the water gate 230 is completely open, the driving screw 255 is rotated, and the driving screw 255 is The rotational force is transmitted to the driven gear 256 meshed in a worm gear shape so that the driven gear 256 is rotated, and the rotary tube 233b is rotated according to the rotation of the driven gear 256 so that the water gate 230 is integrally formed therewith. The waterway 211 can be opened and closed while being rotated in the 360 ° direction.

Therefore, by operating the rotational position of the drive motor 106 by the command of the integrated control system (not shown) to stop the gate 230 to the desired position to keep the gate 230 in an open state or in a closed state Obviously, it can be maintained or maintained in the bottom discharge state.

In addition, the rotation gate according to the 43rd embodiment of the present invention may decelerate the fast rotational speed of the driving motor 106 through the driving screw 255 and the driven gear 256 engaged in a worm gear shape and transmit the deceleration to the gate 230. Since the rotational speed of the water gate 230 can be a large force without being fast to provide a proper speed and force to drive the water gate 230.

[Example 44]

129 is a side cross-sectional view of the revolving door according to the 44th embodiment of the present invention, FIG. 130 is a side cross-sectional view of the revolving door according to the 44th embodiment of the present invention, and FIG. Side cross-sectional view when discharging the bottom of the rotating gate according to the embodiment.

As shown, the rotating gate according to the forty-fourth embodiment of the present invention increases the curvature of the round surface 31f formed at the bottom of the sluice plates 31, 231 to increase the thickness of the sluice plates 31, 231. It is configured to be thin, but there is no interference in the rotation operation, as well as foreign matters are not caught between the housing 20, 220 and the water gate (30) 230 when the water gate (30) 230 is opened, the water gate The center of the rounded surface 31f formed below the plates 31 and 231 has a large curvature compared to the curvature of the circle centered on the rotary shaft 33 or the fixed shaft 233, and the housing 20 ( The round surface 20a formed directly below the sluice of the 220 is formed in an arc shape centering on the rotation shaft 33 or the fixed shaft 233, and the sluice plates 31 and 231 when the sluices 30 and 230 are opened. ) Both ends of the round surface 20a of the housings 20 and 220 coincide with the ends of the lower surface of the sluice plates 31 and 231 and the middle of the round surface 20a of the housing 20 and 220. Spacing It is configured to be.

That is, the center of the round surface 30f formed at the lower portion of the water gates 30 and 230 with respect to the opening of the water gates 30 and 230 is higher than the position of the actual rotation shaft 33 or the fixed shaft 233. It is configured to be located in place.

In this configuration, both ends of the sluice plates 31 and 231 and both ends of the round surfaces 20a of the housings 20 and 220 in the open state of the water gates 30 and 230 coincide with each other so that foreign matters are formed in the gap. It is possible to prevent the inflow, and even when the water gates 30 and 230 are closed, one end of the water gate plates 31 and 231 and one end of the round surface 20a of the housing 20 and 220 may be in close contact with each other. Being able to prevent the leakage of water in the reservoir space, it is possible to perform all operations of opening, closing, bottom discharge of the water gates (30, 230) required as a rotating water gate.

In addition, the thickness of the hydrologic plates 31 and 231 together with the basic functions of the hydrologic gates 30 and 230 can be configured to facilitate the handling in the manufacture of the hydrologic gates 30 and 230. Of course, manufacturing costs can be reduced.

In addition, the rotating gate of such a structure is applicable to all of the first to forty-third embodiments of the present invention.

45th Example

132 is a sectional front view of the rotatable sluice according to the forty-fifth embodiment of the present invention, FIG. 133 is a side sectional view of the rotatable sluice according to the forty-fifth embodiment of the present invention, and FIG. 134 is a forty-fifth embodiment of the present invention. Side view at the closing of the rotating gate according to

The 45th embodiment of the present invention is a modified embodiment of the sixth embodiment, and like the sixth embodiment, the channel 11 is formed between the two support structures 10 coupled with the integrated control system (not shown). On both sides of the support structure 10, the housing 20 is covered with each other, so that a sealed space 12 is formed between the housing 20 and the support structure 10, and the arc-shaped sluice plate 31 and the sluice gate are formed. The water gate 30 is composed of both side plates 32 and the rotation shaft 33 drawn outward from both side plates 32 formed at right angles to both ends of the plate 31, and the rotation shaft 33 of the water gate 30 is It is inserted into the shaft hole 21 formed in each housing 20.

In such a rotating door, the drain side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates ( 32 is formed symmetrically about the rotating shaft 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing (20) .

"의 형상으로 절곡된 제 1크랭크부(108)와 제 1크랭크부(108)를 뒤집은 형상의 제 2크랭크부(108')가 회전축(33)으로부터 연속으로 고정되고, 제 1크랭크부(108)와 제 2크랭크부(108')는 지지대(38)에 의해 밀폐공간(12)의 바닥부에 회전가능하게 지지되며, 제 1크랭크부(108)의 중앙에는 제 1작동실린더(51)의 피스톤로드(56) 선단부가 회전가능하게 연결되고, 제 2크랭크부(108')의 중앙에는 제 2작동실린더(61)의 피스톤로드(66) 선단부가 회전가능하게 연결된다.In addition, in the closed space position of the rotating shaft 33, "

The first crank part 108 and the second crank part 108 ′ having the shape of inverting the first crank part 108 are continuously fixed from the rotation shaft 33, and the first crank part 108 ) And the second crank part 108 ′ are rotatably supported at the bottom of the sealed space 12 by the support 38, and in the center of the first crank part 108 of the first operating cylinder 51. The tip of the piston rod 56 is rotatably connected, and the tip of the piston rod 66 of the second actuating cylinder 61 is rotatably connected to the center of the second crank portion 108 '.

At this time, the positions of the respective operation cylinders 51 and 61 may be located at any place of the sealed space 12 unless the respective operation cylinders 51 and 61 are not horizontal to the rotation shaft 33. In the drawings, the respective working cylinders 51 and 61 are coaxially installed at a position higher than the rotation shaft 33 as an example.

The rotating door according to the 45th embodiment of the present invention configured as described above has a first crank part when the first operation cylinder 51 is extended in accordance with the command of the comprehensive control system 100 in a state in which the water gate 30 is completely open. By pushing 108, the water gate 30 starts to rotate, and at the same time, the second crank portion 108 'also rotates with the second actuating cylinder 61 extending or contracting according to its position. In the maximum extension position of the cylinder 51, the sluice plate 31 does not reach a horizontal state, but since the first operation cylinder 51 and the second operation cylinder 61 are not horizontal to the rotation axis, the second operation cylinder 61 is moved. When the water gate 30 is rotated in accordance with the contraction or extension of the second operation cylinder 61, the first operation cylinder 51 may be contracted or extended again. Repeat the water gate (30) in 360 ° direction Can be rotated.

In this way, when the water gate 30 can be rotated 360 °, by adjusting the expansion and contraction degree of each operation cylinder 51, 61, the water gate 30 is stopped at the open position, the closed position, the bottom discharge position, and the complete floating position. By discharging the water in the reservoir, confining the water in the reservoir, or discharging the lower layer of the reservoir, it discharges foreign substances such as sedimentation sludge, through material acceleration, substance cutting, material desorption, and material injury. The polluted water can be purified naturally.

That is, according to the forty-fifth embodiment of the present invention, since the rotary shaft 33 is rotated in a crank manner, the water channel 11 can be opened and closed while rotating the water gate 30 by 360 ° so that the water channel 11 required as the water gate 30 can be opened. ) Can smoothly perform the opening and closing operation.

Here, the positions of the respective operation cylinders 103 and the crank portions 102 'applied to the forty-fifth embodiment of the present invention can be changed to any other position, and therefore, even if the installation positions of these members are changed. Naturally, it belongs to the scope of the present invention.

46th Example

135 is a sectional front view of the rotatable hydrolock according to the forty-sixth embodiment of the present invention, FIG. 136 is a side sectional view of the revolving sluice according to the forty-sixth embodiment of the present invention, and FIG. 137 is a forty-fifth embodiment of the present invention; Figure 138 is a side cross-sectional view at the time of closing the rotating gate in accordance with the 46th embodiment of the present invention when the bottom of the rotating gate.

As shown in FIG. 46, the sixth embodiment of the present invention is also a modified embodiment of the sixth embodiment, and like the sixth embodiment, the channel (between the two support structures 10 coupled with the integrated control system (not shown) is provided. 11 is formed, and the housings 20 are respectively covered by opposing surfaces of both support structures 10 so that a sealed space 12 is formed between the housing 20 and the support structures 10, and an arc-shaped sluice plate ( 31) A sluice formed by integrally forming both side plates 32 at right angles at both ends is provided to open and close the water channel 11.

In such a rotating door, the drain side of the bottom of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, the sluice 30 is the sluice plate 31 and both side plates ( 32 is formed symmetrically, and both lower surfaces of the sluice plate 31 are rounded to the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing 20.

In addition, the first crank 108 and the support 38 are fixed to the bottom of the housing 20 by the first crank 108 and the support plate 38 fixed to both sides of the water gate 30 to rotate the center of rotation of the water gate 30 The first rotating shaft 109, the second crank portion 108 'which is connected to the tip of the piston rod 104 of the working cylinder 103, and the support 38 to be rotatable to the bottom of the housing 20 An actuating ring which is fixed to form a rotational center of the sluice 30 and the second rotating shaft portion 109 'for rotatably supporting the second crank portion 108' together with the first rotating shaft portion 109, respectively. The crank 116 'is fixed to both side plates 32 of the sluice gate 30, and the positions of the first crank part 108 and the second crank part 108' are the same, and the first rotating shaft part 109 And the second rotation shaft portion 109 ′ are the same position, and each of the cranks 108, 108 ′ and each of the rotation shaft portions 109, 109 ′ are positioned in opposite directions.

At this time, the installation direction of each crank portion 108, 108 'and the operation cylinder 103 may be any position of the sealed space 12, and each crank portion 108, 108' in the drawing is a water gate (30) In the upward direction based on the opening of the), the working cylinder 103 is shown as an example installed in the vertical direction.

In addition, although not shown, a guide groove rounded with a curvature corresponding to a rotational trajectory of the first crank part 108 is formed on the sidewall of the housing 20 so as not to interfere with the rotation of the first crank part 108. Obviously, the packing member must be provided to prevent the leak at all times.

The rotating door according to the forty-sixth exemplary embodiment of the present invention configured as described above has the second crank part 108 when the operation cylinder 103 is contracted according to the command of the comprehensive control system 100 in the state in which the water gate 30 is completely open. ') Is pulled and the operation link 116' is rotated about the first and second rotation shaft portions 109 and 109 ', and the first crank portion ( 108 is rotated in the direction in which the lock 30 is fixed.

When the water gate 30 is rotated to 90 ° from the time of opening according to the contraction of the operation cylinder 103, the water gate plate 31 stands vertically and closely adheres to the bottom of the housing 20 so that the water gate 30 is completely closed. At this time, water is filled in the reservoir.

When the operation cylinder 103 is further contracted in the closed state of the water gate 30, a space is generated between the water gate 30 and the bottom of the housing 20 while the water gate 30 is rotated further. By discharging the subsurface water in the reservoir, it is possible to discharge the foreign substances such as sedimentation sludge together to purify the contaminated water quality through material acceleration, material scavenging, material desorption and material flotation.

In addition, when the low water level rapidly increases, such as flooding, the contracted working cylinder 103 is elongated, and the second crank part 108 'is rotatably connected thereto according to the elongation of the working cylinder 103. Is rotated in the opposite direction as when closed, this force is transmitted to the sluice 30 to rotate in the direction in which the sluice 30 is opened, the sluice plate 31 of the sluice 30 is the bottom of the housing 20 When the surface is horizontal, the sluice gate 30 is completely open, so that the water in the reservoir space is discharged to the upper portion of the sluice gate 30 at a high speed, and between the sluice plate 31 and the bottom of the housing 20 Since the foreign matter is not stuck between the water gate (30) and the housing (20).

That is, according to the forty-sixth embodiment of the present invention, the basic function as the rotating gate can be performed perfectly, and the opening, closing, and bottom discharge operations of the gate 30 are completed by using only one operation cylinder 103. Since it can be carried out so that the installation of the sluice 30 is convenient and there is an advantage that the equipment cost is reduced, the multi-stage bent operation link 116 'is used because the sluice 30 does not have to have a separate rotation axis This will be.

Here, the operation cylinder 103 and the respective crank parts 108, 108 'applied to the forty-sixth embodiment of the present invention can be changed to any other position as described above, so that the installation position of each member Even if it is changed to be within the scope of the present invention is a matter of course.

47th Embodiment

139 is a side cross-sectional view of the revolving door according to a forty-seventh embodiment of the present invention, and FIG. 140 is a side sectional view of the revolving door according to a forty-seventh embodiment of the present invention.

As shown, the forty-seventh embodiment of the present invention controls the power means for providing power to the gate 30 according to the position of the gate 30 when opening the gate 30 so that the gate 30 is always accurate. In order to be opened to the position, to configure the rotating gate by selecting each of the embodiments of the present invention, the proximity sensor 272 to the proximal position of both sides of the water gate of the housing 20 based on the open position of the gate 30 Installed to detect that the gate 30 is in an open state, and when the signal detected through the proximity sensor 272 is transmitted to the integrated control system 100, the integrated control system 100 in the hydraulic control system 264 By controlling to block the oil from being supplied to the power means for providing power to the sluice 30 to ensure that the sluice always open correctly.

In this case, the position of the proximity sensor 272 may be any position as long as the two side plates 32 of the water gate 30 are close to each other based on the opening of the water gate 30, and both sides of the water gate 30 are not shown. 32) A separate sensing rod may be installed at one side, and the proximity sensor 272 may be installed at a position close to the sensing rod.

The power means for operating the water gate according to the forty-seventh embodiment of the present invention can be applied to any one, so the illustration of the power means in the drawings is omitted.

Power means for driving the water gate 30 through the hydraulic control system 264 by the command of the comprehensive control system 100 to discharge the water in the reservoir space by opening the water gate in the state in which the rotating water gate is configured as described above When the oil is supplied to the power means, when the oil is supplied to the power means is started by the power means to rotate the water gate 30 in the opening direction.

The opening of the water gate 30 means that the water gate plate 31 is level with the bottom of the housing 20. When the water gate 30 is rotated in the direction in which the water gate 30 is opened, both side plates of the water gate 30 ( 32 means gradually closer to the proximity sensor 272. When the water gate 30 is completely open, both side plates 32 of the water gate 30 fall into the detection range of the proximity sensor 272, and the proximity sensor. When it is detected that the water gate 30 is completely opened through the 272, the signal is transmitted to the integrated control system 100, and the integrated control system 100 controls the hydraulic control system 264 to open the water gate 30. The oil is blocked from being supplied to the driving power means, and thus the water gate 30 stops its operation.

That is, according to the forty-seventh embodiment of the present invention, the sluice gate 30 can always be stopped at the correct position in the fully open state, thereby improving reliability in use and preventing unnecessary use of power.

48th Example

FIG. 141 is a side cross-sectional view of the revolving door according to the 48th embodiment of the present invention, FIG. 142 is a side cross-sectional view of the revolving door according to the 48th embodiment of the present invention, and FIG. Side cross-sectional view at the time of repair replacement of the rotating gate according to the embodiment.

As shown, the rotating gate according to the forty-eighth embodiment of the present invention is configured to facilitate the repair and replacement of the sluice gate 30 and to open and close the channel 11 even during the repair replacement of the sluice gate. A water channel 11 is formed between the two support structures 10 coupled to the control system (not shown), and the housings 20 are respectively covered on opposite surfaces of the both support structures 10, and the water channels 11 A water gate 30 for opening and closing it is rotatably provided.

In addition, the bottom portion between the two support structures 10 is formed with two rounded steps 13 and 13 ', and the bottom portion of the housing 20 covered therein is also the bottom between the two support structures 10. Similarly, the two-stage rounded step (25, 25 ') is configured to be in close contact with the bottom between the two support structures 10, the sluice (30) is perpendicular to both ends of the arc-shaped sluice plate (31) Both side plates 32 are integrally formed, and each of the side plates 32 is formed in a shape in which the rotating shafts 33 are fixed in the outward direction, respectively, and two sets of the sluice gates 30 of this shape are provided so that the sluice plate 31 is provided. Are positioned at two rounded steps 25, 25 'of the housing 20, respectively.

In addition, the two supporting structures 10 and the two housings 20 are each provided with two guide grooves 14 for accommodating the rotation shaft 33 of each of the water gates 30 and withdrawing the whole water gate 30 upwards. Is formed to accommodate the rotary shaft 33 of the water gate 30, and when the rotary shaft 33 is positioned at the lower end of the guide groove 14, holding the rotary shaft 33 or moving the water gate 30 upwards In order to release the position of the rotary shaft 30 when the lower side of each guide groove 14, the wedge 16 connected to the cylinder 15 is provided to be stretchable. At this time, the water gate 30 located on the reservoir side will be referred to as the reservoir side gate, and the water gate 30 located on the drainage side will be referred to as the drainage side gate.

