KR101122053B1 - Water treatment apparatus - Google Patents

Abstract

PURPOSE: A water treating apparatus is provided to improve water quality purifying capability and to reduce power loss by reducing resistance applied to a main bar in case of the rotation of the main bar. CONSTITUTION: A water treating apparatus includes a main body(110), a connecting bar(140), and a water purifying fan unit(150). The main body is loaded on the surface of water purifying target. The connecting bar is in connection with a shaft(111) which is arranged at the center region of the main body. The water purifying fan unit is in combined with the end part of the connecting bar. The water purifying fan unit includes a fan unit, a plurality of main bars, and inclined bars. The connecting bar is in connection with the fan unit. The main bars include fixing rods, length expandable rods, and a plurality of resistance reducing through holes. The fixing rods are radially arranged based on the fan unit. The resistance-reducing through holes are arranged at the fixing rods and the length expandable rods. The inclined bars are arranged at the end parts of the length expandable rods.

Description

Water Purifier {WATER TREATMENT APPARATUS}

The present invention relates to a water purification device, and more particularly, the energy consumption is low compared to the amount of water movement, and thus the water purification ability can be improved compared to the energy consumption, and in particular, the length of the main bar is adjusted to the water purification area. The present invention relates to a water purification device that can cope adaptively and that can significantly reduce power loss by significantly reducing the resistance received by the main bar when the main bar rotates due to the resistance reducing holes.

Recently, due to the rapid economic growth and improved living standards, environmental pollution is becoming a major problem, and water pollution is becoming more serious, causing seasonal imbalances in water supply and demand due to seasonal and regional differences in rainfall during the year. Many reservoirs have been built to address this imbalance in water supply and demand.

However, in many artificial lakes, natural lakes, reservoirs, and fish farms that are distributed throughout the country, water does not flow and stagnate and has not been treated for long periods of time, resulting in the inflow of sewage or wastewater such as agricultural residues, livestock wastewater and domestic sewage. Water quality is deteriorating.

As a result, water purification has been attempted periodically for dredging, chemical spraying, and aeration of reservoirs and lakes, but there are many problems such as costly effects and temporary effects on ecosystems.

For example, spraying algae, a chemical that kills algae to improve water quality in reservoirs or lakes, is very effective, but the chemicals concentrate in lake sediments and the algae's resistance to algae increases. In the long run, the killing effect is reduced, and there is a problem that chemicals adversely affect aquatic organisms.

In addition, the method of flocculating sedimentation of nutrients by administering a flocculant such as aluminum salt or iron salt is quick and inexpensive, but the water purification effect is small in shallow waters of reservoirs or lakes, and after a few years, it is flocculated by flocculant. There is a problem that the precipitated phosphorus can be eluted again.

In addition, when stratification occurs in a lake or reservoir, the aerobic process is destroyed by aeration of air into the lake to destroy the strata, mix water and air to supply oxygen, and promote decomposition by microorganisms. Although the effect is great, the cost or effect is very small in shallow or elongated lakes or reservoirs.

In addition, the method of removing the sediment of the bottom of the lake or reservoir has a large water quality improvement effect, but there is a problem that the dredging cost is expensive and can destroy or change the underwater ecosystem.

In order to solve this problem, a rotating water purification fan for rotating and purifying water in a lake or a reservoir by rotating by operation of a built-in electric motor supported on the water surface has been developed and is currently being applied in part.

1 is an external view of a conventional self-cleaning water purification fan, FIG. 2 is a structure diagram of a conventional self-cleaning water purification fan, and FIG. 3 is a state diagram of a conventional self-cleaning water purification fan.

Referring to these drawings, the conventional rotating water purification fan 11 is fixed by a fixture 13 such as an anchor, a concrete block, an electric motor (not shown) is built in, and provided from its own buoyancy and buoy 14. The buoyancy is buoyant on the water surface of the lake and reservoir, and is provided to rotate at a low speed of 2 to 4 rpm by the operation of the electric motor.

When the rotational flow by the rotation of the rotating water purification fan 11 having the structure as described above is transmitted to the inside of the lake, the water flows in the rotating direction of the rotating water purification fan 11 at the water surface, the water to the water surface in the water This rising flow field is formed and the water at the bottom of the lake rises and circulates upwards.

