KR101069414B1 - Siphon micro hydropower equipment using discharge way inline turbine of the thermal power plant - Google Patents

Abstract

The present invention relates to a siphon-type hydroelectric power generating apparatus using an inline turbine for a waterproof path of a power plant, and more particularly, a circulation water pump installed in a power plant and pumped after collecting seawater, and transported to a condenser and condenser for condensing water vapor. It is a pressure pipe which is connected to the pipe and drained water is discharged, the water discharge passage formed at the end of the pressure pipe passage to drain the water, formed between the end of the pressure pipe passage and the waterproof passage, the weir to store water, formed in the upper weir pressure pipe passage It relates to a siphon type hydroelectric power generating apparatus using an inline turbine for the waterproof passage of a power plant organically coupled to the branch pipe and the branch pipe and the siphon hydrophobic power generation is connected to the waterway downstream of the weir. The present invention forms a branch pipe having an inline turbine above the weir of the drainage system in which the siphon is maintained by the pressure head of the discharged water after using the seawater in the power plant, the installation cost of the hydropower plant is low and easy to install It works.

Mechanical Power Plant, Small Hydro Power, Power Generation, Pressure Pipeline, Branch Pipe, Inline Turbine

Description

Siphon micro hydropower equipment using discharge way inline turbine of the thermal power plant}

The present invention relates to a siphon-type hydroelectric power generating apparatus using an inline turbine for a waterproof path of a power plant, and more particularly, a circulation water pump installed in a power plant and pumped after collecting seawater, and transported to a condenser and condenser for condensing water vapor. It is a pressure pipe which is connected to the pipe and drained water is discharged, the water discharge passage formed at the end of the pressure pipe passage to drain the water, formed between the end of the pressure pipe passage and the waterproof passage, the weir to store water, formed in the upper weir pressure pipe passage It relates to a siphon type hydroelectric power generating apparatus using an inline turbine for the waterproof passage of a power plant organically coupled to the branch pipe and the branch pipe and the siphon hydrophobic power generation is connected to the waterway downstream of the weir.

Firstly, siphon means a communication tube that transfers a liquid from a high place to a low place. The principle of this siphon is that liquid is pushed up into the tube due to the atmospheric pressure acting on the higher liquid level.

Referring to Korean Patent Application Publication No. 10-2008-0081881, the position of water discharged by the siphon phenomenon by installing a siphon tube in a small beam, installing a vacuum pump and a solenoid valve in the upper part of the branch pipe, and installing a water generator in the lower part of the branch pipe. It is a small hydro power generator that converts energy into electrical energy. Thus, the fluid of the tube having the kinetic energy has a problem that the density is lowered because it contains bubbles therein. In other words, the density of the fluid passing through the turbine affects the turbine efficiency.

In addition, the cost of constructing a domestic small hydro power plant accounts for 60% for civil engineering, 30% for mechanical equipment, and 10% for electrical equipment. In order to construct such a small hydro power plant, facilities such as high information, movable beams, movable flood gates, and temporary barriers should be installed separately. In other words, huge construction costs were used to construct small hydro power plants. In addition, since hydrophobic power generation is caused by a drop, bubbles are generated in the effluent and there is a problem of inhibiting the environment. As a result, complaints were generated by residents and environmental groups.

Therefore, the present invention has been made to solve the above problems, the present invention has an object to provide a siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant is low installation cost and easy to install.

As described above, technical means for achieving the object of the present invention is as follows.

A circulating water pump installed in a power plant and pumping seawater after the intake; A condenser connected to the circulation water pump by a transfer pipe to condense the water vapor; A pressure feed pipe that is connected to the feed pipe to the condenser and drains water; A water repellent path formed at the end of the pressure feed pipe passage to drain water, and a weir formed between the end of the pressure feed pipe passage and the waterproof passage to store water; Branch pipes formed on the upper weir to communicate the upstream and downstream of the weir of the pressure feed pipe; It is characterized in that it comprises a; inline turbine is formed on the pipeline of the branch pipe siphon-type hydropower generation.