In addition, the first driving motor 106c and the second driving motor 106d are respectively provided at the upper portions of the guide grooves 14 of the both side support structures 10, respectively, wherein the first winding rolls 283a and the second volume are respectively provided. A rotatable roll 283b is connected, and an operation link 34 is fixed to one side of the rotation shaft 33 of each flood gate 30, and a first actuating cable is connected between the first winding roll 283a and the tip of the actuating link 34. 284a is connected, and the second actuating cable 284b is connected from the distal end of the actuating link 34 to the second winding roll 283b via the rotating shaft 33, so that the first driving motor 106c and the second are connected. According to the forward and reverse rotation of the driving motor 106d, the water gate 30 is rotated or the whole water gate 30 is configured to be pulled upward.

In this configuration, the drainage side sluice 30 remains open at all times and rotates the first and second driving motors 106c and 106d that drive the reservoir sluice 30 in opposite directions. When the first winding roll (283a) and the second winding roll (283b) is rotated in the opposite direction to each winding the operation cable (284a) (284b), the water reservoir side (30) is rotated while the waterway (11) Space is generated between the water gate 30 and the bottom of the housing 20 so that the lower floor water of the reservoir is discharged through the space, and foreign substances such as sedimentary sludge deposited on the bottom of the river fall out together with the river water. It is possible to purify contaminated water by mass acceleration, mass cutting, material releasing, and material flotation. Of course, in this state, it is apparent that the cylinders 15 stretching and contracting each wedge 16 are all elongated so that each wedge 16 is rotatably supporting the rotation shaft 33 of the reservoir side lock 30. .

In this state, when the water reservoir 30 is broken down to be repaired or to be replaced due to aging, all the cylinders 15 stretching and contracting the wedges 16 are contracted so that the rotating shaft 33 is free. The drainage side gate 30 is left open or the respective driving motors 106c and 106d for driving the drainage side gate 30 are driven to make the drainage side gate 30 closed and then the drainage side gate 30 Drive motors (106c) and (106d) to drive the drive cable (284a) (284b) simultaneously to each winding roll (283a) (283b) at the same time to the drive cable winding direction, The whole will rise along the guide groove 14 to be able to easily replace and repair the water gate (30), from this time the drain side water gate 30 opens or closes the waterway (11), while acting as a main water gate while discharged to the bottom To do.

On the contrary, when the drain side gate 30 is to be repaired and replaced, the reservoir side gate 30 may serve as the main gate and the drain side gate 30 may be raised.

That is, according to the forty-eighth embodiment of the present invention, the waterway 11 is opened and closed while forward and backward rotation of the water gate 30 through the respective operation cables 284a and 284b, or between the water gate 30 and the housing 20. It can serve as a basic water gate 30 to purify the water quality while discharging the bottom water of the reservoir, as well as raise the water gate 30 to the upper portion of the support structure 10 for the convenience of repair and replacement. In addition, since the gate 30 of the structure as described above is spaced apart in two sets, when one of the two gates 30 is broken and repaired or replaced, the other gate 30 is not included in each embodiment of the present invention. Since it can play a role as a sluice according to that there is an advantage that the normal operation of the sluice 30 can be made while repairing or replacing the sluice 30.

And, the control of each of the sluice gate 30 according to the 48th embodiment of the present invention is preferably to be automatically performed by the integrated control system 100, it is natural that the administrator can be manually operated.

In addition, in the forty-eighth embodiment of the present invention, the rotational operation or towing of the water gate 30 by the drive motors 106c and 106d, the winding rolls 283a and 283b, and the operation cables 284a and 284b is performed. As an example, but a cylinder may be applied instead of such a device, it is obvious that such modified embodiment also falls within the scope of the present invention.

In addition, in the forty-eighth embodiment of the present invention, each of the gates 30 is arranged to have a step, but each gate 30 may be installed in a horizontal direction, and thus, such a modified embodiment may also be used. It is natural to fall within the scope of rights.

[Example 49]

FIG. 144 is a side cross-sectional view of the rotating gate according to the forty-ninth embodiment of the present invention, and FIG. 145 is a side cross-sectional view of raising the one side rotating gate of the rotary gate according to the forty-ninth embodiment of the present invention;

As shown, the forty-ninth embodiment of the present invention is a rotary water gate applied to the small-scale underwater beams upstream of a large dam. In the case of a large dam, the size of the storage space becomes very large, so that when the water gate 30 is normally closed, The greater the probability that foreign substances such as sludge accumulate in the lower layer, so that the 49th embodiment of the present invention to minimize the water pollution by continuously discharging the lower layer of the storage space even when the large dam is closed.

To this end, a channel 301 is formed in the horizontal direction in the lower portion of the dam structure 300 to communicate with the reservoir and the discharge portion, and the guide space 302 allows the channel 301 and the upper portion of the dam structure 300 to communicate with each other. And inserting the hydrologic structure 310 into the guide space 302 in such a manner as to be removable, and the elevating means for selectively raising and lowering the hydrologic structure 310 at the upper portion of the dam structure 300.

At this time, the sluice structure 310, the sluice 30 is configured to be rotatable by an operating means (not shown) such as a cylinder inside the rectangular housing 311 configured to pass through the front and rear, the sluice 30 ) Is formed in a shape in which both side plates 32 are integrally formed at both ends of the arc-shaped sluice plate 31 at right angles, and the rotation shafts 33 are fixed to the upper sides of the both side plates 32 in the outward direction. The bottom of 311 is a step 312 formed in a downward direction so as not to interfere with the rotational motion of the water gate 30, and the step 303 also matches the step 312 of the housing 311 in the channel 301. ) Is formed so that foreign substances are not caught during the discharge of water.

In addition, the lifting means according to the forty-ninth embodiment of the present invention may be configured in various ways, such as a winch 320 having a lifting cable 321, a cylinder, a screw, etc., the lifting device having a lifting cable 321 as a lifting means in the drawing An example in which 320 is applied is shown.

In addition, even when the water gate 30 is broken and repaired or replaced, it may be provided with two or more sets of the above-described water gate structure 310 to maintain the operation as the water gate 30, in this case the dam structure 300 Steps 303 formed at two or more guide spaces 302 formed in the housing to accommodate the hydrologic structure 310 to be lowered, respectively, and formed in the waterway 301 according to the position of each hydrologic structure 310. It can be formed in multiple stages. In the drawings, the hydrological structure 310 is provided with two sets as an example.

In this configuration, the at least one hydrologic structure 310 is positioned in the channel 301 and rotates by the operation means to open and close the channel 301 to serve as a gate, as well as the housing 311 and the gate 30. By forming a space between the sluice plate 31 of the discharge and discharge the lower layer water of the reservoir through these spaces, foreign substances such as sedimentation sludge deposited on the bottom of the river to escape like the river water, material acceleration action, material cutting phenomenon, It is possible to purify the contaminated water quality by the substance removal action and the material floating action.

If it is necessary to replace the hydrologic structure 310 in the waterway 301 if a failure occurs or the parts are worn out while performing the role as the hydrological gate, the hydrologic structure may be operated as described above. 310 is to be lifted to the upper portion of the dam structure 300 by the winch 320 can be easily repaired and replaced the hydrological structure (310).

That is, according to the forty-ninth embodiment of the present invention, the small waterway 301 formed in the large dam can be opened and closed through the water gate 30 to maintain the water quality of the wide reservoir space clean, and perform the above operation. The hydrologic structure 310 can be towed to the upper portion of the dam structure 300 to facilitate the convenience of hydraulic replacement, and at least two hydrologic structure 310 is provided so that the hydraulic replacement of the hydrologic structure 310 is performed. When the other hydrologic structure 310 can continue to play a role as a hydrology, there is an advantage that the normal operation of the hydrology can be made.

In addition, although the control of each of the gates 30 according to the forty-ninth embodiment of the present invention is preferably performed automatically by the integrated control system 100, it is natural that an administrator may manually operate the gate.

In addition, in the forty-ninth embodiment of the present invention, the lifting and lowering of the hydrologic structure 310 by the winch 320 is an example, but instead of such a device, a screw or a cylinder may be applied. It is natural to belong to.

In addition, in the forty-ninth embodiment of the present invention, each of the hydrological structures 310 is arranged to have a step, but each of the hydrological structures 310 may be installed in a horizontal direction, and thus, the modified embodiment may also be viewed. Naturally, it belongs to the scope of the invention.

In addition, although the operation means for driving the water gate 30 is not shown, it is obvious that any one can be applied as long as it can rotate the water gate 30 such as a cylinder and a motor.

50th Example

146 is a view illustrating an installation state of a rotating gate according to a fifty embodiment of the present invention, and FIG. 147 is a detailed sectional view of a connection portion of the rotating gate according to a fifty embodiment of the present invention.

"형상의 지지구조체(10)를 축조하고, 지지구조체(10)의 안쪽에는 수직방향으로 다수의 지지판(330)을 고정하여 지지구조체(10)와 지지판(330) 또는 각 지지판(330)의 사이에 수로(11)를 형성하며, 지지구조체(10)와 지지판(330) 또는 각 지지판(330)의 사이에는 각각 회전축(112)을 고정하고, 각 회전축(112)에는 수문(230)을 회전가능하게 각각 설치하되, 수문(230)은 호형의 수문판(231) 양단부에 직각방향으로 양측판(232)이 일체로 형성된 형상으로 구성하면서 양측판(232)의 내부에 공간부(232a)가 형성되도록 하여 양측판(232)의 상부에 회전축(112)이 회전가능하게 삽입되도록 하고, 회전축(112)의 양측판 공간부 위치로부터 작동링크(116)를 각각 인출하여 양측판(232)의 공간부(232a) 일측과 이 작동링크(226)의 사이에 작동실린더(113)를 각각 회전가능하게 연결하여 구성한 것이다. 도면상에는 수문(230)이 3조 구성된 것을 예로 하여 도시하였다.As shown, the fifty-fifth embodiment of the present invention is for installing a plurality of sets of rotating gates in a place having a large width of a river without a support structure in the middle.

"Building the support structure 10 of the shape, and fixed to the plurality of support plates 330 in the vertical direction inside the support structure 10 between the support structure 10 and the support plate 330 or each support plate 330 The water channel 11 is formed in the support structure 10 and the support plate 330 or between the support plate 330, respectively, the rotating shaft 112 is fixed, and each rotating shaft 112 is rotatable gate 230 is rotatable. Although each is installed so as to, the water gate 230 is formed in the shape of the two-side plate 232 integrally formed at both ends of the arc-shaped hydrology plate 231 in a direction perpendicular to the inside of the both sides plate 232 is formed The rotary shaft 112 is rotatably inserted into the upper side of the two side plates 232, and the operation link 116 is drawn out from the position of the two side plate space portions of the rotary shaft 112, respectively, to the space portion of the both side plates 232. (232a) It is configured by rotatably connecting the operation cylinder 113 between one side and the operation link 226, respectively. Reference On the water gate 230 is illustrated by an example that is configured 3 trillion.

At this time, the installation site and the number of the operation link 116 and the operation cylinder 113 is not particularly limited, and in the drawings, the operation link 116 and the operation cylinder 113 are illustrated as an example configured one by one.

In addition, although not shown, the packing member may be prevented from leaking between the side plates 232 of the water gate 230 and the support structure 10, and between the side plates 232 of the water gate 230 and the rotation shaft 112. It is obvious that is provided.

In the state configured as described above, the water gate 230 opens and closes the waterways 11 while the water gate 230 rotates forward and backward according to the expansion and contraction of the operation cylinder 113, or the bottom portion of the support structure 10 and the water gate plate 231 of the water gate 230. By forming a space between them and draining the lower layer of the reservoir through these spaces, foreign substances such as sedimentation sludge deposited on the bottom of the stream can escape like river water, causing material acceleration, material scavenging, material release, and material injury. By action, the contaminated water quality can be purified.

That is, the rotational gate according to the 50th embodiment of the present invention, even if the width of the river is large, so the water gate 230 is formed over the entire width of the shear surface of the river, so that the water gate 230 is opened to discharge the water of the reservoir space at once. It is possible to prevent the condensation of light pollutants in the upper layer of the reservoir to agglomerate with each other, and as the lower layer of the reservoir passes into the space between the water gate 230 and the bottom of the support structure 10, Since the foreign substances such as sewage sludge at the bottom of the river are discharged at once, the water quality of the river can be greatly improved.

In addition, each of the sluice gate 230 can be operated individually or simultaneously depending on the water level of the reservoir or the inflow speed of the water is more convenient to control the water level of the reservoir, concrete such as the support structure 10 in the middle of the river It is possible to install several sets of gates without constructing the structure, thereby saving the cost and time required to build the support structure 10, and the width of the gate gate 230 compared to when constructing the support structure 10 in the middle of the river. It can be implemented relatively large will be easier to adjust the water level.

In addition, the support plate 330 applied to the fifty embodiment of the present invention may be made of various materials such as a plate made of metal, a concrete structure, a synthetic resin plate, and the support plate 330 of the support structure 10. When constructing, the insert may be inserted into the bottom part at a time, and the support plate 330 may be fixed in a later process after the support structure 10 is constructed. The material of the support plate 330 may be changed or the support plate 330 may be fixed. Even if the method of fixing) is changed, it is natural that all of these things fall within the scope of the present invention.

In addition, although not shown in the drawings it may be configured to cover the housing of the support structure 10 and the support plate 330 by a separate housing, such a slight structural change is also within the scope of the present invention.

In addition, the plurality of sets of gates 230 according to the fifty embodiment of the present invention may be automatically controlled by a comprehensive control system, or may be manually controlled, respectively, and the driving method of the gates 230 may also vary. Can be implemented.

[Example 51]

148 is a configuration diagram of a hydrological drive system according to a fifty-first embodiment of the present invention.

Sluice applied to the fifty-ninth embodiment of the present invention can be applied to any kind of water gate as long as the gate to open and close the waterway according to the expansion of the hydraulic cylinder, such as conductive hydro, floating hydro, conductive and floating hydrology Among them, it is shown as an example that the rotation gate according to the third embodiment of the present invention is applied.

Rotational water door to which the present invention is applied, the waterway 11 is formed between the two support structures 10, the housing 20 is covered with the opposite surface of the both support structures 10, respectively, arc-shaped fingerprint plate ( 31) Both side plates 32 are fixed to the both ends at right angles, and a water gate 30 having a shape in which the rotating shaft 33 is fixed is provided at the upper side of the both side plates 32, and the rotating shaft 33 is connected to the housing 20. It penetrates and is rotatably fixed to the support structure 10.

In addition, a space portion 12 is formed inside the support structure 10, and a rear end portion of the operation cylinder 51 made of a hydraulic cylinder is rotatably fixed to one wall surface of the space portion 12, and the rotation shaft 33 The operating link 34 is fixed to the space portion of the cylinder, and the tip of the piston rod 56 of the operating cylinder 51 is rotatably connected to the projection 34a of the operating link 34 so that the operating cylinder 51 The water gate 30 is configured to open and close the water channel 11 while being rotated about the rotation shaft 33 according to the expansion and contraction.

The sluice driving system for driving such a sluice includes a photovoltaic power generation unit 260 having a solar panel 261, a charging circuit 262 for charging electricity generated through the photovoltaic power generation unit 260, and a charging circuit ( The water level sensor 263 which receives the electricity collected in 262 and measures the water level, and the power is supplied from the charging circuit 262, and the operation cylinder 51 is expanded and contracted according to the detection signal of the water level sensor 263 so that the water gate 30 Hydraulic unit 264 for controlling the opening and closing of the control unit, and a central control unit 265 for controlling all components.

In addition, the hydraulic unit 264 includes an oil pump 266 for pumping oil collected in an oil tank (not shown), an engine 267 for driving the oil pump 266, an inlet pipe and various valves (not shown). The engine 267 is configured to be driven using petroleum fuel, and a starting motor 268 for driving the engine 267 is connected to the engine 267.

In this configuration, when the solar light is collected through the solar panel 261 and the power is generated through the photovoltaic unit 260, the electricity is charged through the charging circuit 262 and collected in the charging circuit 262. Electricity is supplied to the hydraulic unit 264 and the water level sensor 263.

At this time, the solar panel 261 of the photovoltaic unit 260 may be configured in the roof of the control box or the management room of the water gate 30, or may be installed in the pagora roof of the park formed around the water gate 30, In this way, the solar panel 261 can be used as a roof of the facility.

In addition, the photovoltaic power generation unit 260 is provided separately at the place where the water gate 30 is installed to cover the power itself, the water level sensor 263 applied to the present invention is a water level such as electrode type water level sensor Any type of sensor can be used as long as it can be detected.

