KR101388997B1 - Contaminat collecting and circulation apparatus using a siphon pipe - Google Patents

Abstract

The present invention relates to a device for collecting pollutants using a siphon pipe and, more specifically, to a system for collecting pollutants and circulating and purifying polluted sea water by discharging turbid water and pollutants inside a harbor to the outside of the harbor using the pressure difference between the inside and the outside of the harbor with a breakwater interposed therebetween. The present invention provides a device for collecting pollutants using a siphon pipe, which comprises: a siphon pipe including an inner harbor side vertical pipe vertically formed inside a harbor, an air side passing pipe integrally connected to the upper end of the inner harbor side vertical pipe to pass over a breakwater, an outer harbor side pipe integrated with the air side passing pipe and having an outlet provided below the sea level outside the harbor, and a plurality of inner harbor side inlet pipes provided at the different heights of the inner harbor side vertical pipe to be opened and closed; a pressure feeding means installed on the siphon pipe and applying pressure to discharge sea water through the outlet; and a pollutant collecting unit for collecting foreign substances discharged from the outlet together with the sea water.

Description

CONTAMINAT COLLECTING AND CIRCULATION APPARATUS USING A SIPHON PIPE}

The present invention relates to a contaminant collection and contaminant seawater circulation purification device using a siphon tube, and more particularly, by using the pressure difference between the inside and the outside of a port with a breakwater in between. The present invention relates to an apparatus for collecting pollutants by circulating and circulating and purifying polluted seawater.

In general, all ports are exposed to pollutants from fishing vessels and ships, and because of their structural characteristics, they are vulnerable to the circulation of the sea. Therefore, the water quality is deteriorating, but in the event of a typhoon or storm, the seawater is disturbed or the existing breakwater is changed to change the form of the port. Unless changed, there is no proper solution to seawater pollution. As such a solution, conventionally, the seawater channel was placed at the lower part of the breakwater to communicate the inside and the outside of the harbor, but the area was excessively large, and only the effect of seawater exchange due to the diffusion was achieved rather than discharging the pollutants inside the harbor. The exchange of seawater between the inner and outer ports was not as smooth as expected.

In addition, it is possible to discharge pollutants inside the port to the outside by using a pump, etc., but because the power must be continuously supplied, power consumption costs are high, and there is a problem that a failure of the pump due to long-term use may occur. .

Related prior arts include the Republic of Korea Patent Publication No. 20-2011-0009817 (published November 14, 2011) 'siphon channel having a compressed air removal means.

SUMMARY OF THE INVENTION An object of the present invention is to provide a pollutant collection and polluted seawater circulation purifying apparatus which collects pollutants at the same time by circulating and purifying polluted water and pollutants in the harbor to the outside.

Another object of the present invention is to provide a contaminant collection and polluted seawater circulating device capable of circulating and purifying polluted seawater in a port by discharging inlets at different heights, and discharging or collecting various pollutants contained in the seawater. have.

The present invention relates to an inner vertical tube formed perpendicularly to the inner side of the port, an atmosphere side diesel pipe integrally connected to an upper end of the inner side vertical pipe and passing through an upper portion of the breakwater, and integrally formed with the atmospheric side diesel pipe. A siphon tube including a plurality of anti-inner tubes disposed at different heights of the anti-inner tube and a discharge inner portion below the sea surface, and each of which is formed to be opened and closed; A pressure feeding means installed on the siphon tube to apply pressure to discharge sea water through the discharge port; It provides a contaminant collection and polluted seawater circulation purification apparatus using a siphon tube, including; and a contaminant collecting unit for collecting the foreign matter discharged with the seawater at the discharge port.

The contaminant collecting unit preferably includes an outer network fixed to the breakwater or the seabed, and an inner network detachably received inside the outer network.

At this time, the outer network and the inner network is a lower portion of the tubular shape of a watertight structure for receiving sea water, the upper portion is more preferably formed of a network to communicate the sea water.

In addition, the inner mesh is more preferable if the bottom surface can be opened and closed.

