KR20200140227A - Sea water pumping apparatus - Google Patents

Abstract

The present invention relates to a seawater pumping device, wherein the seawater rising means and the seawater descending means are driven by using the potential energy of the seawater that has already been pumped, and by using the height difference according to the wave height, continuous without artificial additional energy input. It relates to a seawater pumping device that enables the pumping of seawater. The seawater pumping device of the present invention includes an upper water tank provided at a position above sea level; Seawater descending means disposed to provide a path through which seawater descends from the upper water tank to the sea level; A seawater rising means disposed in parallel with the seawater descending means and providing a path for increasing the seawater from the sea level to the upper water tank; The seawater lowering means and the seawater raising means are mutually coupled, and when the seawater is discharged to the outside by the seawater lowering means in the upper water tank, the load or pressure of seawater discharged to the outside from the upper water tank is applied to the seawater raising means. By transmitting to, it is composed of a power transmission means that allows external seawater to flow into the upper water tank, and in order to maintain the quantity of the upper water tank above a certain level, the amount of seawater introduced from the seawater raising means is the seawater descending means There is a technical feature to exceed the amount of seawater discharged from.

Description

Sea water pumping apparatus

The present invention relates to a seawater pumping device, wherein the seawater rising means and the seawater descending means are driven by using the potential energy of the seawater that has already been pumped, and by using the height difference according to the wave height, continuous without artificial additional energy input. It relates to a seawater pumping device that enables the pumping of seawater.

In general, fish farms and cooling facilities of power plants, which require continuous supply of seawater, are devices for supplying oxygen required by fish by inflow of seawater or cooling facilities. Use only some of its properties and discharge it back to the sea. And in salt fields, most of the seawater is evaporated to obtain salt.

However, in facilities such as fish farms, cooling facilities of power plants, and salt farms located at an altitude higher than sea level, the cost for pumping seawater is relatively high, as it requires the use of artificially processed energy such as the use of electricity. Continuous technology development is taking place.

As a related technology, a device for pumping water through a water pipe by operating a pump on the seabed using the vertical kinetic energy of waves has been proposed, but the size of the facility is large and complex, so economic efficiency is low, and the facility is damaged or lost due to typhoons. There is this.

As a conventional technique for improving this, the "water circulation structure of a farm using wave energy" of Korean Patent No. 14 69955 has been proposed. As shown in FIG. 1, such a conventional technique includes a water tank 10, a water tank outlet 11, a holder 21, a lever member 22, a buoyancy body 23, a piston rod 24, and a piston 25. ), a cylinder 26, an inlet 27, an internal outlet 28, a seawater supply pipe 30, a seawater discharge pipe 40, and a generator 50.

In this conventional technology, the fixing table 21 is a vertically erected columnar member, and the lower part is fixedly installed on the solid ground in the sea not far from the shore where the water tank 10 is installed, and the buoyancy body 23 moves up and down the sea level. The piston 25 also rises when the buoyancy body 23 is descended by the piston 25 and descends according to the piston 25 when the buoyancy body 23 is descended. The piston 25 penetrates the inside of the upper portion of the cylinder 26 to perform vertical motion. When the seawater is introduced into the cylinder 26 through the inlet 27 of the cylinder 26, the seawater is discharged to the seawater supply pipe 30 through the internal discharge port 28.

However, this conventional technology has a structure in which all seawater required for power generation as well as water circulation in a farm is pumped with the force of waves, and the potential energy of seawater is recovered as electric energy through a turbine when the pumped seawater is discharged. Since all the power to pump seawater must be extracted from the power of the waves, the size of the wave power device becomes enormous, and there is a problem that it is difficult to be located in a high place such as inland rather than near the sea level, which requires a lot of energy to pump seawater. Another problem is that the efficiency of converting the potential energy of seawater into electric power by using is relatively limited.

In order to solve the problems of the prior art, the present invention enables the pumping of new seawater by utilizing the potential energy of the seawater that has already been pumped, and at the same time, the energy required for the installed seawater pumping device is increased according to the wave height. The purpose of this is to drive the seawater rising means and the seawater descending means by using the difference, thereby enabling continuous pumping of seawater without artificial additional energy.