When power is applied to the water level sensor 263 and the water level is detected through the water level sensor 263, the signal is transmitted to the central control unit 265, and the central control unit 265 receives the signal transmitted through the water level sensor 263. The hydraulic unit 264 receives a signal to read and to open or close the gate 30 according to its position.

Since the hydraulic unit 264 is in a state where power is applied from the charging circuit 262, when the signal for opening the water gate 30 is received through the central control unit 265, the hydraulic unit 264 drives the starting motor 269, and the starting motor When the engine 267 is driven and the hydraulic pump 266 is operated according to the driving of the engine 268, oil is supplied to the operation cylinder 51 connected to the water gate 30 to rotate in the direction of opening the water gate 30. It will let you.

In addition, when a certain amount of time elapses while the water gate 30 is opened, and a signal indicating that the water level is appropriate through the water level sensor 263 is transmitted to the central control unit 265, the hydraulic unit may be operated according to the command of the central control unit 265. In 264, the operation cylinder 51 is operated in the opposite direction to the opening of the water gate 30 so that the water gate 30 can be closed by rotating the water gate 30 in the opposite direction to the opening.

Therefore, according to the fifty-first embodiment of the present invention, since it is possible to supply power by itself through photovoltaic power generation, there is no need for a separate power, and stable opening / closing operation of the gate is always performed 365 days regardless of weather conditions. It will be able to continuously clean the polluted river water.

52nd Example

Figure 149 is a front sectional view of a rotating gate according to a 52nd embodiment of the present invention, Figure 150 is a side cross-sectional view when opening the rotating gate according to a 52nd embodiment of the present invention, Figure 151 is a 52nd embodiment of the present invention Figure 152 is a side cross-sectional view at the time of discharging the bottom of the rotating gate according to the 52nd embodiment of the present invention, Figure 153 is a cylinder connection of the rotating gate according to the 52nd embodiment of the present invention Structure One embodiment is an illustration, Figure 154 is another embodiment of the cylinder connection structure of a rotating gate according to a 52nd embodiment of the present invention.

As shown in the drawing, the waterway 11 is formed between the two support structures 10, and the housing 20 is provided on the opposite surface of the support structure 10. Covered with each, both sides of the arcuate sluice plate 31 is fixed to both sides in a direction perpendicular to the both sides of the plate 32 and the upper side of the two plate 32 is provided with a sluice 30 formed with fitting grooves (32b), respectively, both support structures Each fitting groove 32b is fitted to each of the fixed shafts 233 fixed to 10 so as to be rotatably installed.

At this time, the two side plates 32 of the sluice 30 may be configured in an arc shape, may be configured in a straight shape, it is shown in the drawings that the two side plates 32 are formed in a straight shape as an example.

In addition, a space portion 12 is formed inside each of the supporting structures 10, and on one side of each of the space portions 12, an operation means for pushing and closing the water gate 30 in an open state is located, and an opposite space is provided. In the part 12, the operation means for pushing and opening the water gate 30 in the closed state is located, respectively, each such operation means is configured as follows.

The rotary shafts 401, 401 'are rotatably installed by the support 402, 402 at positions different from the fixed shaft installation positions of the spaces 12, respectively. The tip portion extends to a position outside the housing 20, and the operation links 403 and 403 'are fixed to the space positions of the respective rotary shafts 401 and 401', and the respective rotary shafts 401 and 401 '. In the housing outer position of the water gate 30 is located opposite the side plates 32, the rotation of each rotation shaft 401 (401 ') to slide the water door 30 in the closed or open direction, respectively, to rotate Fixing operation rods 404 and 404 'having different lengths, respectively, and fixing the operation cylinders 405 and 405' to one side wall of each space 12, each operation cylinder 405 and 405 '. The piston rods 406, 406 'of the end portions are connected to push each of the actuating links 403, 403' to actuate the actuating links 403, 403 'according to the expansion and contraction of each actuating cylinder 405, 405'. Rotate by 401 is configured (401 ') and a working rod (404) (404') so that this is rotated.

At this time, it is natural that the positions of each of the rotation shafts 401 and 401 'should be located on opposite sides with respect to both side plates 32 of the water gate 30, and each of the rotation shafts 401 and 401' is opposite to each other. As it is positioned, the operating links 403, 403 ', the operating rods 404, 404', and the working cylinders 405, 405 'connected to each other are also located on opposite sides, and the water gate 30 is closed. The pushing rod 404 should have a longer length than the pushing rod 404 'which pushes the water gate 30 in the opening direction, and the rotary shafts 401 and 401' are positioned lower than the fixed shaft 233. If the operating rods 404, 404 'can be any straight or rounded shape, but if the position of the rotary shaft 401, 401' is located above the fixed shaft 233 The operating rods 404 and 404 'are formed to be round so as not to interfere with the fixed shaft 233.

In the drawings, the respective operating means positioned in the space parts 12 opposite to each other are shown in one drawing for convenience of description, and the operating rods 404 and 404 'are illustrated in an example in a round shape.

Of course, the connection structure of the actuating cylinders 405, 405 'and the actuating links 403, 403' can be modified in any number of ways, for example, the actuating cylinders 405, 405 'are rotatable. It is also possible to rotatably connect the tip of the piston rods 406, 406 'of the actuating cylinders 405, 405' and the actuating links 403, 403 ', and actuating cylinders 405, 405'. To the end of the piston rods 406 and 406 'of the working cylinders 405 and 405' by fixing them by fixing plates 407 and 407 '. ') May be rotatably provided such that the guide rollers 408, 408' are in contact with the actuating links 403, 403 '.

Reference numeral 38 in the drawing represents a support for supporting the fixed shaft 233.

When the operation cylinder 405 of the one side space 12 is extended in the state in which the rotating gate configured as described above is extended, the operation link 403 is rotated while being pushed by the piston rod 406, and the operation link 403 is fixed. The rotating shaft 401 is rotated, and the operating rod 404 fixed to a position outside the housing of the rotating shaft 401 is rotated according to the rotation of the rotating shaft 401.

When the operating rod 404 is rotated, both side plates 32 of the water gate 30 in contact with the operating rod 404 are pushed, and the water gate 30 is rotated about the fixed shaft 233, and the water gate 30 As the operation cylinder 405 'is contracted in the opposite space 12 as the rotation of the operation link 403' rotates in a direction opposite to the operation link 403 of the one space 12, the rotating shaft 401 '. In addition, the operating rod 404 'is also rotated in the opposite direction so as not to interfere with the rotation of the water gate (30).

When the operating rod 404 is continuously rotated so that the water gate 30 is rotated at an angle of 90 ° in the first open state, the height of the water gate 30 is maximized to become a completely closed state, and the water in the reservoir space is discharged to the outside. You can't go out and stay in the reservoir.

However, if the water stays in the reservoir continuously, it causes contaminants to be accumulated by the massing action to generate foreign substances such as sludge, so it is desirable to discharge the lower layer water in the reservoir intermittently or periodically.

To this end, when the working cylinder 405 is extended as much as possible, such a linear motion is converted into a rotary motion through the operation link 403, the rotating shaft 401, and the operating rod 404 to rotate the water gate 30 by 90 ° or more. When the water gate 30 is rotated by 90 ° or more, a space is generated between the water gate plate 32 of the water gate 30 and the bottom of the housing 20, and the lower water of the reservoir space is discharged through the space to the bottom of the river. It is possible to purify the contaminated water quality by material acceleration, material scavenging, material desorption and material flotation while leaving foreign substances such as sedimentation sludge that have been deposited like river water.

In this state, when the operation cylinder 405 'of the opposite side space 12 is extended, the operation link 403' is rotated in the direction of opening the water gate 30 while the rotating shaft 401 'and the operating rod are rotated by the rotational force. 404 'is rotated, and the water gate 30 is rotated in a direction opposite to that of closing due to the pressure and self-weight transmitted from the operating rod 404', and the operating cylinder 405 of the opposite space 12 While being contracted, the operation link 403, the rotation shaft 401, the operation rod 404 are rotated in the opposite direction as when closed, so as not to interfere with the opening operation of the water gate 30.

When the water gate 30 is continuously rotated by the pressure of the operation cylinder 405 'and the weight of the water gate 30, and the upper end of the water gate plate 31 of the water gate 30 becomes horizontal, the water gate 30 is completely opened. As a result, the water in the reservoir space is quickly discharged to the upper portion of the sluice plate 31 so that the water level can be stabilized in a short time.

That is, in the rotary gate according to the fifty-second embodiment of the present invention, since the operation cylinders 405 and 405 ′ forming the power means are housed in the enclosed space 12 formed in the support structure 10, the water and operation cylinder 405, 405 'is not in contact with each other to improve the reliability of the operation, and the water gate (404, 404') through the operating rods 404, 404 'is not directly connected to the power means Since the water gate 30 is rotated by directly pushing both side plates 32 of 30), in case of failure of the power means, the water gate 30 can be dismantled and repaired while leaving the water gate 30 intact, which is advantageous for maintenance. In addition, since the fixed shaft 233 is inserted into the fitting groove 32b formed on both side plates 32 of the sluice gate 30 when dismantling the sluice gate 30, when the fixed shaft 233 is pulled out backward, the sluice ( The dismantling of 30) is very simple.

And, in the 52nd embodiment of the present invention can be configured to operate the water gate using the structure of the cam of the circular or oval instead of the operating rods (404, 404 '), such a modified embodiment is the scope of the present invention It is natural to belong to

In addition, those skilled in the art can change the size and shape of the operating rods (404, 404 ') freely, or even to adjust the installation position of the operating rods can be produced to operate the gate, so this design change is also the scope of the present invention It is natural to belong to.

53rd Embodiment

155 is a detailed cross-sectional view of a rotating door according to a fifty-seventh embodiment of the present invention.

The rotating water gate is configured such that the lower surface of the rounded sluice plate 31 slides on the rounded portion of the housing 20, and a packing member is disposed on the lower end of the drain side of the sluice plate 31 based on the opening of the water gate 30. When the 409 is fixed and the water gate 30 is closed, a leak occurs between the water gate 30 and the housing 20 by placing the packing member 409 between the water gate plate 31 and the bottom of the housing 20. Since it is impossible to prevent the packing member 409 to move along the rounded surface of the housing 20, the water gate 30 is slightly lifted from the housing 20 to be installed.

Therefore, when the water gate 30 is opened, a slight gap G may be generated between the water gate plate 31 and the housing 20, and foreign matter contained in the water may be discharged from the water gate 30 and the housing. Inflow into the gap (G) between (20) occurred a problem that hinders the rotation of the water gate (30).

Therefore, in the fifty-fifth embodiment of the present invention, foreign matter does not flow between the bottom of the housing 20 and the water gate 30 when the water gate 30 is opened, and the water gate plate based on the water gate 30 is opened. The stopper 410 is integrally formed at the reservoir side end portion 31 in the horizontal direction toward the reservoir side.

When configured in this way, the closing operation of the water gate 30 is made in the same way as a general rotating water gate, and when the water gate 30 is opened, the water stop plate 31 gradually moves to the bottom of the housing 20, and the stopper 410. ) Is hooked to the bottom of the housing 20, after which the water gate 30 is no longer rotated.

In addition, when the rotation of the water gate 30 is stopped by the stopper 410, the top surface of the water gate plate 31 is horizontal, so that the water gate 30 is completely opened, and the water gate plate is stopped by the stopper 410. Since the gap between the 410 and the housing 20 is also blocked, foreign matter is not discharged into the gap G between the water gate 30 and the housing 20 and is discharged as it is.

That is, according to the fifty-fifth embodiment of the present invention, the rotational operation of the water gate 30 is not disturbed at all and the water gate 30 and the housing 20 are stopped by the stopper 410 at the time when the opening of the water gate 30 is completed. Since it prevents the gap (G) between the foreign matter does not flow between the sluice 30 and the housing 20 will be able to improve the reliability of the rotation operation of the sluice (30).

And the fifty-fifth embodiment of the present invention is naturally applicable to any rotation door.

54th Example

156 is a schematic diagram of a water gate according to a fifty-fourth embodiment of the present invention.

As shown, the fifty-fourth embodiment of the present invention is to install a multi-stage sluice of different lengths in accordance with the height difference between the bottom of the river or the river and the water surface when installing the water gate in a wide river or river In the fifty-fourth embodiment of the present invention, all the rotating gates according to the first to fifty-fifth embodiments are applicable.

When installing water gates in wide rivers or rivers, only one water gate is limited in the amount of drainage, and several water gates are installed side by side. Looking at the cross-sections of rivers or rivers, the height between the water surface and the bottom gradually increases toward the river or river side. In order to apply the same height to the multi-stage sluice gates, it is necessary to dig the ground near the riverside or riverside so that it is horizontal to the central bottom of a wide river or river. I had to.

Therefore, when the water gate is installed in multiple stages in a wide river or river, a long construction period is required, and each water gate must be composed of a large size.

The 54th embodiment of the present invention has been proposed in view of the above points, and each support structure 10 is constructed by constructing concrete support structures 10 and 210 at the bottom of a wide river or river according to the curvature thereof. The upper end of the 210 is configured to be gradually lowered toward the center, and each of the support structures 10 and 210 having different heights from the surface of the water gates 30 and 230 are installed, respectively, each of the gates 30 At the closing of the 230, the heights of the respective gates 30 and 230 are configured to gradually increase toward the center so that all of the upper ends thereof coincide with the surface of the water.

The hidden line on the drawing shows the original bottom position of the river or river.

In this configuration, the water level of the reservoir can be properly maintained while opening and closing the respective gates 30 and 230, as well as between the gates 30 and 230 and the support structures 10 and 210. By discharging the subsurface water, foreign substances such as sedimentation sludge deposited on the bottom of the stream can be discharged along with the river water, thereby purifying the water quality contaminated by the acceleration of the material, the scavenging phenomenon, the material desorption, and the material floating action. When installing a plurality of water gates (30, 230) side by side in a wide river or river, the foundation work is carried out as it is without digging the bottom near the river or river side to level the water gates (30, 230) It is possible to significantly reduce the construction period, and because the height of the water gate (30) (230) is gradually lowered toward the river or river side has the advantage that can significantly reduce the equipment cost A.

55th Example

157 is a configuration diagram of a multi-stage floodgate applied to a fifty-fifth embodiment of the present invention.

The fifty-fifth embodiment of the present invention installs the sluice gates 30 and 230 in multiple stages on a sloped river to expand the reservoir and at the same time the water discharged through the sluice gates 30 and 230 of the stage, and the midnight water itself. It is to purify the clean water to remove the pollutants completely by the action and the teenage natural purification action.

To this end, by installing the rotary water gates 30 and 230 in multiple stages in rivers or rivers having a slope, the storage space 1000 is configured in multiple stages, and the rotary water gate 30 applied to the 55th embodiment of the present invention ( 230 is applicable to all the rotating gates of any structure according to the 54th embodiment in the first embodiment, the installation of the water gates 30, 230 is 5 to 10 places in consideration of the length and slope of the river or river It is preferable to install continuously.

In addition, the installation intervals of the water gates 30 and 230 are not particularly limited, but it is natural that at least the water gap should maintain a space where no back flow occurs to the adjacent water gates 30 and 230 when the reservoir space is full.

In this configuration, when the respective reservoir spaces 1000 formed through the rotary water gates 30 and 230 are all filled by the inflow water flowing from the upstream of the river, the rotary water gates 30 and 230 are upward. By using the method of forcibly rotating to discharge the amount of water flowing from the upstream of the river, the clean water with heavy gravity pushes out the polluted water with light gravity according to the action of gravity and specific gravity and moves to the other reservoir space 1000 adjacent to the downstream side. At the same time, the pollutants with light specific gravity contained in the water are drained into the clear water with heavy gravity according to the law of mass jungle, material stripping, mass cutting and material preservation instinct. Forced movement to the upper side of) will naturally purify the contaminated water.

In addition, contaminated water having a light weight in the upper layer of the stored water stored in the storage space 1000 is naturally purified by microorganisms generated in the storage space 1000, and penetrates into the material to contaminate the contaminants. Natural purification by osmotic action to destroy and decompose the structure, and pollutants combined with clean water molecules are combined with water molecules by the material friction action between water molecules and pollutants. Self-cleaning, which purifies the contaminated water into clean water by natural friction, which destroys and breaks down the molecular structures of the pollutants present, natural cleansing by solar heat, and mixed in clean water from the upstream of the river. Purification of contaminated water quality by dilution with dissolved oxygen is carried out in accordance with the installation steps of the rotary water gates 30 and 230. That is to to occur naturally in the interior of each of the water storage space (1000).

That is, according to the fifty-fifth embodiment of the present invention, no matter how contaminated water may be clean water finally removed contaminants while passing through the multi-level water gates 30 and 230 and the reservoir space 1000. It will be able to completely purify the water just by passing through the water gate 30 (230) of the multi-stage without the addition of special chemicals.

In addition, the water flowing through the river or river as it can be fresh water in the storage space of the place where the sluice (30, 230) is installed, so that the fresh water can be increased, and the fresh water in each of these storage spaces for agricultural water, There is an advantage that can be utilized as industrial water, drinking water.