And, it may be further connected to the exhaust means for discharging the air collected in the siphon tube is connected to the air passage pipe of the siphon tube.

The exhaust means may include a gas collecting part extending vertically upward from the atmospheric gas passage and a vacuum pump for discharging the fluid inside the gas collecting part to the outside.

Furthermore, it is more preferable to include a water level sensor for detecting the water level inside the gas collecting unit, and operate the vacuum pump according to the detection of the water level sensor.

The pollutant collecting device according to the present invention discharges the seawater containing the pollutants in the harbor to the outside of the harbor using the principle of siphon, and by collecting them, the seawater in the harbor can be kept clean.

In addition, by collecting the pollutants in the pollutant collecting unit instead of simply discharging the pollutants to the port, it also brings about the effect of preventing the contamination of the extra seawater due to the pollutants in the port.

1 is a block diagram showing a contaminant collection and polluted seawater circulation purification apparatus using a siphon tube according to an embodiment of the present invention,
Figure 2 is a block diagram showing a pollutant collection and polluted seawater circulation purification apparatus using a siphon tube according to another embodiment of the present invention,
3 is a block diagram showing the exhaust means of the pollutant collection and polluted seawater circulation using the siphon tube of the present invention,
Figure 4 is a block diagram showing the contaminant collection unit of the pollutant collection and polluted seawater circulation using the siphon tube according to the present invention.

Hereinafter, with reference to the accompanying drawings it will be described with respect to the pollutant collection and polluted seawater circulation using the siphon tube according to an embodiment of the present invention.

BRIEF DESCRIPTION OF THE DRAWINGS The above and other features and advantages of the present invention will become more apparent by describing in detail exemplary embodiments thereof with reference to the attached drawings in which: It is intended that the invention be described in its entirety by reference to the appended claims and their equivalents. In the following description, well-known functions or constructions are not described in detail since they would obscure the invention in unnecessary detail.

1 is a block diagram showing a contaminant collection and polluted seawater circulation purification apparatus using a siphon tube according to an embodiment of the present invention.

As shown, the pollutant collection and contaminated seawater circulation purification apparatus using a siphon tube according to an embodiment of the present invention by connecting the inner and the outer side of the siphon siphon tube to discharge the seawater inside the harbor on the principle of siphon 110, a pressure feeding means 120 installed on the siphon tube 110 to pressurize the seawater to be discharged through the outlet 117 of the siphon tube 110, together with the seawater at the outlet 117. It includes a contaminant collecting unit 130 for collecting the discharged foreign matter.

Siphon pipe 110 is to transfer the seawater inside the port to the port outside without a separate power through the principle of siphon, it is provided with a pressure-feeding means 120 for faster seawater flow. Operation of the pressure-feeding means 120 generates a faster flow of seawater, thereby improving the collection rate of contaminated seawater. The pressurizing means 120 may operate only when necessary, rather than always operating. Various pumps may be used as the pressure feeding means 120.

In the inner and outer sides of the breakwater, the difference in the flow due to the action of the wave occurs. In other words, the inner side of the harbor is calm due to the blocking of the blue energy of the breakwater. The action of blue is active. Therefore, the average sleep is lowered than the inner surface of the breakwater in front of the breakwater, and the difference in the periodic flow is greatly generated. Therefore, if a siphon tube is connected between the front of the breakwater caused by the blue wave and the relatively quiet breakwater back, the flow from the inner side to the outer side is always generated.

As shown in the figure, when the siphon is installed over the breakwater, the contaminated seawater is discharged outward. In addition to the outward flow due to the difference in mean water level, the relatively small water pressure is continuously generated by the periodic flow caused by the wave action around the siphon outlet, resulting in a considerably large flow rate of seawater drawn out through the pipe.