This water circulation eliminates oxygen deficiency in the water, and organic matter is decomposed by the metabolism of microorganisms to purify the water quality.

The rotating water purification fan 11 as described above is simple in structure and low in equipment cost, requires less power at a rotational speed of 2 to 4 rpm, and is environmentally friendly due to a small impact on the ecosystem.

However, because the rotating water purification fan that is simply rotating is limited to the area around the fan to purify the water quality, a large number of rotating water purification fans must be installed to purify a large area of lake or reservoir. Accordingly, there is a problem in that the equipment cost or maintenance cost is excessively consumed.

On the other hand, Korean Patent Office Publication No. 10-2004-0053560 discloses a eutrophication prevention device. The technique disclosed in this document relates to an eutrophication prevention device that can be applied irrespective of the area of a lake, a swamp, a pond, and the like by allowing the rotor blade to rotate as well as to rotate.

However, in the case of the prior art, including the technology disclosed in the above document, since the structure of the rotary blades has a straight shape, the energy consumption is inevitably high compared to the amount of water movement, and as a result, there is a problem in that water purification ability is inferior to energy consumption. It is urgent to prepare appropriate measures for this.

Korean Patent Office Publication No. 10-2004-0053560

An object of the present invention, the energy consumption is lower than the amount of water movement can improve the water purification capacity compared to the energy consumption, as well as to adapt to the water purification target area by adjusting the length of the main bar, in particular, for reducing the resistance Through holes significantly reduce the resistance the main bar receives during rotation of the main bar, providing a water purification system that can significantly reduce power loss.

The object is an apparatus body seated on the surface of the water purification object; A connection bar connected to a shaft disposed in a central region of the apparatus body; And a water purification fan unit coupled to an end of the connection bar, wherein the water purification fan unit comprises: a fan unit to which the connection bar is connected; A fixed rod disposed radially with respect to the fan unit, a length extension rod coupled to the fixed rod so as to extend in length, and a plurality of resistors provided on the fixed rod and the length extension rod to reduce resistance during rotation; A plurality of main bars with reducing apertures; And an inclined bar disposed at the ends of the length bar of the main bar, the inclined bar being inclined at a predetermined angle with respect to the main bars.

The inclined bar may be integrally connected to or detachably connected to the main bar.

The inclined bar may have an inclination angle of 30 degrees to 60 degrees with respect to the rotation direction of the water purification fan unit.

One side of the inclined bar may be further provided with a wing wall for doubling the flow of water.

The wing wall, the fixed wing wall; And at least one additional wing wall detachably connected to the fixed wing wall to double the contact area of water with the fixed wing wall.

Three or four main bars may be provided based on the fan unit.

The main bar may be provided to be adjustable in length.

The connection bars may be provided in pairs symmetrically on both sides of the apparatus body, and the water purification fan units may be provided at ends of the pair of connection bars, respectively.

After the length between the fixing rod and the length extension rod is determined, it may further include a bolt inserted into the through hole for resistance reduction to fix the length between the fixing rod and the length extension rod.

According to the present invention, the energy consumption is low compared to the amount of water movement, and the water purification ability can be improved compared to the energy consumption, and in particular, by adjusting the length of the main bar, it is possible to adaptively cope with the target area for water purification, and to reduce the resistance through air. Due to this, the resistance of the main bar during the rotation of the main bar is significantly reduced, thereby reducing the power loss.

1 is an external view of a conventional rotating water purification fan.
Figure 2 is a structure diagram of the installation of a conventional self-cleaning water purification fan.
Figure 3 is a state diagram of the operation of the conventional rotating water purification fan.
4 is a perspective view of a water purification apparatus according to a first embodiment of the present invention.
5 is a structural diagram according to the installation state of FIG.
6 is a schematic plan view of FIG. 5;
7 is an enlarged perspective view of the fan unit for water purification shown in FIG. 4.
8 is a plan view of FIG. 7.
9 is a perspective view of a fan unit for water purification in the water purification apparatus according to the second embodiment of the present invention.
10 is a perspective view of a fan unit for water purification in the water purification apparatus according to the third embodiment of the present invention.
11 is a plan view of the fan unit for water purification in the water purification apparatus according to the fourth embodiment of the present invention.
12 is a plan view of the water purification apparatus according to the fifth embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings will be described a preferred embodiment of the present invention.