56th Example

FIG. 158 is a cross-sectional view of the revolving door according to the 56th embodiment of the present invention, and FIG. 159 is a cross-sectional view of the revolving door according to the 56th embodiment of the present invention.

As shown, the fifty-eighth embodiment of the present invention is to remove it only by the rotation operation of the rotary door when foreign matter is stuck to the bottom of the support structure on which the rotary door is driven. The rotational doors according to the first to the fifty-fifth embodiments of the present invention can be applied to all of them, and the drawings for the specific power means for rotating the water gate are omitted.

Typically, when constructing a rotating gate, the support structures 10 and 210 are rounded to correspond to the rotation radius of the gate 30 and 230. When the size of the rotating gate is large, the supporting structure 10 The company building the 210 and the company manufacturing and installing the rotating gate are selected as separate companies, so the company constructing the supporting structure 10 or 210 supports the structure according to the conduction or floating hydrology. ) 210 will be constructed first, and the support structure (10) (210) of this structure will be installed later in another company to rotate the rotational doors so that the bottom surface of the support structure (10) (210) to form a horizontal gate (30) There is no choice but to install the rotating gate after digging round as much as the radius of rotation of 230.

In addition, the curvature of the lower surface of the sluice plate (31) (231) of the sluice (30) (230) is preferably centered around the rotation axis (33) or the fixed shaft (233), if it is configured as such a sluice plate ( 31) The thickness of the 231 is too thick, so the sluice (30) 230 is more heavy than necessary, excessive energy is required to drive it, there is a problem that the manufacturing cost is high, so the sluice (30) (230) In the manufacture of the sluice plate (31) (231) of the curvature is configured to be larger than the rounded portion of the support structure (10) (210).

In addition, opening of the water gates 30 and 230 to prevent leakage between the rounded portions of the support structures 10 and 210 and the water gates 30 and 230 when the water gates 30 and 230 are closed. When the sluice plates 31 and 231 of the sluice gates 30 and 230 are installed on the basis of the poem, the packing member 409 is installed at the drain side side. In order not to interfere with the gates 30 and 230 and the support structure 10, the rounded portion of the 210 is slightly spaced apart.

Therefore, for the same reason as above, a space such as a bowl may be generated in the rounded portions of the support structures 10 and 210, as well as the water gates 30 and 230 and the support structure when the water gates 30 and 230 are opened. There was a problem that foreign matter enters the gap between the rounded portions of the (10) (210) and accumulates in the rounded space of the support structure (10) (210), thus preventing the rotation of the water gates (30) (230).

In the fifty-eighth embodiment of the present invention, even if foreign matter is introduced into the rounded portion of the support structure (10) (210), it is removed so that it does not interfere with the rotation operation of the sluice (30) (230). On the basis of the opening time of the 230, the water pads 31 and 231 of the water gates 30 and 230 extend to the rounded portions of the support structures 10 and 210 adjacent to the packing member 409. The foreign matter removal plate 411 is fixed.

At this time, the foreign material removing plate 411 is preferably made of a material such as stainless steel having elasticity and corrosion resistance, any other material can be applied as long as it has the equivalent properties and performance.

In addition, the foreign material removing plate 411 may be configured in a cross-section "a" shape or "tt" shape, and the like, the installation position is located on the water storage side rather than the packing member 409 so that the water gate (30) (230) ) When the foreign matter removal plate 411 is rotated to the upper side of the support structure (10, 210) at the closing of the support structure (10) (210) accumulated foreign matter accumulated in the rounded space of the support structure (10, 210) It can be configured to be removed outside of).

When the reservoir space formed through the sluice gates 30 and 230 in the state configured as described above becomes the full water level by the inflow water flowing from the upstream of the river, the sluice gates 30 and 230 are rotated upward by the power means, so that the sluice gate ( By forming a space between the bottom of the 30 and 230 and the bottom of the support structure 10 and 210 to discharge the amount of water flowing from the upstream of the stream to the lower end of the sluice 30, 230, the heavy clean The water is discharged by pushing the polluted water with light specific gravity according to the action of gravity and specific gravity, and the light pollutants contained in the water have specific gravity according to the law of material jungle, material release, material cutting and material preservation instinct. Pushed by these heavy clean waters, they are forced to the upper side of the water to naturally purify the contaminated water.

At the same time, the polluted waters that are stagnant in the upper part of the storage water stored in the reservoir are naturally purified by microorganisms generated in the reservoir, and penetrate into the material to destroy and destroy the pollutant structure. Natural purification by the osmotic action, by the destruction of the pollutant structure by the action of material friction caused by the collision of material molecules and material molecules, and by the heat of the sun. Purification and the purification of contaminated water by dilution with dissolved oxygen mixed in clean water from the upstream of the river occur naturally inside the reservoir.

In addition, when the water level rapidly blows, such as flooding, it is very important to discharge the water in the reservoir space in a short time to maintain a stable water level. In this case, the water gates 30 and 230 are operated by operating the power means in the opposite direction. It rotates in the opposite direction as when closed, and then the upper surface of the sluice plates 31 and 231 of the sluices 30 and 230 and the bottom of the support structure 10 and 210 are horizontal to store the water in the reservoir space. It can be discharged in a short time to maintain a stable water level.

However, as described above, when the water gates 30 and 230 are opened, foreign substances such as sand and gravel through a gap between the water gates 30 and 230 and the rounded portions of the support structures 10 and 210. This foreign matter is accumulated in the rounded space of the support structure (10, 210) to increase the contamination, as well as to interfere with the rotation operation of the water gate (30, 230) as described above.

In accordance with the fifty-eighth embodiment of the present invention, the sealing member 409 is adjacent to the drainage side of the sluice plates 31 and 231 on the basis of the opening time of the sluice 30 and 230. The foreign matter removing plate 411 that is fixed to the rounded portion of the support structure (10, 210) to the fixed installation, this foreign matter removing plate 411 is the support structure 10 when the water gate (30) 230 is closed Since it is installed in a position that can be rotated to the upper space position of the 210, when the water gates 30 and 230 are rotated in a closed direction in the open state, the lower surface portions of the water gate plates 31 and 231 The fixed foreign matter removing plate 411 is rotated as if it sweeps while slidingly contacting the bottom of the rounded space while being in close contact with the bottom surface of the rounded space of the support structures 10 and 210. Foreign matter introduced into the rounded space of the) can be discharged to the outside of the support structure (10,210).

Therefore, foreign matters are automatically removed when the water gates 30 and 230 are rotated in the closing direction so that the rotation of the water gates 30 and 230 by foreign matters does not occur at all. It may be discharged together with water at the bottom of the stream or at the time of discharge or opening the bottom of the water gate (30) (230). In addition, the fine foreign matter is not floating in the rounded space of the support structure (10, 210) by the hydraulic pressure or water flow is floating down with the discharged water.

That is, according to the fifty-eighth embodiment of the present invention, the bottom portion of the support structure (10, 210) for supporting the sluice (30, 230) is made horizontal, the bottom portion of the sluice (30, 230) Even if only a rounded space corresponding to the rotation radius is formed, it does not interfere with the rotation operation of the water gates 30 and 230 at all, so that the reliability of opening and closing the water gates 30 and 230 is improved.

In addition, the foreign material removing plate 411 applied to the 56th embodiment of the present invention can be changed in various materials and shapes. Therefore, even if the material and shape of the foreign material removing plate 411 is applied differently, It is natural to fall within the scope of rights.

57th Embodiment

160 is a cross-sectional view of the lower discharge of the rotary door according to the 57th embodiment of the present invention.

As shown, the fifty-seventh embodiment of the present invention is to prevent contaminants having a low specific gravity shrouded in the upper portion of the reservoir when discharged from the lower end of the rotating gate to be taken down by water pressure or water flow. In the 57th embodiment, the rotatable gates according to the first to 56th embodiments of the present invention can be applied to all of them. In the drawings, illustration of specific power means for rotating the gate is omitted.

In the rotary gate, in the 57th embodiment of the present invention, when the lower end is discharged between the lower parts of the gates 30 and 230 and the support structures 10 and 210, the pollutants having a lighter specific gravity are discharged by water pressure or water flow. The foreign matter collection groove 420 is formed on the upper surface of the round surface of the sluice plates 31 and 231 based on the closing time of the sluice gates 30 and 230 so as not to be discharged with water.

At this time, the foreign matter collection groove 420 is composed of the introduction portion 421, the space portion 422, the jaw 423, the lower surface of the hydrologic plate 31, 231 from the top by the water pressure or water flow at the bottom discharge The introduction portion 421 is preferably configured to extend in a streamlined form from the round surface of the sluice plates 31 and 231 so that contaminants having a light weight coming down are easily introduced into the space portion 422. The lower portion of the groove 420 forms the jaw 423 so that the pollutants having a lighter gravity collected in the space 422 are not easily leaked to the outside.

When the reservoir space formed through the sluice gates 30 and 230 in the state configured as described above becomes the full water level by the inflow water flowing from the upstream of the river, the sluice gates 30 and 230 are rotated upward by the power means, so that the sluice gate ( By forming a space between the bottom of the 30 and 230 and the bottom of the support structure 10 and 210 to discharge the amount of water flowing from the upstream of the stream to the lower end of the sluice 30, 230, the heavy clean The water is discharged by pushing the polluted water with light specific gravity according to the action of gravity and specific gravity, and the light pollutants contained in the water have specific gravity according to the law of material jungle, material release, material cutting and material preservation instinct. Pushed by these heavy clean waters, they are forced to the upper side of the water to naturally purify the contaminated water.

At the same time, the polluted waters that are stagnant in the upper layer of the stored water stored in the reservoir are naturally purified by the microorganisms generated in the reservoir and osmotic action to break into the substance and destroy the pollutant structure. Self-cleaning effect by the natural cleansing effect, and by destroying the structure of the pollutant due to the friction of the substance caused by the collision of the material molecules and the material molecules, and the natural cleansing effect by the solar heat And the purification of contaminated water quality by dilution with dissolved oxygen mixed in clean water coming upstream from the river naturally occurs inside the reservoir.

By the way, when the lower water is discharged through the space between the lower end of the water gate (30) 230 and the support structure (10, 210), the lower pressure of the reservoir space is forced to generate a strong water pressure and water flow, such water pressure and water flow As a result, pollutants having a low specific gravity in the upper layer of the reservoir may be discharged down the rounded surface of the sluice plates 31 and 231 to contaminate the river water.

In view of the above, the fifty-seventh embodiment of the present invention has a rounded surface of the sluice plates 31 and 231 on the top of the round surface of the sluice plates 31 and 231 based on the closing time of the sluice plates 30 and 230. The foreign material collection groove 420 having an introduction portion 421 extending in a streamlined form from the space portion and the space portion 422 in which the light specific gravity material is collected and the jaw 423 which prevents the light specific material from being drawn out. When the bottom water of the reservoir is discharged through the space between the lower end of the water gate (30) 230 and the support structure (10) (210), when the strong water pressure and water flow are generated, the specific gravity of the herpes on the upper layer of the reservoir space The light contaminants may flow down the rounded surface of the sluice plates 31 and 231 and then flow into the space portion 422 through the introduction part 421 of the foreign material collection groove 420. It is possible to prevent the discharge of the material with the discharged water.

In addition, if the pollutants having a low specific gravity collected in the foreign matter collection groove 422 does not generate the strong water pressure or water flow due to the closing of the water gates 30 and 230, the above-mentioned contaminants move to the upper part of the reservoir space by the action of gravity and specific gravity. It can be purified by the self-cleaning action as one.

That is, according to the fifty-seventh embodiment of the present invention, the specific gravity is light in the process of purifying the water quality of the river water while discharging it into the space between the water gates 30, 230 and the support structures 10, 210 as much as the inflow of the influent. Since the material is prevented from being discharged together due to water pressure or water flow, the water quality can be satisfactorily achieved in a faster time.

In addition, the foreign matter collection groove 420 applied to the fifty-seventh embodiment of the present invention is configured to have a shape such as a fishing needle, but the size and shape of the foreign matter collection groove 420 may be variously modified. Therefore, even if the size and shape of the foreign matter collection groove 420 is applied to vary the natural scope of the present invention is a matter of course.

In addition, even if the position of the foreign matter collection groove 420 is to be able to perform the same action even if the somewhat changed, even if it is applied to change the position of the foreign matter collection groove 420 is also natural that belongs to the scope of the present invention. .

As described above, the sluice of the present invention is combined with the total control system, the sluice combined with the total control system is formed asymmetrically longer with the length of the drain side around the axis of rotation or symmetrical composition ratio In addition, the packing member is fixed to the outside of the drainage side, by interlocking one or two working cylinders to the water gate of such a structure to open and close the waterway while rotating at an angle of about 90 to 360 °, As the bottom plate of the plate and the housing is horizontal, the water is discharged smoothly and foreign matters are not caught between the water gate and the housing. When the water gate is closed, the water gate and the housing are completely adhered by the packing member to prevent leakage. Of course, the length of the drain side and the bottom of the housing are made asymmetrically about the axis of rotation. Since the height of the drain side becomes round is formed in the downward direction, sandwiched between the bottom portion of the water gate and the housing which is in the water storage space by an amount corresponding to the sum of the thickness of the packing member can be secured more greatly.

"형상으로 형성되는 틈새를 패킹부재를 통해 완벽하게 패킹시킬 수 있으므로 수문의 폐쇄시 저수공간의 누수를 방지할 수 있는 완벽한 폐쇄상태를 구현할 수 있는 것으로, 이와 유사한 특허는 본 출원인에 의해 제안된 바 있으나, 본 발명에서는 이를 개선하여 수문의 폐쇄 상태에서 패킹부재를 압착하여 수문과 하우징 사이의 틈새를 패킹시키거나, 수문의 회전동작시 수문의 하단부가 패킹을 눌러주면서 회전됨으로써 패킹부재에 의해 수문과 하우징 사이의 틈새를 완벽하게 패킹시켜줄 수 있는 특징이 있는 것이다.Also, between the sluice and the housing

"Because the gap formed in the shape can be completely packed through the packing member, it is possible to realize a perfect closed state to prevent leakage of the storage space when the water gate is closed, and a similar patent has been proposed by the present applicant. However, in the present invention to improve this by compressing the packing member in the closed state of the floodgate to seal the gap between the watergate and the housing, or during the rotation operation of the floodgate by pressing the packing to the lower end of the floodgate by the packing member It has the feature of completely packing the gap between the housings.

In addition, when the fixed shaft is fixed to the support structure, and the power means for rotating the water gate is located inside or outside the side plates of the water gate does not need to form a separate sealed space inside the support structure to improve workability In addition, it is possible to improve the bearing capacity of the supporting structure, and to form a floodgate relatively large in relation to the width of the river, so that the water can be discharged in a faster time when the low water level rises rapidly, such as flooding. There is an advantage to prevent the occurrence of dangerous situations, such as, each gate can be operated by the electricity generated by the solar power generation can save the cost of using ordinary electricity, and Through the use of electricity stored in it can prevent the occurrence of power outages.

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.

In addition, when the water gate is closed for a little while to open, the lower water in the reservoir can be discharged through the space between the water gate and the housing, so that the polluted substances contained in the river water are naturally purified. “And“ Material Scavenging ”,“ The Law of Conservation Instinct ”and“ Agglomeration ”and“ Material Bonding ”,“ Material Rejection ”and“ Material Release ”and“ Material Decomposition ” Because it has the effect of purifying the purified river water, the polluted river water has a significant action effect that is purely purified.

In other words, the contaminated water is naturally purified while staying in the reservoir, and it can prevent the secondary contaminants that create new pollutants by blocking the condensation phenomenon caused by the condensation and contaminants. And, as the water is discharged, aeration is caused by a drop, which enables the water purification to be more active through the natural purification of the water itself and the floating of foreign substances by aeration. If it is installed in the water will be able to be purified more naturally through each step.

Therefore, this system can be used to purify polluted river water easily at low cost even in the case of large rivers, and can create completely clean river water because it uses the natural purification system naturally generated by nature. It is effective in producing clean water without using chemicals such as chlorine and fluorine. When applied to a large dam it is possible to reduce the occurrence of sedimentation sludge in the dam, there is a significant action effect that can prevent the green algae caused by the above actions at the source.

In addition, there is a significant effect that blocks the source of the red tide caused by the flow of polluted river water from the land of the land flow into the sea.

Also, no matter how much water is trapped, the stored water does not decay, so you can not only trap a large amount of water, but also because of the capillary phenomenon caused by the trapping of the water, Due to its status, it promotes the growth of trees growing in the mountains and prevents forest fires in advance, and this action prevents the desertification of the land caused by drought, thus making the desert occupied. There is a significant effect on the conversion.