The siphon tube 110 is an anti-inner vertical tube 112 which is formed perpendicular to the inner side of the port, and an air-side diesel pipe 114 that is integrally connected to the upper end of the inner inner vertical tube 112 and passes over the breakwater. The anti-outer tube 116 is formed integrally with the atmospheric gas passage 114 and has a discharge port 117 under the sea surface of the outer side, and is provided at different heights of the inner inner vertical tube 112. Each of the plurality of the inner inlet pipe 113 is formed to be opened and closed.

The inlet pipe 113 is formed in a plurality of different heights, it is formed to selectively open and close. Therefore, the seawater of a specific level may be selected to be introduced into the siphon tube (110). There are various kinds of contaminants in the seawater in the port, and it is to make it possible to collect the contaminants by discharging the seawater at a certain level according to the state of seawater pollution.

The contaminant collecting unit 130 is for collecting and collecting contaminants from seawater mixed with contaminants discharged from the discharge port 117, and the seawater mixed with the contaminant discharged from the discharge port 117 collects the contaminant collecting unit 130. After being filtered through, it is discharged.

The pollutant collecting unit 130 includes an outer mesh 132 fixed to a breakwater or seabed, and an inner mesh 134 separably received inside the outer mesh, so that the pollutants are collected in the inner mesh 134. It is preferable to float the inner mesh 134 so that the collected pollutants can be collected separately.

Atmospheric side oil passage 114 passes through the upper end of the breakwater, and in the case of a breakwater that passes, the atmospheric side oil passage 114 is buried at the upper end of the breakwater, as shown in FIG. It is desirable that 114 does not interfere with the passage of pedestrians or vehicles.

However, in the case of a breakwater that does not require passage, as shown in FIG. 2, the air-side diesel pipe 114 may be formed in the form of being exposed to the upper end of the breakwater.

2 is a block diagram showing a contaminant collection and polluted seawater circulation purification apparatus using a siphon tube according to another embodiment of the present invention, Figure 3 is a contaminant collection and exhaust water of the contaminated seawater circulation purification apparatus using a siphon tube of the present invention The configuration diagram is shown.

The siphon tube 110 operates smoothly when the inside is filled with seawater, and when the use time elapses, bubbles may accumulate inside and the seawater may not flow smoothly.

In view of this, the present invention may be provided with the exhaust means 140 in the atmosphere side oil passage (114).

As shown in FIG. 3, the exhaust means 140 includes a gas collecting part 142 extending upwardly perpendicular to the atmospheric side gas passage 114 of the siphon tube 100, and inside the gas collecting part 142. It includes a vacuum pump 144 for discharging the fluid (air or air and sea water) to the outside.

In the case of the evacuation means 140, in the case of the breakwater requiring passage, it is preferable to be disposed on one side of the breakwater so as not to interfere with the passage of the pedestrian and the vehicle.

The gas collecting unit 142 is preferably provided at the highest portion of the atmosphere side oil passage 114. To this end, the atmosphere side oil passage 114 may be formed to have a gradient to one side, and in this case, the gas collecting part 142 is formed at the top of the highest side.

Since air rises above the seawater, bubbles mixed in the seawater are collected in the gas collecting unit 142.

When there is no air in the gas collecting unit 142, the water is filled with sea water, and as the bubbles are collected, the water level of the gas collecting unit 142 is lowered.

When the level of the gas collecting unit 142 is lowered, the vacuum pump 144 is operated to extract the air inside the gas collecting unit 142 to the outside, and the gas collecting unit 142 is filled with seawater again.

At this time, in order to operate the vacuum pump 144 automatically, the gas level collecting unit 142 may be provided with a level sensor 146 for detecting the water level.

When the water level sensor 146 is lowered to a certain level inside the gas collecting unit 142, the vacuum pump 144 is to operate.

Through this operation, the siphon tube 110 can be smoothly operated by discharging the air inside the siphon tube 110.

4 is a block diagram showing a contaminant collecting unit of the contaminant collecting device using a siphon tube according to the present invention.

As shown, the outer mesh 132 is fixed to a breakwater or seabed, and is connected to the outlet 117 of the siphon tube 100.

The inner mesh 134 is detachably housed in the outer mesh 132.