4 is a perspective view of a water purification apparatus according to a first embodiment of the present invention, FIG. 5 is a structural diagram according to an installation state of FIG. 4, FIG. 6 is a schematic plan view of FIG. 5, and FIG. 7 is shown in FIG. 4. 8 is an enlarged perspective view of the fan unit for water quality purification, and FIG. 8 is a plan view of FIG.

Referring to these drawings, the water purification apparatus of this embodiment includes a connection bar connected to the apparatus main body 110 seated on the surface of the water purification target and the shaft 111 disposed in the central region of the apparatus main body 110 ( 140 and a fan unit 150 for water purification coupled to an end of the connection bar 140.

The apparatus body 110 will be described first, and the apparatus body 110 forms a central skeleton of the water purification apparatus seated on the surface of the water purification object.

A support pawl 112 is provided at the center of the device body 110. The support pole 112 may maintain a stable posture on the surface of the water by buoyancy and serves to stably support the fan unit 150 for water purification.

The support poles 112 are connected by wires W1 and W2 by fixing blocks 113 and 114 such as anchors, concrete blocks B, and the like. That is, the lower flange 115 and the upper flange 116 provided on the lower and upper portions of the support pole 112 may be connected by the fixing blocks 113 and 114 and the wires W1 and W2.

By applying such a fixed structure, it may be helpful to maintain a stable posture of the support pole 112 even in extreme conditions in a stagnant body of water, for example, on a windy day or a rainy day.

As described above, the support pole 112 is to maintain a stable posture on the surface by buoyancy, for this purpose is provided with a weight 117 in the lower center region. The weight of the weight 117 can be appropriately designed.

The connection bar 140 is configured to connect the apparatus main body 110 and the water purification fan unit 150.

On the other hand, the water purification fan unit 150 is connected by the connection bar 140 on the basis of the device body 110, the revolution according to the rotation is induced to purify the water quality.

The water purification fan unit 150 includes a fan unit 151 to which the connection bar 140 is connected, a plurality of main bars 152 disposed radially with respect to the fan unit 151, and a main bar ( An inclined bar 153 disposed at the end of the 152 and inclined at a predetermined angle with respect to the main bars 152. In addition, the water purification fan unit 150 further includes a wing wall 154 coupled to one side of the inclined bar 153 to double the flow of water.

An electric motor (not shown) is provided inside the fan unit 151, and may be rotated at, for example, 2 to 4 rpm by the electric motor. When the rotational flow of water by the rotation is transmitted to the inside of the lake, the water flows in the rotating direction of the water purification fan unit 150 at the surface of the water, thereby forming a flow field in which the water rises to the surface of the water to the water of the lake bottom It will cycle up and up (see arrow in FIG. 5). The circulation of water eliminates oxygen deficiency in the water, and organic matter is decomposed by the metabolism of microorganisms, thereby purifying water quality.

At this time, since the water purification fan unit 150 that revolves on the basis of the shaft 111 of the device body 110 naturally revolves on the water surface by its rotating moment, the device body 110 includes a fan unit for water purification ( No power means such as a motor to idle 150 is provided. That is, the support pole 112 merely supports the water purification fan unit 150 connected by the connection bar 140 to induce revolutions, and provides power required for the revolution to the water purification fan unit 150. It is not.

Specifically, one end of the connection bar 140 is rotatably inserted into the shaft 111 by a boss 141, for example, a boss 141 such as a bearing, and a fan for water purification at the other end of the connection bar 140. The unit 150 has a structure that is rotatably connected. Accordingly, as the water purifying fan unit 150 rotates, the connecting bar 140 is rotated radially about the shaft 111 by the rotation moment thereof, thereby inducing the revolution of the water purifying fan unit 150. have.