In addition, even when the water gate is closed, the discharge passage formed inside the water gate can discharge the water in the reservoir space, so that the river water can be purified continuously and the water level can be maintained at an appropriate level. It is possible to move upstream through the discharge passage formed to restore or maintain the ecosystem.

In addition, by detecting this when the center of gravity of the gate crosses in the opposite direction, by reducing the extension speed of the working cylinder acting in the opposite direction, the rotational speed of the gate can be artificially lowered to ensure safety.

When the water is confined using the hydrologic gate of the present invention, which is configured to discharge the amount of water flowing from the upstream of the stream through the lower end of the hydrologic gate, the influent flowing from the upstream of the stream is always the same as the influent flowing through the lower end of the hydrologic gate. Because it can be discharged, water pollution is not aggravated and the pollutants contained in the water are naturally decomposed and purified into clean water by the ten actions exerted in the reservoir space confined by the rotating water gate.

“The 10 Natural Purifications Naturally Exerted”

① The act of naturally purifying pollutants by dissolved oxygen in water

② The effect that the pollutants are naturally decomposed and purified by microorganisms.

③ Natural purification of pollutants by friction of water molecules moving by Brownian motion

④ Purification effect which naturally decomposes polluted material by solar heat

⑤ Natural purification effect that the pollutant is decomposed naturally by friction of aquifer in contact with air.

⑥ Purification effect that the pollutant is naturally decomposed by osmotic pressure

⑦ Natural purification effect that the pollutant is decomposed naturally by the compressive force generated by the pressure of gravity

⑧ Decomposition of pollutants by substance penetration action caused by capillary action

⑨ Natural decomposition of pollutants by the law of substance preservation instinct

미립자 Pollutants contained in the water are naturally purified due to the decomposition of the pollutants caused by the friction between the particles contained in the water and the particles.

"Definition of" Material Decomposition "and" Material Bonding "in which pollutants are naturally purified"

All pollutants such as nitrogen and phosphorus are combined with water molecules by the viscous force of the pollutants, and become heavier than the specific gravity of water molecules, and they are settled in the bottom layer of the river by gravity.

As a result of the decomposition of sedimentary sludges, the natural degradation of the sedimentary sludge is caused by the natural decomposition of the sedimentary sludge by depositing contaminants on the bottom of the stream (iron has a specific gravity of 7.85). Red rust produced by decomposing naturally has a specific gravity of about 0.97).

Particles of contaminants generated by natural decomposition action add to the water pollution by repeating the recombination of the existing water molecules with other contaminants flowing upstream. will be.

These actions are "material decomposition" and "material binding". However, if the influent is discharged through the lower part of the hydrologic gate, the laminar flow caused by the action of gravity never causes material binding to combine with other materials with different specific gravity. Will be.

"Definition of" The Law of Conservation Instinct "in which pollutants are naturally purified."

When other foreign matter penetrates and combines in the material structure of matter, it is the "law of substance preservation instinct" that refuses to unconditionally refuse to combine.

Naturally polluted waters will eventually be cleansed by the natural action of the water molecules in the clean state trying to shake off the contaminants in the water molecules. This action is the "law of substance conservation instinct" (similar to the principle that if oil is poured into the water, it will not be diluted quickly but will float in the water).

All water molecules are not easily bound by the action according to the "law of substance conservation instinct", which tries to preserve pure water molecule structures permanently, even if contaminants enter the water molecules, but do not immediately bind, like the principle of oil floating in water. .

No matter how contaminated water is by this action, it is always kept clean by the action of the law of substance preservation instinct.

“Definition of the substance aggregation action” in which pollutants are naturally purified

All contaminants are transformed into polar particles through the process of natural decomposition and evaporate into the atmosphere of the ground by the convection of moisture evaporation to form clouds. Through this circulation process, the pollutants that occur from time to time and the "agglomeration" of the masses in the atmosphere change to heavier than the specific gravity of the water, mixed with rainwater, falling to the ground, or combined with moisture contained in the air. As it falls to the ground, it sinks to the bottom of the river by agglomeration of substances that aggregate with other pollutants contained in the river water, which further worsens the water quality of the river water.

Light pollutants such as nitrogen are converted into substances that are heavier than the specific gravity of water by "agglomeration", which is often combined with other pollutants by convection, which often occurs as the material decomposes and transforms into polar particles. It sinks into a waterfront space consisting of a drinking water gate or rubber dam or a gravity or concrete gravity dam, creating another pollutant by aggregating another pollutant with another pollutant to increase water pollution. . The material produced by this "agglomeration" is sedimentation.

"Definition of" material binding action "in which pollutants are naturally purified"

Particles of incompletely decomposed materials are combined with water particles and contaminant particles by the viscous force exerted by the microparticles and the magnetic force of the material. Through this, the particles become heavier than the specific gravity of the water molecules and are settled at the bottom of the river. What is produced by this "material binding action" is sedimentation.

"Definition of" Material Friction "in which pollutants are naturally purified"

The tip of the water has a pointed shape. The continually flowing Brownian motion creates a thorough friction between the sharp parts of the water and the surface of all the materials that enter the water, so that all substances that enter the water are completely decomposed and the material itself is lost. Using material friction, people wash and bathe with water to wash off harmful substances.

If you correctly define the principle of the natural decomposition of contaminated substances in water, because of the "material friction action," even the most polluted substances are thoroughly decomposed naturally by the pointed parts, the largest weapons of water, and the existence of the substance itself. The water itself is decomposed naturally by water.

"Definition of" purification of pollutants naturally "and" purification of polluted water naturally by material laminar action "

When other foreign matter penetrates into the structure of clean water molecules and tries to combine with water molecules, it is not easily diluted by the substance rejection action that rejects them. (Pouring oil into water does not immediately dilute water and oil. It is because of "substance rejection". Due to this action, when the influent is discharged through the lower part of the gate, the laminar flow action naturally occurs due to the action of gravity, so that the polluted water with light gravity moves to the upper part and the clean water with heavy gravity has According to the logic, the material separation action is caused by the "laminar flow and the material cutting action" discharged first through the lower part of the floodgate, so that the uncontaminated clean water is moved downstream and the polluted river water is stagnated inside the floodgate. It is naturally cleansed by the naturally occurring teenage cleansing.

"Definition of" Material Acceleration "to make polluted water even worse"

The substances contained in all river waters, or more than 24 million kinds of substances on earth, are caused by gravity to act differently and according to their specific gravity. It flows in layers.

Due to this action, clean water with a heavy specific gravity flows slowly while it is in the lower layer of the river water, and polluted water with a light specific gravity flows rapidly while being in the upper layer of the river water. This action occurs because of the "mass acceleration phenomenon".

If water is confined using conductive hydrology, rubber dams, and gravity or concrete gravity dams that are discharged through the upper end, water pollution is further aggravated by such material acceleration and mass aggregation.

"Definition of" Material Scavenging Action "to help the pollutants naturally clean up"

When stream waters coming from upstream try to pass through the lower part of the sluice, clean water with heavy gravity pushes lightly contaminated water upstream and then exits through the lower layer of lightly contaminated water first. Material cutting action ”is caused by the action of gravity.

When the incoming water is discharged through the lower part of the water gate using the rotary water gate, the polluted water is naturally purified by the clean water so that the clean water leaves the contaminated waters and escapes first through the lower part of the water gate. Because of the "stroke," even the polluted water is purified to clean water.

"Definition of Water Purification by" Material Bonding and Mass Degradation "in which Pollutant is Naturally Purified"

The strong viscous forces of pollutants inevitably bind to other pollutant molecules, and at the same time, they transform into a material that is heavier than water, and sink to the bottom of the river. The natural degradation of the ten species in the state of sinking to the bottom layer of the river causes the substances to be decomposed again, generating fine particles of fine pollutants. At this time, the contaminants generated at this time and the contaminants pushed upstream from the upstream and the repetitive action of the material binding action occurs again to create a sedimentation sludge. This action is "material binding action and material decomposition action" is.

"Definition of Water Purification for" Material Desorption "in which Pollutants are Naturally Purified"

When a certain impact is applied to the water to shake off the contaminants that penetrate the water molecular structure to make pure water molecules, the contaminants contained in the pure molecular structure of the water are immediately released from the water molecule. As this occurs, contaminated river water is reduced to clean water.

In addition, if you install the hydrologic gate of the present invention configured to discharge the river water flowing from the upstream of the river through the lower end of the hydrologic gate because the above actions occur naturally, no matter how polluted river water is naturally purified by clean water There is an absolute advantage.

Claims (59)

A water channel 11 is formed between the support structures 10 and coupled to the integrated control system 100, and the housings 20 are respectively covered on opposite surfaces of the support structures 10. An enclosed space 12 is formed between the support structures 10, and both side plates 32 and both side plates 32 formed at right angles to both end portions of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of a rotation shaft 33 drawn outward from the outside, and the rotation shaft 33 is used to purify the contaminated river water by using the rotation gate formed by inserting the shaft holes 21 formed in the respective housings 20. In the method, The sluice coupled with the integrated control system 100 is the sluice plate 31 and both side plates 32 in the open position of the sluice 30 is more than the reservoir side of the drain side with respect to the rotation axis 33 Fixing the shock absorbing packing member 40 continuously in the longitudinal direction of the sluice gate 30 on an outer side of the drainage side boundary of the sluice plate 31 and the side plates 32 while being formed asymmetrically long; The operation link 34 is drawn out to the water storage side at the closed space position of the rotary shaft 33, and the first operation cylinder 51 is installed at the upper water storage side of the sealed space 12, and the operation link 34 A support roller 52 is rotatably installed at a position parallel to the first operation cylinder of the upper portion, and is supported by the support roller 52 and the rotation shaft 33 from the piston rod end of the first operation cylinder 51. The connecting member is connected to the distal end of the operation link 34, and the pressing plate 35 is drawn out from the side of the operating link position side of the rotary shaft 33 in the opposite direction to the operating link extraction direction, and the pressing plate 35 is positioned. The support plate 62 and the operating plate 63 are fixed to the outside in a "V" shape having a gentle inclination and the support plate 62 is rotated without interference when the support plate 35 is rotated when the water gate 30 is rotated. ) Through the operation plate 63 from the opposite position A ring-shaped slider 64 having an operating groove 65 formed therein up to the support plate 62 is inserted therein, and the operation plate 63 is rotatably fixed to the end of the piston rod of the second operation cylinder 61 to operate the respective cylinders. The water quality in combination with the system for purifying the contaminated water quality with clean water, characterized in that the water gate 30 is opened and closed by rotating the water gate 30 by an angle of about 270 ° by the interlocking of the 51 and 62. Eco-friendly method to cleanse. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system 100, and the housings 20 are respectively covered by opposing surfaces of the support structures 10. An enclosed space 12 is formed between the support structures 10, and both side plates 32 and both side plates 32 formed at right angles to both end portions of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of a rotation shaft 33 drawn outward from the outside, and the rotation shaft 33 is used to purify the contaminated river water by using the rotation gate formed by inserting the shaft holes 21 formed in the respective housings 20. In the method, In the open position of the sluice gate 30 combined with the integrated control system 100, the sluice plate 31 and both side plates 32 are asymmetrically longer than the reservoir side with its drainage side centered on the rotation axis 33. Fixing the packing member (40) continuously in the longitudinal direction of the sluice (30) on the outer side of the sluice plate (31) and the side plate (32) on the drain side boundary while forming; The operation link 34 is drawn out to the water storage side in the sealed space position of the rotary shaft 33, and the first operating cylinder 51 and the second operating cylinder 62 face each other on both sides of the upper portion of the sealed space 12. The first support roller 52 'and the second support roller 52 "are rotatably installed at positions parallel to each operation cylinder immediately above the operation link 34, respectively. By the first support roller 52 ′ and the rotating shaft 33 from the piston rod tip of the first operating cylinder 51 positioned on the water storage side with respect to the position of the water gate 30, the operating link ( The first support member is connected to the front end of 34, and the second support roller 52 " is moved from the piston rod front end of the second operation cylinder 61 positioned on the drainage side with respect to the position of the water gate 30. FIG. By connecting the second connecting member to the distal end of the operation link 34 via the A system for purifying contaminated water quality with clean water, wherein the water gate 30 is opened and closed by rotating the water gate 30 at an angle of about 270 ° by interlocking with each operation cylinder 51, 61. Eco-friendly method for purifying water by combining. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system 100, and the housings 20 are respectively covered by opposing surfaces of the support structures 10. An enclosed space 12 is formed between the support structures 10, and both side plates 32 and both side plates 32 formed at right angles to both end portions of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of the rotating shaft 33 drawn out from the outside, and the rotating shaft 33 is inserted into the shaft holes 21 formed in the respective housings 20 to purify the contaminated river water. In the way, In the open position of the sluice gate 30 combined with the integrated control system 100, the sluice plate 31 and both side plates 32 are asymmetrically longer than the reservoir side with its drainage side centered on the rotation axis 33. Fixing shock absorbing packing member (40) continuously in the longitudinal direction of the sluice (30) on the outer side of the drainage side boundary of the sluice plate (31) and both side plates (32); At the closed space position of the rotary shaft 33, the operating link 34 having the operating rod 34a formed at the front end thereof is drawn out to the storage side, respectively, and the first operating cylinder 51 is disposed at both upper sides of the sealed space 12. Respectively arranged in the vertical direction to be rotatable, and each of the operating rods (34a) is formed by forming a long hole (57) on the front end of the piston rod (56) of the first operating cylinder (51), The second operation cylinder 61 is rotatably disposed at the potential or the rear of the first operation cylinder 51, and the long hole 67 is formed at the tip of the piston rod 66 of the second operation cylinder 61. The body 30 or the piston rod 56 of the first operation cylinder 51 is inserted into the water gate 30 by the interlocking operation of the respective operation cylinders 51 and 61 and rotates at an angle of about 270 °. Clean water into the contaminated water quality, characterized by opening and closing the water channel 11 Combined with the system that was environmentally Tuesday method for purifying the water. A channel 11 is formed between the two support structures 10 coupled to the integrated control system 100, and the housings 20 are respectively covered by opposing surfaces of the support structures 10. And a closed space 12 is formed between the support structure 10, and both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is constituted by the rotating shaft 33 drawn outward from the outside, and the rotating shaft 33 is inserted into the shaft holes 21 formed in the housings 20 to purify the contaminated river water. In the way, The sluice plate 31, the side plate 32, the rotating shaft 33 of the sluice 30 is configured to be symmetrical, the side plate 32 is configured in a "ㅗ" shape on the side, the sluice plate Lower sides of the 31 are formed to be rounded at the same curvature so as to be in sliding contact with the rounded portion in the bottom direction of the bottom of the housing 20 and fixed by the lower surfaces of the side plates and the fixing member; At the closed space position of the rotary shaft 33, the operating link 34 having the operating rod 34a formed at the distal end thereof is drawn out to the water storage side, and the operating link 34 is disposed at both upper sides of the sealed space 12. First operating cylinders 51 for rotating are disposed in the sealed space 12 so as to be rotatable, and long holes 57 are respectively provided at the tip of the piston rod 56 of the first operating cylinder 51. And a second operation cylinder 61 for rotating the first operation cylinder 51 around the first cylinder 51, wherein the operation rods 34a are fitted to each other. A long hole 67 is formed at the distal end of the piston rod 66 of the second actuating cylinder 61, and the body or the piston rod 56 of the first actuating cylinder 51 is fitted therein to form the respective actuating cylinders 51. The waterway 11 is rotated at an angle of 360 ° by the interlocking of the (61). Eco-friendly method for purifying water by combining with the system for purifying contaminated water with clean water, characterized in that the opening and closing. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, The drainage side of the bottom portion of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 forms the sluice plate 31 and both side plates 32. It is formed symmetrically about the rotation axis 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing 20, On the basis of the fully open state of the water gate (30), the heavy end portion (101) is built in the drain side side of the water gate plate (31); In the closed space position of the rotating shaft 33 is a planar "

Fixed to the rotating shaft 33, the end of the operating rod 102, the opposite end of the rotating shaft fixed portion of the piston rod 104 of the operating cylinder 103 is rotatably connected And; The actuating cylinder 103 is positioned in the same direction as the channel opening / closing position of the sluice 30 so as to rotatably fix the rear end thereof to a position at least higher than the height of the rotation shaft 33, and the sluice 30 is completely On the basis of the opening when the operating rod 102 is horizontally configured at the same angle as the width direction of the sluice plate 31 toward the operation cylinder 103 direction of the expansion and contraction of the operation cylinder (103) ( Purifying the contaminated water quality to clean water, characterized in that for opening and closing the waterway 11 while rotating the water gate 30 by an angle of 360 ° using one operation cylinder 103 according to the position of 101) Eco-friendly method to purify water quality in combination with the system. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, The drainage side of the bottom portion of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 forms the sluice plate 31 and both side plates 32. It is formed symmetrically about the rotation axis 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing 20, On the basis of the fully open state of the water gate (30), the heavy end portion (101) is built in the drain side side of the water gate plate (31); In the closed space position of the rotary shaft 33 in the closed space position of the rotary shaft 33 "