A waterway in the form of a dam and a waterway for discharging water from the power plant to the sea; A weir formed on the tarmac to store water; A branch pipe formed in the upper weir and flowing water from the upstream side to the downstream side of the waterproof path; And an inline turbine formed on a pipeline of the branch pipe and configured to siphon hydrophobic power generation.

Branch pipe is characterized in that the inlet port is a water inlet is formed at a position relatively higher than the outlet port is discharged.

Branch pipe is characterized in that it is further provided with a flow control valve for adjusting the flow rate on one side of the inline turbine.

The branch pipe is further provided with a shut-off valve for opening and closing the flow of water on one side or both sides of the inline turbine

Branch pipe is characterized in that it is further provided with an expansion joint pipe at the end.

End of the branch pipe is characterized in that it is extended to communicate with the interior of the waterproof path.

Branch pipe is characterized in that provided with two or more inline turbine.

The inline turbine includes a main body having a circular ring shape formed at the center to generate power; A runner having a circular ring shape inserted into an inner surface of the main body and having wings formed on the inner surface of the inner surface of the ring incorporating the permanent magnet so as to rotate entirely by water flow; A guide fan inserted into the runner blades formed therein, the guide fan having a rotary wing configured to induce water flow to the runner to one side; A casing for fixing the runner and the guide fan to both sides of the main body; And a water lubrication bearing for sealing between the body and each casing.

As described above, the present invention forms a branch pipe having an inline turbine in the upper portion of the weir of the drainage system in which the siphon is maintained by the water pressure head after using seawater in the power plant, so that the installation cost of the hydropower generator is low, and the hydropower generation It is easy to install the device.

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

< In the first embodiment  Configuration according to

1 is a longitudinal cross-sectional view showing a first embodiment of a siphon-type hydropower generator according to the present invention. As shown in FIG. 1, a first embodiment according to the present invention relates to a hydroelectric power generation apparatus installed in a power plant in which a plurality of pressure feed pipes 5 formed in a drainage system are formed in a pipe form. In this first embodiment, a circulation water pump 2 is installed at a power plant to collect and pump the seawater 1, and is connected to the circulation water pump 2 by a transfer pipe 3 to condense water vapor. A condenser 4 is formed, and a condenser 4 is formed to connect the condenser 4 to discharge water, and a condensation conduit 5 is formed at the end of the condensation conduit 5. And a weir (7) for storing water is formed between the end of the pressure feed pipe (5) and the waterproof passage (9).

Thus, the first embodiment forms a branch pipe 6 which communicates the pressure feed pipe 5 upstream of the weir 7 and the waterproof path 9 downstream of the weir 7 above the weir 7. An inline turbine 8 is formed on the pipeline of (6) to siphon hydrophobic power generation. At this time, the branch pipe (6) is the velocity energy is generated by the pressure and the speed of the pressure feed pipe (5) as the main pipe is to continue to generate siphon due to the drop of water in the branch pipe (6). To this end, the branch pipe 6 allows the inlet port through which water is introduced to be formed at a position higher than the outlet port through which the water is discharged. As a result, the inline turbine 8 generates hydrophobic power using the flow velocity passing through the branch pipe 6.

In addition, the branch pipe (6) is formed on the one side of the in-line turbine 8, that is, the flow rate control valve 61 for adjusting the flow rate on the inlet which is the front end of the branch pipe (6). This is to adjust the flow rate according to the amount of water discharged from the sea water (1).

The aforementioned branch pipe 6 is formed with a shutoff valve 62 for opening and closing the flow of water on one side or both sides of the inline turbine 8. This is to block the flow of water due to repair due to a failure of the inline turbine 8.