In other words, since the water purifying fan unit 150 of the present invention is rotatably connected to the shaft 111 by the connecting bar 140, the water purifying fan unit 150 is rotated by the rotating moment generated while the water purifying fan unit 150 is rotated. By revolving, it is possible to purify water of, for example, eight times more water than a simple water purification fan unit. That is, forcibly rotating the water purification fan unit 150 connected to the shaft 111 by the connection bar 140 generates a rotation moment in the water purification fan unit 150, which is connected to the connection bar 140. By inducing the revolution around the shaft 111, which can cover the surface of a much larger area than the conventional water purification fan fixed at a specific point, as a result, it is possible to purify the water quality of a wider body of water Will be.

The structure of the water purification fan unit 150 will be described in more detail with reference to FIGS. 7 and 8.

The fan unit 151 is a place where an electric motor or the like is installed, and the plurality of main bars 152 are disposed radially based on the fan unit 151. In the present embodiment, three main bars 152 are provided based on the fan unit 151.

Longer length of the main bar 152 may purify the water in a wider body of water. Therefore, if the length of the main bar 152 can be changed to provide a more advantageous effect, in consideration of this point, the main bar 152 may be provided as a length adjustable, for example, a telescopic bar.

Let's look at this more specifically. In the present embodiment, the main bar 152 may include a fixed bar 159 disposed radially with respect to the fan unit 151 and a length bar 158 coupled to the fixed bar 159 so as to extend in length. Equipped.

Since the volume of the fixed bar 159 is slightly smaller and the volume of the length bar 158 is slightly larger, the length of the fixed bar 159 and the length bar 158 is adjusted to each other. As such, when the lengths of the fixed bar 159 and the length extension bar 158 are mutually adjusted, it is possible to adaptively cope with the place where the device is disposed. In particular, it is advantageous to purify water in a wider body of water.

A plurality of resistance reducing holes 159a and 158a are formed in the fixed bar 159 and the length extension bar 158, respectively. The resistance reducing through holes 159a and 158a serve to reduce resistance to the main bar 152 when the main bar 152 rotates. That is, since water may escape through the resistance reducing through holes 159a and 158a when the main bar 152 rotates, resistance due to the rotation of the main bar 152 may be reduced, thereby reducing power loss. The resistance reducing apertures 159a and 158a are more advantageously long holes as shown.

When the length adjustment between the fixed bar 159 and the length extension bar 158 is completed, the bolts may be formed by resistance reducing through holes 159a and 158a formed in the fixed bar 159 and the length extension bar 158 as shown. The fixed bar 159 and the length extension bar 158 may be tightened by inserting B).

Inclined bars 153 are respectively coupled to the ends of main bar 152. That is, the inclined bar 153 is disposed to be inclined at a predetermined angle with respect to the main bars 152. At this time, the inclined bar 153 may be integrally connected to the main bar 152 or otherwise detachably connected.

The inclined bar 153 may have an inclination angle of 30 degrees to 60 degrees with respect to the rotation direction of the water purification fan unit 150. In this embodiment, the inclined bar 153 is manufactured to have an inclination angle of 45 degrees. And the wing wall 154 is coupled to one side of the inclined bar 153 serves to double the flow of water.

As such, by applying the inclined bar 153 to which the wing wall 154 is connected, there is an advantage of reducing the amount of energy and increasing the amount of water movement compared to the amount of water movement. That is, since the friction of water in contact with the wing wall 154 can be reduced by half, for example, the effect of energy reduction can be expected.

According to the present invention having such a structure, the energy consumption is low compared to the amount of water movement, and the water purification ability can be improved compared to the energy consumption, and in particular, the length of the main bar 152 is adjusted to be adaptive to the water purification target region. The resistance reduction through holes 159a and 158a may significantly reduce the resistance received by the main bar 152 when the main bar 152 rotates, thereby significantly reducing power loss.

9 is a perspective view of a fan unit for water purification in the water purification apparatus according to the second embodiment of the present invention.

Referring to this figure, the water purifying fan unit 250 in this embodiment has the structure of the wing wall 254 is different from that of the first embodiment, and many of the structures of the fan unit 250 are the same as those of the first embodiment described above.