Crank portion 102 'bent in the shape of "and integrally fixed to the rotary shaft 33 so that both sides are rotatably supported by the support 38 to the bottom of the sealed space 12, the crank At the center of the part 102 ', the tip of the piston rod 104 of the actuating cylinder 103 is rotatably connected; The actuating cylinder 103 is positioned in the same direction as the channel opening / closing position of the sluice 30 so as to rotatably fix the rear end thereof to a position at least higher than the height of the rotation shaft 33, and the sluice 30 is completely On the basis of the opening, the crank portion 102 'is horizontally formed at the same angle as the width direction of the sluice plate 31 toward the actuating cylinder 103 direction to expand and contract the actuating cylinder 103 and the heavy object. Purifying the contaminated water quality with clean water by opening and closing the waterway 11 while rotating the water gate 30 at an angle of 360 ° using one operation cylinder 103 according to the position of 101. Eco-friendly method to purify water quality in combination with the main system. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and the two side plates 32 and the two side plates 32 formed at right angles to both ends of the arc-shaped hydrology plate 31 and the hydrology plate 31 are moved outwardly. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, The drainage side of the bottom portion of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 forms the sluice plate 31 and both side plates 32. It is formed symmetrically about the rotation axis (33), the lower surface of both sides of the sluice plate (31) is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing (20); In the closed space position of the rotary shaft 33 is "

Fixed to the first crank part 108 and the second crank part 108 ′ having the shape of inverting the first crank part 108 continuously from the rotation shaft 33, and the first crank part 108 The portion 108 and the second crank portion 108 ′ are rotatably supported by the support 38 at the bottom of the sealed space 12, and in the center of the first crank portion 108, there is a first portion. Rotatingly connecting the distal end of the piston rod 56 of the operating cylinder 51 and rotatably connecting the distal end of the piston rod 66 of the second operating cylinder 61 to the center of the second crank portion 108 '. However, each of the operation cylinders 51 and 61 is installed at a position other than the horizontal direction with the rotation shaft 33 so that the water gate 30 is 360 degrees according to the expansion and contraction of the operation cylinders 51 and 61. Purifying contaminated water quality with clean water, characterized in that to clean the water quality while opening and closing the waterway 11 while rotating to It is environmentally friendly method in combination with the system that purifies water. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. The enclosed space 12 is formed between the 10 and the water gate formed by integrally forming both side plates 32 at right angles to both ends of the arc-shaped sluice plate 31 so that the water passage 11 can be opened and closed. In the method of purifying the contaminated river water by using a rotating water gate, The drainage side of the bottom portion of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 forms the sluice plate 31 and both side plates 32. It is formed symmetrically, the lower surface of the both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the surface rounded downward in the housing (20); Rotational center of the water gate 30 is rotatably fixed to the bottom of the housing 20 by the first crank 108, the support 38 is fixed to both side plates 32 of the water gate 30 Rotation to the bottom of the housing 20 by the first rotating shaft 109, the second crank 108 ', which is connected to the front end of the piston rod 104 of the working cylinder 103, and the support 38 The second rotation shaft portion 109 ', which is secured to be rotatable and supports the second crank portion 108' together with the first rotation shaft portion 109 while forming a rotational center of the sluice 30, is bent sequentially. The first and second crank parts 108 and 108 are fixed to both side plates 32 of the water gate 30 through the first crank part 106. ') Are the same as each other, the position of the first rotary shaft portion 109 and the second rotary shaft portion 109' is the same as each other, each of the cranks 108 (108 ') And each of the rotating shaft portions 109 and 109 'are positioned in opposite directions to rotate the water gate 30 through the operation link 116' according to the expansion and contraction of the operation cylinder 103. (11) Eco-friendly method for purifying water quality by combining with the system for purifying the contaminated water quality to clean water, characterized in that to clean the water quality while opening and closing. A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, The drainage side of the bottom portion of the housing 20 is formed to be rounded downward to be in sliding contact with the arc-shaped sluice plate 31, and the sluice 30 forms the sluice plate 31 and both side plates 32. It is formed symmetrically about the rotation shaft 33, the lower surface of both sides of the sluice plate 31 is formed to be rounded with the same curvature so as to be in close contact with the rounded surface in the downward direction of the housing 20 ; An actuating link 34 is fixed to the rotatable shaft 33 at a closed space position of the rotatable shaft 33, and a piston rod 104 ′ of the actuating cylinder 103 ′ is provided at an end opposite to the rotatable shaft fixing portion of the rotatable link 34. ) Rotatably connect the tip; The actuating cylinder 103 'is positioned in the same direction as the channel opening and closing position of the water gate 30, and the actuating link 34 is fixed to the rotating shaft 33 in the actuating cylinder 103' installation direction, The actuating cylinder 103 'and the actuating link 34 are installed such that the lower side angle between them is about 180 ° based on the full opening of the water gate 30 to the expansion and contraction of the actuating cylinder 103. In accordance with the eco-friendly method for purifying the water quality in combination with the system for purifying the contaminated water quality to clean water, characterized in that the opening and closing of the waterway 11 while rotating the water gate 30 using one operation cylinder 103 accordingly . A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, The rotary shaft 33 is rotatably connected to the reducer 105 in a closed space position, and the reducer 105 is connected to the drive motor 106 so as to transmit power to drive the drive force of the drive motor 106 to the rotary shaft. Eco-friendly method for purifying water quality by combining with a system for purifying contaminated water quality with clean water, characterized in that for opening and closing the waterway (11) by rotating the water gate (30) by decelerating transmission to (33). A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The water gate 30 is composed of the drawn rotation shaft 33, and the rotary shaft 33 of the water gate 30 is contaminated river water by using the rotation gate formed by being inserted into the shaft hole 21 formed in each housing 20 In the method of purifying, Directly connecting the hydraulic actuator 106 'to the rotary shaft 33, and controlling the rotational speed by controlling the flow rate of the oil supplied to the hydraulic actuator 106' purifying contaminated water quality with clean water Eco-friendly method to purify water quality by combining with the A water channel 11 is formed between the two support structures 10 coupled to the integrated control system, and the housings 20 are respectively covered by opposing surfaces of the support structures 10 so that the housing 20 and the support structures are respectively covered. An enclosed space 12 is formed between the two sides, and is formed from both side plates 32 and both side plates 32 formed at right angles to both ends of the arc-shaped sluice plate 31 and the sluice plate 31. The sluice gate 30 is composed of the drawn rotation shaft 33, and the rotatory shaft 33 of the sluice 30 is contaminated using the rotation gate formed by being inserted into the shaft holes 21 formed in the housings 20, respectively. In the method of purifying river water, The winding roll 33a is fixed to the closed space position of the rotating shaft 33, the driving motor 106 is fixed to the closed space 12, and the rotating shaft 33 is attached to the axis of the driving motor 106. The winding rolls (106a) corresponding to the fixed winding rolls (33a) are fixed, and a wire rope (107) is connected between each of the winding rolls (33a) and (106a) so that the rotational force of the driving motor (106) is increased. In combination with a system for purifying contaminated water quality with clean water, characterized in that the water passage 11 is opened and closed by transmitting the wire rope 107 to the rotary shaft 33 to rotate the water gate 30. Eco-friendly method to purify water quality. The method according to any one of claims 1 to 12, The third operation cylinder 71 is installed at the inner reservoir side of the housing 20 so as to be stretched to the drainage side, and the third operation cylinder 71 is disposed at the middle of the bottom portion of the housing 20 which is rounded downward. The variable operation plate 72 which is projected according to the expansion and contraction is fixed to the tip of the piston rod of the third operation cylinder 71 to store water even when the water gate 30 is closed according to the expansion and contraction of the third operation cylinder 71. Eco-friendly method for purifying water quality by combining with the system for purifying polluted water with clean water, which is characterized by purifying polluted river water by discharging the bottom water of the space. The method according to any one of claims 1 to 7, and 9 to 12, The rotating shaft 33 is installed to rotatably penetrate the center of the elevating block 90 in the sealed space 12, and the elevating pipe 91 is fixed to both lower portions of the elevating block 90, respectively. Each of the elevating pipes 91 is inserted into the inner space of the fixed pipe 92 fixed to the bottom of the sealed space 12 so as to be lifted, respectively, and the inner space of the fixed pipe 92 and the elevating pipe 91. In the lifting cylinder 93 is rotatably fixed to the bottom of the closed space 12, respectively, the piston rod 94, the front end of the lifting block 90, respectively rotatably fixed to the lifting block, Each of the members for opening / closing the gate 30 by rotating the rotary shaft 33 is fixed to the shaft 90 according to the expansion and contraction of the elevating cylinder 93 while the gate 30 is closed. 30 to form a space between the housing 20, such as Eco-friendly method for the contaminated water, characterized in that for purifying polluted river water by the lower layer can drain the water storage space through a space in conjunction with a system that purifies with clean water to purify the water. The method according to any one of claims 1 to 7, and 9 to 12, The guide groove 22 is formed in the up and down direction at the rotation shaft insertion portion of the housing 20, and the width of the housing adjacent the rotation shaft 33 is greater than the width of the guide groove 22 of the housing 20. While it is configured to rotatably fix the packing plate 23 having a length of more than twice the length so that it is always in close contact with the wall surface of the housing 20, the contact portion of the packing plate of the housing 20 The packing plate guide groove 24 is formed therein so that the packing plate 23 can be moved up and down in the direction of the guide groove 22 and is always positioned at a predetermined position regardless of the rotation of the rotation shaft 33. 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 to 12, The sluice of the sluice 30 on the basis of the state in which the sluice 30 is completely closed so that no leakage occurs between the three edges of the sluice plate 31 of the sluice 30 and the housing 20. 3 in front of the lower surface of the plate 31 and the position blocking the position between the housing 20

"Positioning the support frame 111 of the shape, and the upper side of each side of the support frame 111 is provided with a rotating shaft 112 so that each of the rotating shaft 112 penetrates the side wall of the housing 20, In the enclosed space 12 between the housing 20 and the support structure 10, the operation link 116 is fixed to the rotation shaft 112, and the tip of the piston rod 114 of the support frame operation cylinder 113 is attached thereto. Rotatably connected to each other, and a rear end of the support frame operating cylinder 113 is rotatably connected to an inner wall drain side of the housing 20 in the closed space 12, and drained from the support frame 111. On the side "

&Quot; Packing between the sluice 30 and the housing 20 by attaching a shape-shaped packing member 115 to stretch the support frame working cylinder 113 in accordance with the state of the sluice 30, Eco-friendly method for purifying the water quality by combining with a system for purifying the contaminated water quality to clean water, characterized in that it does not interfere with the rotation of the water gate (30). The method according to any one of claims 1 to 12, The sluice of the sluice 30 on the basis of the state in which the sluice 30 is completely closed so that no leakage occurs between the three edges of the sluice plate 31 of the sluice 30 and the housing 20. 3 in front of the lower surface of the plate 31 and the position blocking the position between the housing 20

"Position the support frame 111 of the shape, and on the drain side of the support frame 111"

It is configured by attaching a "shaped packing member 115, and each of the connection links (117) rotatably fixing the" L "shaped connection links 117 at the center of the storage side of both sides of the support frame 111. Each of the rotating shafts 112 passes through the side wall of the housing 20 so that the rotating shafts 112 are provided at an upper portion of the 117, respectively, and a sealed space 12 between the housing 20 and the support structure 10 is provided. At the rotation shaft 112, the operation link 116 is fixed to the piston rod 114 of the support frame operation cylinder 113 to be rotatably connected thereto, and the rear end of the support frame operation cylinder 113, respectively. The portion is rotatably connected to the inner wall drainage side of the housing 20 in the sealed space 12 to expand and contract the support frame operating cylinder 113 between the water gate 30 and the housing 20. Do not pack or interfere with the rotation of the water gate (30) Eco-friendly method for purifying the water in conjunction with a system that purifies contaminated water with clean water, characterized in that. The method according to any one of claims 1 to 7, and 9 to 12, On the basis of the state in which the sluice gate 30 is completely closed, the front side of the sluice plate rim of the housing 20 is located at the front side.

&Quot; Position the support protrusion 111 'in the shape, and on the drain side of the support protrusion 111 "

"A shape of the packing member 115 is attached, but the support protrusion 111 'and both sides of the packing member 115 are formed with the same curvature as the curvature of the sluice plate 31 of the sluice 30, the housing A guide groove 22 'having a long shape in the horizontal direction is formed at the hydrological rotation shaft insertion position of the 20 to insert the rotation shaft 33 of the hydrology 30 therein, and the rotation shaft in the sealed space 12. 33 is rotatably supported by a pair of support brackets 125, wherein the support brackets 125 have the same shape as the guide grooves 22 'formed in the housing 20. Respectively formed, and the front end of the piston rod 124 of the forward and backward cylinder 123 is rotatably fixed to a position between the support brackets of the rotating shaft 22, and the rear end of the forward and backward cylinder 123 is housing 20 Fixed to the inner wall surface of the front and rear cylinders in the expansion and contraction of the 123 La the sluice 30 and environmentally friendly method for binary entirety before and after combination with a system that purifies contaminated water, characterized in that for purifying contaminated river water, clean water purifying the water. The method of claim 18, A housing plate of the rotary shaft 33 is rotatably fixed to a packing plate 23 ′ having a width larger than the width of the guide groove 22 ′ of the housing 20 and having a length greater than twice the length thereof. It is configured to maintain a state in close contact with the wall surface of the housing 20 at all times, and the packing plate 23 'is formed by forming a packing plate guide groove 24' in the packing plate contact portion of the housing 20 The water quality is combined with a system for purifying contaminated water quality with clean water, characterized in that it is possible to move forward and backward in the direction of the guide groove 22 'and is always located at a predetermined position regardless of the rotation of the rotation shaft 33. Eco-friendly method to purify. The method according to any one of claims 1 to 7, and 9 to 12, On both side walls of the housing 20, the door frame 127 is formed with the same curvature as the curvature of the lower surface of the sluice plate 31 of the sluice 30, and the support for supporting the rotation shaft 33 of the sluice 30 The support bracket 125 is configured to be inclined at a predetermined angle to the water storage side by supporting the lumber 126 on the drain side bottom portion of the bracket 125, and the rotation shaft 33 of the water gate 30 is formed on the support bracket 125. It is configured to be positioned above the water storage side rather than the center of rotation of the door frame 127 according to the position so that the sluice plate 31 tightly adheres to the door frame 127 when the water gate 30 rotates. Eco-friendly method to purify the water quality by combining with the system to clean the polluted water with clean water. The method according to any one of claims 1 to 12, The sluice plate 31 of the sluice 30 is composed of a flat plate, both sides of the plate 32 fixed to both sides of the sluice plate 31 forms a triangular shape as a whole while the lower end is composed of a rounded shape, round The contaminated water quality is configured to be located at a lower side than at least the sluice plate 31, and each of the rotary shaft 33 in the outward direction from the upper one side of the two side plates 32, respectively 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 to 12, On the basis of the state in which the sluice gate 30 is completely closed, the front side of the sluice plate rim of the housing 20 is located at the front side.