In addition, when installed near the coast like a conventional seawater pumping device, there is another object to enable the reduction of facility construction cost and operation cost according to the size reduction of facilities required for seawater pumping.

In addition, there is another purpose to make it possible to use it at a point that is more than a certain distance from the sea level, where the energy required for pumping seawater is relatively high compared to a facility that requires seawater pumping located on the coast.

The above object of the present invention is a seawater pumping apparatus, comprising: an upper water tank provided at a position above sea level; Seawater descending means disposed to provide a path through which seawater descends from the upper water tank to the sea level; A seawater rising means disposed in parallel with the seawater descending means and providing a path for increasing the seawater from the sea level to the upper water tank; The seawater lowering means and the seawater raising means are mutually coupled, and when the seawater is discharged to the outside by the seawater lowering means in the upper water tank, the load or pressure of seawater discharged to the outside from the upper water tank is applied to the seawater raising means. By transmitting to, it is composed of a power transmission means that allows external seawater to flow into the upper water tank, and in order to maintain the quantity of the upper water tank above a certain level, the amount of seawater introduced from the seawater raising means is the seawater descending means This is achieved by technical features that allow to exceed the amount of seawater discharged from.

Therefore, the seawater pumping device of the present invention enables the pumping of new seawater using the potential energy of the seawater that has already been pumped, and at the same time, the energy required for the installed seawater pumping device is generated by using the height difference according to the wave height. Thus, by driving the seawater raising means and the seawater descending means, there is an effect of enabling continuous pumping of seawater without artificial additional energy input as a whole.

In addition, there is another effect for enabling reduction of facility construction cost and operation cost by reducing the size of facilities required for seawater pumping.

In addition, compared to facilities that require seawater pumping located on the coast, the energy required for pumping seawater is relatively high at a point that is more than a certain distance from the sea level, thereby securing flexibility in the location required for facility construction. There is another effect that can be done.

1 is a configuration diagram of a water circulation structure of a farm using wave energy according to the prior art,
2 is an exemplary view showing a first embodiment of the seawater pumping device according to the present invention,
3 is an exemplary view showing a second embodiment of the seawater pumping apparatus according to the present invention,
Figure 4 is an exemplary view showing a modified example of the seawater container of the present invention,
5 is an exemplary view showing a third embodiment of a seawater pumping device according to the present invention,
6 is an exemplary view of the installation of the seawater pumping device according to the present invention.

The terms or words used in the specification and claims should not be construed as being limited to their usual or dictionary meanings, and the inventor may appropriately define the concept of terms in order to describe his own invention in the best way. It should be interpreted as a meaning and concept consistent with the technical idea of the present invention based on the principle that there is.

Accordingly, the embodiments described in the present specification and the configurations shown in the drawings are only the most preferred embodiment of the present invention, and do not represent all the technical spirit of the present invention, and thus various alternatives that can be substituted for them at the time of application It should be understood that there may be equivalents and variations.

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

2 is an illustrative view showing a first embodiment of the seawater pumping device according to the present invention, illustrating that the seawater descending means 200 and the seawater raising means 300 are formed in a tubular shape.

In the following description, it should be referred to that the seawater descending means 200 and the seawater raising means 300 are formed in a tubular shape, and that a description encompassing other embodiments of the present invention is included.

The present invention is located above sea level 100 and includes an upper water tank 110 for supplying sea water to aquaculture farms or industrial facilities requiring cooling.

In addition, the seawater supply device of the present invention is provided with a seawater descending means 200 and a seawater rising means 300, and the seawater descending means 200 is a path through which seawater descends from the upper water tank 110 to the sea level 100. Provides, and the seawater rising means 300 provides a path for rising seawater from the sea level 100 to the upper water tank 110.

Here, the base of the sea level means the vicinity of the sea level, more preferably less than the sea level, and further, it is more preferable that the sea water descending means 200 and the sea water raising means 300 are arranged side by side.

In addition, in order to cause the descent and rise of seawater in the seawater descending means 200 and the seawater rising means 300, a power transmission means 400 is provided, and the power transmission means 400 includes the seawater descending means 200 and Combined with the seawater raising means 300, when seawater is discharged to the outside by the seawater lowering means 200 in the upper water tank 110, the amount of seawater discharged to the outside by potential energy in the upper water tank 110 By directly transferring the load or pressure to the seawater raising means 300, external seawater is allowed to flow into the upper water tank 110.