That is, in the present embodiment, the wing wall 254 includes a fixed wing wall 255 and an additional wing wall 256 detachably connected to the fixed wing wall 255 to double the contact area of the water with the fixed wing wall 255. Doing. When the additional wing wall 256 is applied in this way, the area can be increased compared to the wing wall 154 of the first embodiment, so that the amount of movement of water is increased, which is much more helpful for water purification. In the present embodiment, the additional wing wall 256 is applied to a structure fitted to the fixed wing wall 255.

10 is a perspective view of a fan unit for water purification in the water purification apparatus according to the third embodiment of the present invention.

Referring to this figure, the fan unit 350 for water purification in the present embodiment also has the structure of the wing wall 354 different from the first embodiment, and the structure of many of the above-described first embodiment is the same.

That is, in the present embodiment, the wing wall 354 includes a fixed wing wall 355 and an additional wing wall 356 detachably connected to the fixed wing wall 355 to double the contact area of the water with the fixed wing wall 355. Doing. When the additional wing wall 356 is applied in this way, the area can be increased compared to the wing wall 154 of the first embodiment, so that the amount of movement of water is increased, which is much more helpful for water purification. In the present embodiment, the additional wing wall 356 is applied in a structure in which the bolt 357 is assembled on the side wall of the fixed wing wall 355.

FIG. 11 is a plan view of the fan unit for water purification in the water purification apparatus according to the fourth embodiment of the present invention.

Referring to this figure, in the case of the water purification fan unit 450 in the present embodiment, four main bars 452 are radially connected to the fan unit 451, and ends of the respective main bars 452 are provided. The inclination bar 453 is shown in the structure is connected. Even if such a structure is applied, it is helpful for water purification.

12 is a plan view of the water purification apparatus according to the fifth embodiment of the present invention.

In this embodiment, the connection bar 340 is provided in a pair symmetrically on both sides of the device body 110, the water purification fan unit 550 is provided at each end of the pair of connection bar 340, respectively Proposed structure.

Even if such a structure is applied, the energy consumption is low compared to the amount of water movement, and thus the water purification ability can be improved compared to the energy consumption.

As described above, the present invention is not limited to the described embodiments, and various modifications and changes can be made without departing from the spirit and scope of the present invention, which will be apparent to those skilled in the art. Therefore, such modifications or variations will have to be belong to the claims of the present invention.

110: device body 111: shaft
112: support pole 113, 114: fixed block
115: lower flange 116: upper flange
117 weight 140 connection bar
150: fan unit for water purification 151: fan unit
152: main bar 153: inclined bar
154: wing wall

Claims (9)

An apparatus body seated on the surface of the water purification object;
A connection bar connected to a shaft disposed in a central region of the apparatus body; And
A fan unit for water purification coupled to an end of the connection bar,
The fan unit for water purification,
A fan unit to which the connection bar is connected;
A fixed rod disposed radially with respect to the fan unit, a length extension rod coupled to the fixed rod so as to extend in length, and a plurality of resistors provided on the fixed rod and the length extension rod to reduce resistance during rotation; A plurality of main bars with reducing apertures; And
And an inclined bar disposed at an end of the length bar of the main bar, the inclined bar being inclined at a predetermined angle with respect to the main bars.
The method of claim 1,
And the inclined bar is integrally connected to or detachably connected to the main bar.
The method according to claim 1 or 2,
The inclined bar has an inclination angle of 30 degrees to 60 degrees to the rear with respect to the rotation direction of the water purification fan unit.
The method of claim 1,
One side of the inclined bar is water purification device, characterized in that the wing wall is further provided to double the flow of water.
The method of claim 4, wherein
The wing wall,
Fixed wing walls; And
And at least one additional wing wall detachably connected to the fixed wing wall to double the contact area of water with the fixed wing wall.
The method of claim 1,
The plurality of main bars on the basis of the fan unit is provided with three or four water purification device.
The method of claim 1,
The main bar is a water purification device, characterized in that the length adjustable.
The method of claim 1,
The connecting bar is provided in pairs symmetrically on both sides of the device body,
The water purification fan unit is provided at each of the ends of the pair of connection bar water purification device.
The method of claim 1,
After the length between the fixed bar and the length bar is determined, the water purification device further comprises a bolt inserted into the through hole for resistance reduction to fix the length between the fixed bar and the length bar.

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