The outer mesh 132 and the inner mesh 134 both include lower cylinders 132a and 134a having a watertight structure, and upper meshes 132b and 134b connected upwardly of the lower cylinders 132a and 134a.

When the contaminants enter the inside of the inner mesh 134 together with the seawater through the outlet 117, the seawater temporarily stays in the inner mesh 134 and is discharged to the outside through the upper mesh 134b. In this process, contaminants remain inside the internal network 134.

The lower cylinder 134a of the inner mesh 134 is confined to prevent seawater from being discharged to the outside, so that the pollutants having a small size can sink in the confined seawater.

When contaminants accumulate on the inner mesh 134, the inner mesh 134 is lifted to empty the contaminants of the inner mesh 132. For this purpose, the bottom surface 134c of the inner mesh 134 may be opened and closed. .

Hereinafter, embodiments of the present invention have been described with reference to the accompanying drawings, but the present invention is not limited to the above embodiments, but may be manufactured in various forms, and having ordinary skill in the art to which the present invention pertains. It will be understood by those skilled in the art that the present invention may be embodied in other specific forms without changing to the spirit or essential features of the invention. It is therefore to be understood that the above-described embodiments are illustrative in all aspects and not restrictive.

110: siphon tube
113: inlet pipe
112: vertical inner tube
114: atmospheric route pipe
116: outer side pipe
117: Outlet
120: conveying means
130: pollutant collecting unit
132: external mesh
134: internal mesh
140: exhaust means
142: gas collection unit
144: vacuum pump
146 level sensor

Claims (10)

The inner inner vertical pipe formed perpendicular to the inner side of the port, the atmospheric side pipe which is integrally connected to the upper end of the inner inner vertical pipe and passes to the upper part of the breakwater, and the sea surface of the outer side which is formed integrally with the atmospheric side pipe A siphon tube including a plurality of anti-inner tubes provided at different heights of the anti-outer tube having a discharge port and a lower inner vertical tube, each of which is formed to be opened and closed;
A pressure feeding means installed on the siphon tube to apply pressure to discharge sea water through the discharge port;
A contaminant collecting unit collecting foreign substances discharged together with sea water from the discharge port; And
And exhaust means connected to an atmospheric gas passage of the siphon tube to discharge air collected in the siphon tube.
The exhaust means is
A gas collecting portion extending vertically upward from the atmospheric gas passage,
Pollutant collection and polluted seawater circulation purification apparatus using a siphon tube, characterized in that it comprises a vacuum pump for discharging the fluid inside the gas collecting unit to the outside.
The method according to claim 1,
The pollutant collecting unit
External mesh fixed to a breakwater or seabed,
Pollutant collection and contaminated seawater circulation purification apparatus using a siphon tube, characterized in that it comprises an inner network detachably received inside the outer network.
3. The method of claim 2,
The outer network and the inner network
The lower part is a watertight tubular shape to accommodate seawater.
The upper portion is a contaminant collection and polluted seawater circulation purification device using a siphon tube, characterized in that formed by the network to communicate the seawater.
The method of claim 3, wherein
The inner mesh
Pollutant collection and polluted seawater circulation purification device using a siphon tube, characterized in that the bottom surface can be opened and closed.
delete delete The method according to claim 1,
It is provided with a water level sensor for detecting the water level inside the gas collecting unit,
Pollutant collection and polluted seawater purification apparatus using a siphon tube, characterized in that for operating the vacuum pump in response to the detection of the water level sensor.
The method according to claim 1,
The exhaust means is a pollutant collection and polluted seawater circulation purification apparatus using a siphon tube, characterized in that disposed on one side edge of the breakwater.

The method according to claim 1,
The atmospheric side diesel pipe is a pollutant collection and polluted seawater circulation purification device using a siphon tube, characterized in that the buried in the upper end of the breakwater.
The method according to claim 1,
The atmospheric side gas pipe is exposed to the upper end of the breakwater pollutant collection and contaminated seawater circulation purification apparatus using a siphon tube.

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