Here, when seawater is discharged to the outside by the seawater descending means 200 from the upper water tank 110, the seawater has a function of supplying oxygen to the aquaculture tank 111 of the aquaculture or cooling industrial facilities requiring cooling. After performing, let seawater be discharged to the outside.

Here, the aquaculture tank 111 may be configured as a part of the upper water tank 110.

In addition, if the quantity of the upper water tank 110 cannot be maintained above a certain level due to evaporation of seawater, etc., it may be impossible to continuously perform the function of seawater pumping, so the upper water tank 110 has a constant The amount of water above the level must be stably maintained, and therefore, the amount of seawater flowing from the seawater raising means 300 to the upper water tank 110 must exceed the amount of seawater discharged from the seawater descending means 200.

Here, in the case of excessively exceeded seawater, it is possible to discharge the seawater naturally by overflowing from the upper water tank 110, or to eliminate excessive seawater quantity by additionally providing a forced discharge means. You can come up with a plan to use this.

In this way, in order to ensure that the amount of seawater flowing from the seawater raising means 300 to the upper water tank 110 exceeds the amount of seawater discharged from the seawater lowering means 200, the seawater lowering means 200 is the seawater raising means. It should be longer than (300), and at the same time, in terms of the diameter of the pipe, the seawater raising means 300 is lowered into the sea within a diameter range such that the total seawater weight of the seawater lowering means 200 is greater than the total seawater weight of the seawater raising means 300. It is formed to be larger than the means 200.

Here, the stroke distance refers to the length of the passage of the pipe when the seawater descending means 200 and the seawater raising means 300 are formed in a tubular shape.

In addition, the power transmission means 400 is further provided with a power generating means composed of at least one of an electric motor, an engine, a wave power device, or a wind power device, so that the discharge of seawater from the upper water tank 110 due to the difference in potential energy and Accordingly, it is possible to efficiently increase the quantity of additional quantity in addition to the quantity of inflow.

However, even when the power transmission means 400 is additionally provided with a power generating means to secure additional quantity, the seawater descending means 200 allows the seawater to descend below the gravitational acceleration, thereby exceeding the gravitational acceleration and It is only possible to minimize the use of energy required for seawater pumping only when the action of the power generating means, not the pressure, is prevented.

In addition, the seawater pumping device of the present invention is formed by a power generating means (not shown) and a power generating means composed of at least one of an electric motor, an engine, a wave power device, or a wind power device between the upper water tank 110 and the sea level 100. It is possible to assist in securing a stable amount of water in the upper water tank 110 by additionally providing a seawater elevation assistance means (not shown) that is driven to supply seawater to the upper water tank 110 from the sea level.

2 is a view showing that the seawater descending means 200 and the seawater raising means 300 are formed in a tubular shape in an embodiment of the seawater pumping device according to the present invention, and the power transmission means 400 is a seawater descending means 200 and Consists of a plurality of wings that connect the inner spaces of the seawater raising means 300 to each other, are operated by seawater descending in the inner space of the seawater lowering means 200, and cause seawater rise in the inner space of the seawater raising means 300 It is provided with a wing portion 410.

However, the wing portion 410 provided in the sea water elevation means 300 is arranged to be spaced apart from the bottom of the wave to 9.8 meters or less, so that the sea water elevation means 300 which may be generated when the space is disposed more than 9.8 meters. It is possible to prevent a vacuum from being generated in the inner space of the seawater raising means 300 that may be generated.

In Fig. 2(a), the power transmission means 400 is illustrated to have one rotation center shaft 420, and in FIG. 2(b), two rotation center shafts 420 are provided.

In this way, when the power transmission means 400 has one rotational center shaft 420, it is located between the seawater descending means 200 and the seawater rising means 300, and has two rotational center axes 420. When provided, the rotational center shaft 420 is positioned in the seawater descending means 200 and the seawater rising means 300 respectively.