&Quot; Position the support protrusion 111 'in the shape, and on the drain side of the support protrusion 111 "

&Quot; Attachment-shaped packing member 115, wherein both sides of the support protrusion 111 'and the packing member 115 are formed to have the same curvature as the curvature of the sluice plate 31 of the sluice 30, and the packing The outer ends of the member 115 are both side portions of the water gate 30 based on the closing of the water gate 30 so that the outer side edges and lower edges of the water gate 30 come into contact with each other when the water gate 30 is rotated. Rather than the edge and the lower edge position to be located in the position 5 to 10 mm forward to the drainage side, the pointed boundary between the lower end and the upper side of the side plate 32, the packing member 115 during the rotation of the water gate (30) In combination with the system for purifying the contaminated water quality with clean water, characterized in that each guide 128 is formed so as to press the part interfering with the lower end of the water gate so that the water does not come into direct contact with the pointed area. When purifying water quality It is environmentally friendly method. The method according to any one of claims 1 to 12, The rotating shaft 33 is rotatably fixed to the upper side of the two side plate 32, the space portion 32a is formed inside the both side plate 32, the space portion position of the rotating shaft 33 When the push rod 33b is respectively fixed and rotated in the direction of closing the water gate 30, the water pad 31b and the both sides from the time when the push rod 33b comes into close contact with one side wall of the space 32a. It is possible to rotate the plate 32, the rotation of the push rod 33b in the opposite direction is to clean the polluted water quality, characterized in that the sluice plate 31 and both side plates 32 to be opened by its own weight Eco-friendly method to purify water quality by combining with water purification system. The method according to any one of claims 1 to 12, On the basis of the state in which the sluice gate 30 is completely closed, the front side of the sluice plate border of the housing 20

&Quot; shaped support protrusion 111 'is positioned, and a packing member 115 having one side bulging is attached to both side drain side surfaces of the support protrusion 111', and a lower side of the support protrusion 111 '. An eco-friendly method for purifying water quality by combining with a system for purifying contaminated water quality with clean water, characterized by attaching a central bulging symmetrical packing member 115 'to the drain side. The method according to any one of claims 1 to 7, and 9 to 11, In the enclosed space 12, the protection plate 33c made of stainless steel or copper is wound at least two to three times on the rotation shaft 33 of the water gate 30, and the support shaft 125 is held as it is. Eco-friendly method to purify the water quality by combining with the system for purifying contaminated water quality to clean water, characterized in that it is rotatably inserted in the configuration. The method of claim 24, The siphon plate 129 is fixed to the lower surface of the sluice plate 31 to form a siphon passage 130 between the sluice plate 31 and the siphon plate 129, but the lower portion of the siphon plate 129. Is fixed at intervals higher than the lower end of the sluice plate 31 on the basis of the closing time of the water gate 30 so that there is no interference with the packing member (115 '), the upper end of the siphon plate 129 The eco-friendly method for purifying the water quality by combining with a system for purifying the contaminated water quality to clean water, characterized in that to be located at a higher position than the sluice plate 31 to discharge the water through it. A closure, which is constituted by the method of any one of claims 1 to 11, and connected to an operation cylinder 103, which is respectively connected to an operation cylinder 103 for rotating the water gate 30 to operate the water gate 30. An oil tank 143 containing oil discharged from the pipe 141 and the open pipe 142, the closed pipe 141 or the open pipe 142, and the oil collected in the oil tank 143 are pumped to close the pipe. An oil pump 144 for supplying to the 141 or the open pipe 142, a control valve 145 for selecting the pipes 141 and 142 to supply the oil pumped through the oil pump 144, and a closed pipe In constructing the hydraulic piping system of the check valves 146 and 147 respectively installed on the 141 and the open pipe 142 to prevent backflow, The bypass pipe 148 is connected to the front and rear ends of the check valve 146 of the closed pipe 141, and the emergency valve 149 is interposed between the bypass pipe 148, and the emergency valve 149 is It is positioned directly below the upper end of the support structure 10, and the upper end of the support structure 10 to be rotatable to the drain side in accordance with the water pressure overflowing the support structure 10 to operate the emergency valve 149 By installing the rotary pressure plate 150, when the flood, power outage, the closing of the water gate 30 occurs at the same time, the water gate 30 is automatically opened by the water pressure of the water flowing over the support structure (10) Eco-friendly method to purify water quality by combining with the system that purifies polluted water quality with clean water. A water channel 211 is formed between both side support structures 210, and housings 220 are respectively covered on opposing surfaces of the both side support structures 210, and both sides are perpendicular to both ends of the arc-shaped sluice plate 231. In the method of purifying the contaminated river water by using a rotating gate that is rotatably fixed between the housing 220, the water gate 230 is fixed to the plate 232, A fixed shaft 233 constituting the rotation center of the water gate 230 penetrates through the housing 220 to be fixed to a wall surface of the support structure 210; A space portion 232a is formed inside the two side plates 232, and a rear end portion of the operation cylinder 240 is fixed to one wall surface of the space portion 232a, and the space portion of the fixed shaft 233 Fixing the operation link 234, the front end of the piston rod 241 of the operation cylinder 240 is rotatably fixed to the operation link 234 by the expansion and contraction of the operation cylinder 240, the side plates 232 ) And opening and closing the waterway 211 while rotating the watermark plate 231 and forming a space between the water gate 230 and the bottom of the housing 220 to discharge the lower layer water of the reservoir space through 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 28, At the rim of the fixed shaft 233, the hydraulic pipes 243 are respectively received to communicate with the space portion 232a of the two side plates 232, and each of the hydraulic pipes 243 is a space of the two side plates 232. Eco-friendly to clean the water quality by combining with the system for purifying contaminated water with clean water, characterized in that it is withdrawn from each of the adjacent operating cylinder 240 installation position located in the portion and connected to the operation cylinder 240, respectively Method. A water channel 211 is formed between both side support structures 210, and housings 220 are respectively covered on opposing surfaces of the both side support structures 210, and both sides are perpendicular to both ends of the arc-shaped sluice plate 231. In the method of purifying the contaminated river water by using a rotating gate that is rotatably fixed between the housing 220, the water gate 230 is fixed to the plate 232, A fixed shaft 233 constituting the rotation center of the water gate 230 is fixed to the wall surface of the support structure 210 through the housing 220; The first operation cylinder 244 is installed on the wall upper reservoir side of the housing 220, and the first support roller 251 is rotatably installed on the horizontal side of the first operation cylinder 244. Connecting a first chain (252) to the reservoir side of the two side plates (232) from the tip of the piston rod (245) of the first operating cylinder (244) via the first support roller (251); The second operation cylinder 246 is installed on the drainage side of the middle portion of the wall of the housing 220, and the second support roller 253 is rotatably installed on the horizontal position of the water storage side of the second operation cylinder 246. The second chain 254 is connected to the drainage side of the two side plates 232 via the second support roller 253 from the tip of the piston rod 247 of the second operation cylinder 246 to the respective operation cylinders (254). 244 and 246 open and close the channel 211 while rotating both side plates 232 and the sluice plate 231 and space between the sluice 230 and the bottom of the housing 220. 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 211 is formed between both side support structures 210, and housings 220 are respectively covered on opposing surfaces of the both side support structures 210, and both sides are perpendicular to both ends of the arc-shaped sluice plate 231. In the method of purifying the contaminated river water by using a rotating gate that is fixed to the water gate 230, the plate 232 is fixed rotatably between the housing 220, opening and closing the waterway 211, A fixed shaft 233 constituting the rotation center of the water gate 230 penetrates through the housing 220 to be fixed to a wall surface of the support structure 210; An actuating cylinder 240 'is rotatably installed at one side of the wall 220 of the housing 220, and a tip of the piston rod 241' of the actuating cylinder 240 'is rotated at the drain side of the both side plates 232. It is possible to connect and open and close the waterway 211 while rotating the two side plate 232 and the watermark plate 231 according to the expansion and contraction of the operation cylinder 240 'and the water gate 230 and the housing 220 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 211 is formed between both side support structures 210, and housings 220 are respectively covered on opposing surfaces of the both side support structures 210, and both sides are perpendicular to both ends of the arc-shaped sluice plate 231. In the method of purifying the contaminated river water by using a rotating gate that is rotatably fixed between the housing 220, the water gate 230 is fixed to the plate 232, A fixed shaft 233 constituting the rotation center of the water gate 230 penetrates through the housing 220 to be fixed to a wall surface of the support structure 210; An airtight space 214 is formed between the housing 220 and the support structure 210, and the operation pipe 246 is inserted into the fixed shaft connection portions of the both side plates 232 to the outside. 246 is located inside the sealed space 214, and the operating link 234 'is fixed to the sealed space position of the operating pipe 246, the operating cylinder 240' on one side of the sealed space 214. ) Is rotatably fixed and the tip of the piston rod 241 'of the actuating cylinder 240' is rotatably connected to the distal end of the actuating link 234 'according to the expansion and contraction of the actuating cylinder 240'. Opening and closing the water channel 211 while rotating the side plate 232 and the watermark plate 231 to form a space between the water gate 230 and the bottom of the housing 220 through which the lower layer of the reservoir space To clean the polluted water by purifying the polluted water by draining the water. Combining environmentally friendly method and system for purifying the water that purifies with. A water channel 211 is formed between both side support structures 210, and housings 220 are respectively covered on opposing surfaces of the both side support structures 210, and both sides are perpendicular to both ends of the arc-shaped sluice plate 231. In the method of purifying the contaminated river water by using a rotating gate that is rotatably fixed between the housing 220, the water gate 230 is fixed to the plate 232, A fixed shaft 233 constituting the rotation center of the water gate 230 penetrates through the housing 220 to be fixed to a wall surface of the support structure 210; A space portion 232a is formed in both side plates 232, and an operation link 234 is fixed at a space portion of the fixed shaft 233, and is horizontal with an end of the operation link of the space portion 232a. An idle roller 237 is positioned on the opposite side, and another idle roller 237 'is rotatably positioned inside the fixed shaft 233, and the idle roller (234) is formed from the distal end of the operation link 234. 237, by connecting the operation cable 238 to draw out through the inside of the fixed shaft 233 via the idle roller 237 'in order to pull or release the operation cable 238 Opening and closing the waterway 211 while rotating both side plates 232 and the sluice plate 231 to form a space between the sluice 230 and the bottom of the housing 220 through which the bottom water of the reservoir space To purify the contaminated water by discharging Eco-friendly method to purify water quality by combining with polluted water quality system to clean water. A water channel 211 is formed between the two support structures 210, and housings 220 are respectively covered on opposite surfaces of the both support structures 210 to form a sealed space 214 therebetween, and the housing 220. Fixed shafts 233 are fixed to the inner side of the support structure 210 through the through, and both sides of the board are provided with a water gate 230 on which both side plates 232 are fixed at right angles to both ends of the arc-shaped hydroplate 231. In the method for purifying the contaminated river water by using a rotational gate made of 232 is rotatably fixed to the fixed shaft 233, respectively, A guide link 249 having a guide groove 249a having a long hole-shaped guide groove 249a extends from the water storage side of the both side plates 232 to the fixed shaft 233 and extends to the sealed space 214. And insert the guide protrusion 231f 'into the guide groove 249a in the sealed space 214, and in a position different from the fixed shaft 233 in the sealed space 214. The operating shaft 257 is rotatably fixed in the same direction, and the opposite end of the guide groove of the driven link 249 is fixed to the operating shaft 257, respectively, from one side of the operating shaft 257. 248 is pulled out and rotatably connected to the tip of the piston rod 241 of the operation cylinder 240 to rotate the water gate 230 according to the expansion and contraction of the operation cylinder 240 to open and close the water channel 211. And form a space between the sluice gate 230 and the bottom of the housing 220. This environmentally-friendly method in conjunction with a system that purifies contaminated water with clean water, characterized in that for purifying contaminated water by discharging the lower layer can be of the water storage space to purify the water through. A water channel 211 is formed between the two support structures 210, and housings 220 are respectively covered on opposite surfaces of the both support structures 210 to form a sealed space 214 therebetween, and the housing 220. Fixed shafts 233 are fixed to the inner side of the support structure 210 through the through, and both sides of the board are provided with a water gate 230 on which both side plates 232 are fixed at right angles to both ends of the arc-shaped hydroplate 231. In the method for purifying the contaminated river water by using a rotational gate made of 232 is rotatably fixed to the fixed shaft 233, respectively, The first guide protrusions 231g and the second guide protrusions 231h are respectively drawn out from the outer sides of the both side plates 232 in the direction of the fixed shaft 233 to extend to the closed space 214, and The first guide rollers 231i and the second guide rollers 231j are respectively inserted into the guide protrusions 231g and 231h, and the first driven link 249 'is placed in contact with the guide rollers 231i and 231j. ) And a second driven link 249 "inside the sealed space 214, and inside the sealed space 214, the first operating shaft in the same direction at a different position from the fixed shaft 233. 257 'and the second actuating shaft 257 "are rotatably fixed respectively to fix each of the driven links 249' and 249" thereto, and each actuating shaft 257 'and 257 " The first drive link 248 'and the second drive link 248 ", respectively, from the end portions of the piston rods 245 and 247 of the first actuating cylinder 244 and the second actuating cylinder 246, respectively. Swivel In order to rotate the water gate 230 according to the expansion and contraction of the respective operation cylinders (244, 246) to open and close the waterway (211) and between the water gate 230 and the bottom of the housing 220 Eco-friendly method for purifying water quality by combining with a system that purifies polluted water with clean water, which forms a space and discharges the lower layer water in the reservoir to purify the polluted water. A water channel 211 is formed between the two support structures 210, and housings 220 are respectively covered on opposite surfaces of the both support structures 210 to form a sealed space 214 therebetween, and the housing 220. Fixed shafts 233 are fixed to the inner side of the support structure 210 through the through, and both sides of the board are provided with a water gate 230 on which both side plates 232 are fixed at right angles to both ends of the arc-shaped hydroplate 231. In the method for purifying the contaminated river water by using a rotational gate made of 232 is rotatably fixed to the fixed shaft 233, respectively, The side plate 232 integrally formed with a rotary tube 233b inserted into the fixed shaft 233 so that the rotary tube 233b is rotatably inserted into the fixed shaft 233, and the rotary tube In the sealed space position of the 233b, the driven gear 256 is press-fitted and fixed integrally, and on one side of the driven gear 256, a driving screw 255 having a diameter smaller than that of the driven gear 256 is provided with the driven gear ( And the drive screw 255 is fixed to the shaft of the drive motor 206 so that the rotational force of the drive motor 106 is fixed to the drive screw 255 and the driven gear 256. The water pipe 211 is opened and closed while the water pipe 230 is transmitted to the rotary tube 233b, and a space is formed between the water gate 230 and the bottom of the housing 220. To purify the contaminated water by discharging the lower layer water Is an eco-friendly method to purify water quality in combination with a system that purifies polluted water with clean water. The method according to any one of claims 1 to 12, 28 and 30 to 36, The lower end portions of the side plates 32 and 232 respectively form a support protrusion 232b in a direction facing each other, and the water gate plates 31 and 231 are mounted on the support protrusion 232b in the state of the bolt 39. Eco-friendly method to purify the water quality by combining with the system for purifying the contaminated water quality to clean water, characterized in that fixed by the configuration. The method according to any one of claims 1 to 12, 28 and 30 to 36, The sluice plates 31 and 231 are fixed to both ends of the middle plate 231c and the top plate 231d of a flat shape on the rounded bottom plate 231b, and the middle plate 231c and the top plate 231d are fixed to each other. Purifying the contaminated water quality with clean water by fixing the H-shaped reinforcing rod 231e to the center of the upper plate 231d, the intermediate plate 231c, and the lower plate 231b so as not to cry or bend. Eco-friendly method to purify water quality by combining with the The method of claim 28 or 33, One side of the side plate 232 is opened to communicate with the space portion 232a, and has a lid 232d to seal the open portion, the bolt 232d against the open portion bolted Eco-friendly method for purifying water by combining with the system for purifying contaminated water with clean water, characterized in that the fastening with (39). The method according to any one of claims 1 to 12, 28 and 30 to 36, The sensing rods 71 are fixed to the reservoir side of the side plates 32 and 232, and a plurality of proximity sensors 72a to 72e are sequentially positioned to sense the position of the sensing rods 71 on the upper portion of the housing 20. And a proximity sensor control buttons 74a to 74e are formed in the control box 73 for controlling the sluices 30 and 230, respectively, according to the number of the proximity sensors 72a to 72e. Eco-friendly method to purify water quality by combining with the system that purifies polluted water quality with clean water. The method according to any one of claims 1 to 12, 28 and 30 to 36, Proximity sensors 272 are installed in proximity to both sides of the sluice plate of the housing 20 based on the open position of the sluice 30 to detect that the sluice 30 is in an open state, and the proximity sensor 272 When the detected signal is transmitted to the integrated control system 100, the integrated control system 100 controls the hydraulic control system 264 to supply oil to power means for providing power to the water gate 30. 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 it is blocked. The method according to any one of claims 1 to 12, 28 and 30 to 36, The support structure (10) after arranging reinforcing bars in the formwork for building the wall for supporting the water gates (30) (230) of the support structure (10) (210) and curing by pouring concrete therebetween. Rotatably fixing the water gate (30) (230) to the wall of (210); In the state in which the formwork 212 is installed on the lower surface of the water gate (30, 230) by connecting the connecting member 213 between the water gate (30) 230 and the formwork (212) the water gate (30) In order to prevent rotation of the 230 and the formwork 212 is integrated with the reinforcing rods to smoothly operate the sluice gate, and to cure by pouring concrete therebetween when the disassembly of the formwork 212 Eco-friendly method to clean the water quality by combining with the system to clean the contaminated water quality to clean water using the process of dismantling the connection member 213 together to install the water during civil engineering. The method according to any one of claims 1 to 12, 28 and 30 to 36, The support structure (10) after arranging reinforcing bars in the formwork for building the wall for supporting the water gates (30) (230) of the support structure (10) (210) and curing by pouring concrete therebetween. Rotatably fixing the water gate (30) (230) to the wall of (210); Between the water gates 30 and 230 and the formwork 212 'in a state in which a formwork 212' having a plurality of coupling pins 212a on a lower surface is installed on the lower surface of the water gates 30 and 230. In order to smoothly operate the revolving door in the state in which the sluice 30 and 230 are integrated with the form 212 ′ so as not to rotate by connecting the connecting member 213 'to the concrete, between the concrete After pouring and curing, only the connection member 213 'is dismantled, and the formwork 212' cleans the polluted water quality by using a process of installing civil engineering facilities to form the bottom of the waterways 11 and 211. Eco-friendly method to purify water quality by combining with water purification system. The method according to any one of claims 1 to 12, 28 and 30 to 36, A latching jaw 291 is formed and provided with a hinge member 290 having an axial rotation part 292 thereon and installed on both sides of the upper end of the sluice plate 31, 231, the plate-shaped leg plate 293 Eco-friendly to clean the water quality in combination with the system for purifying contaminated water quality with clean water, characterized in that it is configured to be rotatably inserted into the locking jaw 291 of the shaft rotation portion 292 of the hinge member 290 Method. The method according to any one of claims 1 to 12, 28 and 30 to 36, The sluice plates 31 and 231 are placed on the plate-shaped support plate 31a with the waterproof plate 31b for blocking leakage, and the reinforcing plate 31c is placed on the upper side thereof, and the bolts 31d and the nuts 31e are placed on the plate. Eco-friendly method for purifying water quality by combining with the system for purifying polluted water with clean water. The method according to any one of claims 1 to 12, 28 and 30 to 36, The center of the round surface 31f formed below the sluice plates 31 and 231 is the rotary shaft 33 or the fixed shaft 233 or the respective rotary shaft portions 109 and 109 'of the operation link 116'. Comprising a large curvature compared to the curvature of the circle around the center, the round surface (20a) formed directly below the sluice of the housing (20, 22) is centered on the rotary shaft 33 or the fixed shaft (233) When the water gates 30 and 230 are opened, both ends of the water gate plates 31 and 231 coincide with both ends of the round surfaces 20a of the housings 20 and 220 when the water gates 30 and 230 are opened. Combined with a system for purifying contaminated water quality with clean water, characterized in that the middle portion of the lower surface of the plate (31) (231) and the middle portion of the round surface (20a) of the housing (20) (220) are separated from each other Eco-friendly method to cleanse. A water channel 211 is formed between the two support structures 210, and housings 220 are respectively covered on opposite surfaces of the both support structures 210 to form a sealed space 214 therebetween. In the method for purifying the contaminated river water by using a rotating water gate provided with a water gate 230 in the waterway 211 to open and close 211), The semi-circular guide rails 280 are formed in the water storage side direction from the lower side of the housing 220 to face the side wall, and the sluice gates each have a semicircular guide protrusion 231f formed on both sides thereof. 231, the guide protrusions 231f are slidably positioned on the guide rails 280, respectively, and the first and second towing cables 282a are provided at upper and lower ends of the guide rails of the sluice plate 231. The first and second towing cables 282a and 282b are connected to the inside of each of the guide rails 280 so as to be movable along the guide rails 280 while connecting the first and second towing cables 282b, respectively. End portions of the towing cables 282a and 282b are respectively wound on the first and second winding rolls 283a and 283b rotatably penetrating the housing 220, and the first and second winding rolls 283a. The first and second windings for rotating the first and second winding rolls 283a and 283b in the closed space position of the 283b. Winding the copper cables 284a and 284b, respectively, and the piston rods 286a and 286b of the first and second operating cylinders 285a and 285b at the free ends of the first and second operating cables 282a and 282b. The front and rear parts of the first and second operating cylinders 285a and 285b to pivot the water gate 230 according to the expansion and contraction of the first and second operating cylinders 285a and 285b. 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 211 is formed between the two support structures 210, and housings 220 are respectively covered on opposite surfaces of the both support structures 210 to form a sealed space 214 therebetween. In the method for purifying the contaminated river water by using a rotating water gate provided in the water passage 211 to open and close 211), The semi-circular guide rails 280 are formed in the water storage side direction from the lower side of the housing 220 to face the side wall, and the sluice gates each have a semicircular guide protrusion 231f formed on both sides thereof. 231 and the guide protrusions 231f are slidably positioned to the guide rails 280, respectively, and the towing cable 282 is connected to an upper end of the guide rail of the sluice plate 231. 282 is positioned inside the guide rail 280 to be movable along the guide rail 280, while receiving the force even when pushing the traction cable 282 and at the same time the guide rail ( A plurality of donut-shaped guide pieces 281 are closely attached to each other so as to be bent along the traction cable 282 so as to be slidably positioned in the guide rail 280. The end of the traction cable 282 is connected to the distal end of the piston rod 286 of the operation cylinder 285 to pivot the water gate 230 according to the expansion and contraction of the operation cylinder 285 to the waterway 211. Purging the polluted water to clean water, characterized in that for opening and closing the water gate 230 and the bottom portion of the housing 220 to form a space to discharge the lower layer water of the reservoir space to clean the polluted water quality Eco-friendly method to purify water quality by combining with the A water channel 11 is formed between the two support structures 10, and housings 20 are respectively covered on opposite surfaces of the both support structures 10, and a closed space 12 is formed therebetween. In the method for purifying the contaminated river water by using a rotating gate provided with a water gate 30 in the waterway 11 to open and close 11), The hydraulic rod 34 'is drawn out upward in an eccentric manner to one side of the sluice plate 31 having an asymmetrical round shape and the rotating shaft 33 is fixed to the upper end of the operating rod 34'. 30, the rotation shaft 33 of the water gate 30 passes through the housing 20 so as to be rotatably fixed to the inside of the support structure 10, and a closed space of the rotation shaft 33. The actuating link 34 is drawn out from the position to fix the tip of the piston rod 241 of the actuating cylinder 240 to the rotatable position, and at the bottom of the housing 20 when the sluice 30 is rotated. In order to avoid interference with the rounded bottom surface of the plate 31, the curvature similar to the curvature of the sluice plate 31 is formed to be rounded downward so that the sluice gate 30 may be hammered in accordance with the expansion and contraction of the operation cylinder 240. By turning to open and close the waterway 11 and the water gate 30 and the housing Eco-friendly to clean the water quality by forming a space between the bottom of the (20) to combine the system to purify the contaminated water with clean water, characterized in that by purging the contaminated water by discharging the lower layer water of the reservoir Method. 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 the water gates 30 open and close the water channels 11. In the method for purifying contaminated river water by using the rotatable rotatable gate, Two stages of rounded steps 13 and 13 'are formed in the bottom portion between the two support structures 10, and the bottom portion of the housing 20 covered therebetween is provided between the two support structures 10. To form a two-stage rounded step (25, 25 ') to be in close contact with the bottom of the, the sluice (30) is formed at both ends of the arc-shaped sluice plate (31) at right angles in a direction perpendicular to both ends And the rotating shafts 33 are fixed to the upper side of the two side plates 32 in the outward direction, respectively, and the two water gates 30 are provided so that the water gate plates 31 are rounded of the housing 20. Positioned at two stepped portions 25 and 25 ', respectively; The two support structures 10 and the housing 20 are each provided with two guide grooves 14 for receiving the rotation shaft 33 of each of the sluices 30 and allowing the entire sluice 30 to be pulled upward. It is formed to accommodate the rotary shaft 33 of the sluice 30, and when the rotary shaft 33 is positioned at the lower end of the guide groove 14, holding the rotary shaft 33 or the sluice 30 A wedge (16) connected to the cylinder (15) is provided at both sides of the lower side of each of the guide grooves (14) so as to release the position of the rotation shaft (33) when moving upward; The first driving motor 106c and the second driving motor 106d are respectively provided on upper portions of the guide grooves of the both side support structures 10, and the first winding rolls 283a and the second winding rolls 283b, respectively. And a working link 34 fixed to one side of the rotation shaft 33 of each of the floodgates 30, and a first working cable between the first winding roll 283a and the front end of the working link 34. 284a, and the first drive motor 106c by connecting a second actuating cable 284b from the distal end of the actuating link 34 to the second winding roll 283b via the rotating shaft 33. Purifying contaminated water quality with clean water by rotating the water gate 30 or pulling the entire water gate 30 upward according to the forward and reverse rotation of the second driving motor 106d. Eco-friendly method to purify water quality by combining with the Both side plates 32 are integrally formed at both ends of the arc-shaped gate plate 31 at right angles, and the water gates 30 of which the rotating shafts 33 are fixed to the upper sides of the side plates 32 in the outward direction are respectively formed. In the method for purifying polluted river water using a rotatable rotatable gate, At least two guide spaces 302 are formed at a lower portion of the dam structure 300 in a horizontal direction to communicate with the reservoir and the discharge portion in a horizontal direction, and the upper portion of the water channel 301 and the dam structure 300 communicate with each other. And a lifting means for inserting and inserting the hydrologic structure 310 into the guide spaces 302, respectively, and lifting and lowering the hydrologic structure 310 on the upper portion of the dam structure 300. It is provided with each, the sluice structure 310 is configured to be rotatable by the operation means to the water gate 30 inside the rectangular housing 311 configured to pass through the front and rear, the bottom portion of the housing 311 Steps 312 are rounded downwards so as not to interfere with the rotational operation of the water gate 30, and the step 303 has multiple steps in accordance with the steps 312 of the housings 311 in the channel 301. The number by the operating means Rotate 30 to open and close the waterway 301 and at the same time discharge the lower layer water in the reservoir to purify the contaminated water quality and tow up the entire hydrological structure 310 entirely by the elevating means. Eco-friendly method to purify the water quality by combining with the system to purify the contaminated water quality with clean water, characterized in that it can be. In the method of purifying the contaminated river water by using a rotating water gate rotatably provided with the water gate 230 integrally formed on both ends of the arc-shaped hydrology plate 231 in a direction perpendicular to both ends, On both sides and bottom of the river "