Here, when the power transmission means 400 is provided with one rotation center shaft 420, as shown in Fig. 2(a), the power transmission means 400 is an oval around the rotation center shaft 420 The upper housing 430 includes a wing portion 410 that rotates by contacting the inner surface, and the load or pressure of seawater is transmitted to the wing portion 410 provided in the seawater descending means 200 by the descent of seawater, The load or pressure transmitted to the wing portion 410 provided in the seawater descending means 200 is transferred to the wing portion 410 provided in the seawater raising means 300 so that the seawater rises.

In addition, when the power transmission means 400 is provided with two rotation center shafts 420, the power transmission means 400 includes a blade portion 410 rotating inside the housing around the rotation center shaft 420, respectively. It is provided, and the load or pressure of seawater is transmitted to the wing portion 410 provided in the seawater descending means 200 by descending of the seawater, and the load transmitted to the wing portion 410 provided in the seawater descending means 200 Alternatively, the pressure is transmitted to the wing portion 410 provided in the seawater raising means 300 so that the seawater rises.

Here, the load or pressure of the seawater descending means 200 is transmitted to the seawater raising means 300 by any one of gears, chains, shafts, hydraulic means, and pneumatic means, but is not limited to these means.

3 is an exemplary view showing a second embodiment of the seawater pumping device according to the present invention. As shown in Figure 3, unlike the first embodiment of the present invention, the seawater descending means 200 and the seawater raising means 300 are formed in a "∪" shape with a plurality of seawater containers 210 and seawater It is composed of a transfer unit 220 for transferring the receiving container 210, and is coupled to a power transmission means 400 having a rotating support 450 supporting the transfer unit 220.

Here, the opening of the seawater container 210 is coupled to the transport unit 220 so as to face the opposite direction of the sea level 100, and the coupling direction is switched near the upper water tank 110 to waterproof the seawater to the upper water tank 110. It is switched to the sea level 100 in the vicinity of the sea level 100 so that the sea water is freshwater.

Here, the seawater descending means 200 and the seawater raising means 300 are provided with a plurality of seawater containers 210 having openings formed in a "∪" shape, and from the seawater raising means 300 to the upper water tank 110 In order to ensure that the amount of seawater introduced exceeds the amount of seawater discharged from the seawater descending means 200, the seawater descending means 200 must be longer than the seawater rising means 300 in terms of the stroke distance, and the seawater descending means 200 Within the range so that the total weight of seawater is greater than the total weight of seawater of the seawater raising means 300, the seawater raising means 300 uses a larger seawater container 210 than the seawater descending means 200, or the transfer unit 200 By forming a narrow spacing between the combined vessels, the amount of seawater flowing into the upper water tank 110 can exceed the amount of seawater discharged.

Here, the stroke distance means the length at which the transfer unit 200 rotates once.

Here, in FIG. 3, although a preferred embodiment in which the rotating support 450 is arranged in two vertically is shown, the present invention also has a structure in which one rotating support 450 is arranged only in the upper portion to support the transport unit 220 It goes without saying that it can be implemented, and the arrangement shape of the rotation support 450 and the number of rotation support 450 may be variously changed.

In addition, any one or more of the seawater descending means 200 or the seawater raising means 300 further includes a seawater quantitative loading means (not shown) in order to accommodate a certain amount of seawater in each seawater container 210. It is more preferable that the quantitative loading means is provided with a seawater supply device (not shown) located near the sea level in the case of the upper water tank 110 in the case of the seawater descending means 200, and in the case of the seawater raising means 300, Since the technical matters related to this are the same as those for receiving the quantity in a general container, the description thereof will be omitted.

In addition, the rotation support 450 and the transfer unit 220 are formed by any one of a combination of a sprocket-chain or a gear-timing belt.

Figure 4 is an exemplary view showing a modified example of the seawater container 210 of the present invention. Unlike shown in FIG. 3, the seawater container 210 is vertically coupled as shown in FIG. 4(a) or vertically as shown in FIG. 4(b) so that the openings of the seawater container 210 face opposite directions, and the seawater container 210 Unlike FIG. 3, since the change of direction of the seawater container 210 is not required, it is fixedly coupled to the transfer unit 220.

Here, the seawater descending means 200 and the seawater raising means 300 are directed to the openings of the seawater container 210 in opposite directions with respect to the moving direction of the transfer unit 220, and by the seawater descending means 200 By transferring the generated load or pressure to the seawater raising means 300, seawater pumping is achieved.

5 is an exemplary view showing a third embodiment of the seawater pumping apparatus according to the present invention, and descriptions thereof are omitted for parts described in other embodiments. As shown in FIG. 5, the seawater pumping apparatus of the present invention includes a wave-floor water tank 510 having a wave-floor level maintenance means 520 formed based on the lowest point of the wave, and a wave-high water level maintenance means 540 based on the highest point of the wave. It is also possible to supplement the energy required for the operation of the seawater pumping device by additionally providing at least one of the wave height tanks 530 having a) and utilizing the difference in height of the waves generated by the waves.

Here, the wave water level maintenance means 520 is composed of one or more of a flap or check valve for discharging seawater from the wave water tank 510 in one direction, or a drain pump, and the wave water level maintenance means 540 in one direction It is possible to configure with any one or more of a wave type hill, a check valve, a flap, or a pumping pump for introducing seawater to 530, and in FIG. 5, a flap with a wave bottom level maintenance means 520 and a wave height level maintenance means 540 for convenience Is illustrated.

6 is an exemplary view of the installation of the seawater pumping device according to the present invention. As shown in Fig. 6, it is illustrated that the seawater pumped by the seawater pumping device of the present invention is applied to a farm.

In Figure 6, it is located above the sea level 100 and is provided with an upper water tank 110 for supplying seawater necessary for a farm, and the seawater descending and rising occurs in the seawater descending means 200 and the seawater rising means 300. A power transmission means 400 is provided to ensure that, when seawater is discharged to the outside by the seawater descending means 200 from the upper water tank 110, the load or pressure of seawater discharged to the outside from the upper water tank 110 By transferring the water to the seawater raising means 300, external seawater is introduced into the upper water tank 110.

Here, the seawater introduced into the upper water tank 110 is supplied to the aquaculture tank 111 to supply oxygen required for fish, etc., and then discharged to the outside through the seawater descent means 200, in FIG. It is illustrated that a flap is used as the wave-low water surface maintaining means 520, and a wave-shaped hill and a flap are simultaneously used as the wave-high water surface maintaining means 540.

Although the present invention has been shown and described with a preferred embodiment as described above, it is not limited to the above-described embodiment, and within the scope of the spirit of the present invention, to those of ordinary skill in the art. Various changes and modifications will be possible.

100: sea level 110: upper water tank
111: Aquaculture tank
200: seawater descending means 210: seawater container
220: transfer unit
300: seawater elevation means
400: power transmission means 410: wing
420: rotation center axis 430: oval-shaped housing
440: shaft 450: rotating support
510: wave water tank 520: wave water surface maintenance means
530: wave height tank 540: wave height maintenance means

Claims (21)