"Building the support structure 10 of the shape, and fixed to the plurality of support plates 330 in the vertical direction inside the support structure 10, the support structure 10 and the support plate 330, or the respective support plate The water channel 11 is formed between the 330, and the rotation shaft 112 is fixed between the support structure 10, the support plate 330, and each support plate 330, respectively. 112 is rotatably installed in the water gate 230, respectively, so that the space portion 232a is formed inside the two side plates 232 of the water gate 230, the rotating shaft on the upper side of the side plate 232 To allow the 112 to be rotatably inserted, and to extract the operation link 116 from the position of the side plate space of the rotary shaft 112, respectively, one side of the space portion 232a of the both side plate 232 and the operation link ( 116 between the working cylinder 113 rotatably connected to the expansion and contraction of the respective working cylinder 113 In accordance with the system for purifying the contaminated water quality with clean water, characterized in that to rotate the water gates 230 to open and close the waterway 11 and at the same time to discharge the lower layer water of the reservoir space to purify the contaminated water quality. Eco-friendly method to purify the water quality. 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 method to purify the contaminated river water according to the opening and closing of the water gate 30 by rotatably installing the water gate 30 fixed to the plate 32 on both support structures 10, Each of the fitting grooves of the side plate 32 is formed by fixing fitting shafts 233 to the upper side of the sluice 30 both side plates 32, respectively, and fixing the fixed shaft 233 to the both side support structures 10, respectively. (32b) is installed to be rotated by being fitted to the fixed shaft (233); Space portions 12 are formed inside the support structure 10, and rotation shafts 401 and 401 ′ are supported at positions different from the fixed shaft installation positions of the respective space portions 12. 402 is rotatably installed so that the front end portions of the respective rotary shafts 401, 401 'are extended to a position outside the housing 20, and the spaces of the rotary shafts 401, 401' The operation links 403 and 403 'are respectively fixed, and both sides of the water gate 30 are located at positions outside the housing of the respective rotary shafts 401 and 401' according to the rotation of the respective rotary shafts 401 and 401 '. Located on the opposite side of the plate 32 to secure the operating rods 404, 404 'of different lengths to push and rotate the water gate 30 in the closing direction or the opening direction, respectively, the respective space portion 12 The cylinders 405 and 405 'are fixed to one side wall, respectively, and the end portions of the piston rods 406 and 406' of the respective operation cylinders 405 and 405 'are respectively The copper links 403 and 403 'are connected to push to close or open the water gate 30 according to the expansion and contraction of each of the operation cylinders 405 and 405', and at the same time, discharge the lower layer water in the reservoir to contaminate the water. 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 according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, The photovoltaic power generation unit 260 having a solar panel 261, a charging circuit 262 for charging electricity generated through the photovoltaic power generation unit 260, and supplied with electricity collected in the charging circuit 262. Water level sensor 263 for measuring the water level, and the power is supplied from the charging circuit 263 and in accordance with the detection signal of the water level sensor 263, the respective operation cylinder (51, 61, 71, 103, 103 ', 240, 240', 244, 246, 285, 285a) , 285b, 405, the hydraulic unit 264 for controlling the opening and closing of the water gate (30,230) and the central control unit 265 for controlling all the components of the hydrologic drive system, but the charging circuit 262 is wired to be applied to the starting motor 268 for starting the oil pump 266 of the hydraulic unit 264, and the lower portion of the water gates 30 and 230 as much as the inflow quantity flowing down the upstream of the river. To clean up contaminated river water Eco-friendly method to purify the water quality by combining with the system to purify the contaminated water quality with clean water. The method according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, A packing member is disposed at the bottom end of the drain side of the sluice plates 31 and 231 based on the opening of the sluice plates 31 and 231 so as not to leak between the sluice plates 31 and 231 and the housings 20 and 220 when the sluices 30 and 230 are closed. While fixing the 409, foreign matter does not flow into the gap G between the water gates 30 and 230 and the housings 20 and 220, which are secured to secure the moving space of the packing member 409 when the water gates 30 and 230 are opened. Purifying the contaminated water quality with clean water so as to form a stopper 410 integrally in the horizontal direction toward the water storage side at the water storage side ends of the water gate plates 31 and 231 so that the water gates 30 and 230 are opened. Eco-friendly method to purify water quality in combination with the main system. The method according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, At the bottom of the river or river, the support structures 10 and 210 are respectively constructed according to the curvature so that the upper end height of each of the support structures 10 and 210 is gradually lowered toward the center, and the height from the water surface is increased. Each of the support structures 10 and 210 is different from each other, but the water gates 30 and 230 are respectively installed, so that when the closing of each of the water gates 30 and 230, the upper ends thereof are all coincident with the water surface. The height of the 230 is combined with a system for purifying polluted water with clean water, characterized by being configured to gradually increase toward the center, an environmentally friendly method for purifying water quality. The method according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, The reservoirs 1000 are formed by installing the rotary water gates 30 and 230 formed of multiple stages in a river or river having a slope, and each reservoir space 1000 formed through the respective rotary water gates 30 and 230. ) When the water level is all high due to the inflow water flowing from the upstream of the river, each rotary sluice 30, 230 is forced to rotate upward to discharge the amount of water flowing in from the upstream of the river. The water pushes out polluted waters with light specific gravity under the action of gravity and specific gravity and discharges them directly to the other reservoir space 1000 adjacent to the downstream side. According to the law of material cutting action and material preservation instinct, it is pushed by clean water with heavy gravity to the upper side of the storage space 1000 composed of multiple stages. The purification and simultaneously induces such naturally purified by the natural purifying function of purifying the naturally contaminated water through the process of being moved; The polluted waters having a light weight in the upper layer of the stored water stored in each of the storage spaces 1000 are naturally purified by microorganisms generated in each of the storage spaces 1000 and penetrate into the material to be contaminated. Natural purification by osmotic action to destroy and decompose material structure, and pollutants combined with clean water molecules combine with water molecules by material friction action between water molecules and pollutants The natural friction action that destroys and decomposes the molecular structures of pollutants, which are contaminated by self-cleaning, cleansing the polluted water into clean water, natural cleansing by solar heat, and mixed into clean water from the upstream of the river. Actions to purify the contaminated water quality by dilution with dissolved oxygen present in the installation stages of the rotary water gates 30 and 230 Eco-friendly method for purifying the water quality by combining with the system for purifying the contaminated water quality to clean water, characterized in that it is made naturally inside each storage space (1000) configured according to the system. The method according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, On the basis of the opening of the water gates 30 and 230, the packing member 409 is fixed to the bottom side of the water gate plate 310 (231) of the water gates 30 and 230, and the water gate 30 ( The foreign material removal plate 411 which is extended to the rounded portion of the support structure 10 and 210 is fixed to the lower portion of the sluice plate 31, 231 on the drain side of the sluice plate 31, 231. 30) 230 purifies the water quality by combining with a system for purifying contaminated water quality with clean water, characterized in that to remove foreign substances introduced into the rounded portion of the support structure (10, 210) during the rotation operation Environmentally friendly method. The method according to any one of claims 1 to 12, 28, 30 to 36, 47 to 53, An introduction part 421 extending in a streamline form from the round surface of the sluice plates 31 and 231 on the rounded surface of the sluice plates 31 and 231 based on the closing time of the sluice plates 30 and 230. And a foreign material collection groove 420 having a space portion 422 in which a light specific gravity material is collected and a jaw 423 which prevents light pollutants from coming out of the specific gravity collected therein. Combined with a system for purifying contaminated water quality with clean water, characterized in that the pollutants having a low specific gravity when discharged to the bottom through the space between the support structures (10, 210) can not be carried down by water pressure or water flow. Eco-friendly method to purify water quality.

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