In the seawater pumping device,
An upper water tank provided at a position above sea level;
Seawater descending means disposed to provide a path through which seawater descends from the upper water tank to the sea level;
A seawater raising means disposed in parallel with the seawater descending means and providing a path for increasing the seawater from the sea level to the upper water tank;
The seawater lowering means and the seawater raising means are mutually coupled, and when seawater is discharged to the outside by the seawater lowering means from the upper water tank, the load or pressure of seawater discharged to the outside by potential energy in the upper water tank By directly transmitting the water to the seawater raising means, it is composed of a power transmission means for allowing external seawater to flow into the upper water tank,
The power transmission means has one or two rotation center shafts,
Seawater pumping apparatus, characterized in that in order to maintain the quantity of the upper water tank above a certain level, the amount of seawater introduced from the seawater raising means exceeds the amount of seawater discharged from the seawater descending means. The method of claim 1,
Seawater pumping device, characterized in that the total weight of seawater accommodated in the seawater descending means exceeds the total weight of seawater accommodated in the seawater raising means The method of claim 1,
Seawater pumping device, characterized in that the stroke distance of the seawater descending means is greater than the stroke distance of the seawater raising means The method of claim 1,
The power transmission means is a seawater pumping device, characterized in that it further comprises any one or more power generating means of an electric motor, an engine, a wave power device, or a wind power device. The method of claim 4,
The seawater descending means is a seawater pumping device, characterized in that the seawater descends below gravitational acceleration. The method of claim 1,
Seawater pumping device, characterized in that the seawater descending means and the seawater raising means have a tubular shape. The method of claim 6,
The power transmission means connects the inner space of the seawater lowering means and the seawater raising means to each other, and is operated by lowering the seawater in the inner space of the seawater lowering means, and a plurality of wings that cause seawater rise in the inner space of the seawater raising means Seawater pumping device, characterized in that it has a wing portion consisting of The method of claim 7,
Seawater pumping device, characterized in that the wing portion provided in the seawater raising means is disposed to be spaced apart from the bottom of the wave by 9.8 meters or less The method of claim 7,
When the rotation center axis is one, it is located between the seawater descending means and the seawater elevation means, and when the rotational center axis is two, it is located inside the seawater descending means and the seawater elevation means, respectively. Seawater pumping device The method of claim 9,
When the power transmission means has one rotation center shaft, the power transmission means includes a blade portion rotating by contacting the inner surface of the elliptical housing around the rotation center shaft, and the seawater descending means by the descending of the seawater The load or pressure of seawater is transmitted to the wing portion provided in, and the load or pressure transmitted to the wing portion provided in the seawater descending means is transmitted to the wing portion provided in the seawater raising means to increase seawater. Seawater pumping device, characterized in that The method of claim 9,
When the power transmission means has two rotational center shafts, the power transmission means each has blades that rotate inside the housing around the rotational center axis, and is provided in the seawater descending means by the descending of the seawater. A load or pressure of seawater is transmitted to the wing portion, and the load or pressure transmitted to the wing portion provided in the seawater descending means is transmitted to the wing portion provided in the seawater raising means to increase seawater. Seawater pumping device, characterized in that The method of claim 11,
Seawater pumping device, characterized in that the load or pressure of the seawater descending means is transmitted to the seawater raising means by any one of a gear, a chain, a shaft, a hydraulic means, and a pneumatic means. The method of claim 1,
The seawater descending means and the seawater raising means are composed of a plurality of seawater containers with openings formed in a "∪" shape and a transfer part for transferring the seawater container, and a power transmission means having a rotating support supporting the transfer part Seawater pumping device, characterized in that coupled to The method of claim 13,
Seawater pumping device, characterized in that at least one of the seawater descending means or the seawater raising means further includes a seawater quantitative loading device to accommodate a certain amount of seawater in each seawater container. The method of claim 13,
Seawater pumping device, characterized in that the rotation support and the transfer part are formed by any one of a combination of a sprocket-chain or a gear-timing belt The method of claim 13,
The opening of the seawater container is coupled to the conveying unit so as to face opposite the sea level, and the bonding direction is switched near the upper water tank to waterproof the seawater to the upper water tank, and the seawater is switched to the sea level direction near the sea level to freshwater the seawater. Seawater pumping device, characterized in that The method of claim 13,
Seawater pumping device, characterized in that the openings of the seawater container are coupled in a horizontal or vertical direction so as to face opposite directions The method of claim 13,
Each of the seawater descending means and the seawater raising means includes the rotational support and the transfer part supported on the rotational support, and the seawater container coupled so that the openings face in opposite directions with respect to the moving direction of the transfer part. Seawater pumping device, characterized in that it is made by being coupled to each of the conveying unit, and transmitting a load or pressure generated by the seawater descending means to the seawater raising means. The method of claim 1,
The seawater pumping device is characterized in that it further comprises at least one of a wave trough having a wave trough level maintaining means formed based on the lowest point of the wave and a wave trough trough having a wave trough level maintaining means based on the highest point of the wave. Pumping device The method of claim 19,
The wave bottom maintaining means is a flap or check valve that discharges seawater from the wave bottom tank in one direction, or is composed of one or more of a drain pump, and the wave level holding means is a wave-shaped hill that introduces seawater into the wave bottom tank in one direction. , A seawater pumping device comprising at least one of a check valve, a flap, or a pumping pump The method of claim 1,
The seawater pumping device is driven by a power generating means composed of at least one of an electric motor, an engine, a wave power device, or a wind power device between the upper water tank and the sea level and the power generating means to transfer seawater from the sea level to the upper water tank. Seawater pumping device, characterized in that it further comprises a seawater elevation aid means to supply

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