The aforementioned branch pipe 6 forms an expansion joint pipe 63 at the end. This is for the end of the branch pipe 6 to be lower than the surface of the water in order to maintain the siphon principle of the branch pipe 6 according to the flow rate flowing in the pressure feed pipe (5). To this end, the end of the branch pipe (6) is formed extending into the pressure feed pipe (5).

In addition, two or more inline turbines 8 can be formed in parallel with the branch pipes 6. This is to generate more power when the pressure head formed in the branch pipe 6 is high, that is, in the case of the high pressure flow pipe 5. Thus, the inline turbine 8 is formed in parallel in the branch pipe 6 because it is difficult to install many branch pipes 6 in the pressure feed pipe 5. The formation of two or more such inline turbines 8 is shown in the enlarged view of FIG.

2 is a perspective view illustrating a main part cut in the inline turbine according to the present invention, Figure 3 is an exploded perspective view showing an inline turbine according to the present invention. As shown in FIG. 2 and FIG. 3, in the inline turbine 8, the main body 81 that generates electric power by a magnetic field is formed in a circular ring shape. At this time, the main body 81 is a runner 82 of a circular ring shape is inserted into the inner surface. The runner 82 has a wing 821 formed on the inner surface of the runner 82 so that the whole rotates by water flow on the inner surface of the ring in which the permanent magnet is incorporated. In addition, the guide fan 83 is inserted and installed inside the runner 82 blade 821 is formed, at this time, the guide fan 83 is a rotary blade 831 for inducing water flow to the runner 82 to one side. Is formed. The above-mentioned main body 81 forms the casing 84 which fixes the runner 82 and the guide pan 83 to both sides. In addition, a water lubrication bearing 85 is formed between the main body 81 and each casing 84 to seal the main body 81. Here, in order to maximize the speed of the flow rate, the directions of the blades 821 of the runner 82 and the rotary blade 831 of the guide fan 83 are formed to be opposite to each other. That is, as the guide fan 83 rotates, the water flow formed by the rotary blades 831 is formed in the opposite direction to the wings 821 of the runner 82 to further accelerate the rotation of the runner 82 to maximize the amount of power generated.

The power plant according to the first embodiment is provided with more than 10 condenser 4 is high application value.

< In the second embodiment  Configuration according to

Figure 4 is a longitudinal cross-sectional view showing a second embodiment of a siphon type hydroelectric power generating apparatus according to the present invention. As shown in FIG. 4, the second embodiment according to the present invention relates to a hydrophobic power generating apparatus installed on the upper weir 7 on the waterproof passage 9 connected to the sea side from the power plant side waterproof passage 9. In this second embodiment, a solder or beam-type waterproof passage 9 for discharging water from a power plant to the outside and a waterproof pump for discharging water from the waterproof passage 9 to the bottom of the outer wall of the waterproof passage 9 are formed. At this time, the weir 7 is formed at the center of the waterproof passage 9 to store water.

In this way, the second embodiment forms a branch pipe 6 which communicates both the upstream and downstream of the weir 7 of the waterproof passage 9. An inline turbine 8 is formed on the pipeline of the branch pipe 6 to perform siphon-type hydroelectric power generation. At this time, the branch pipe (6) is the velocity energy is generated in the waterway (9) in the form of the channel to the branch pipe (6) is to continue to generate the siphon by the energy gradient difference. As a result, the inline turbine 8 generates hydroelectric power. As described above, since the second embodiment can form a plurality of branch pipes 6 on the upper weir 7, the amount of power generated by the hydro-power generator can be increased.

In addition, the branch pipe (6) is formed on the one side of the in-line turbine 8, that is, the flow rate control valve 61 for adjusting the flow rate on the inlet which is the front end of the branch pipe (6). This is to adjust the flow rate in accordance with the amount of water discharged from the waterproof passage (9).

The aforementioned branch pipe 6 is formed with a shutoff valve 62 for opening and closing the flow of water on one side or both sides of the inline turbine 8. This is to block the flow of water due to repair due to a failure of the inline turbine 8.

The aforementioned branch pipe 6 forms an expansion joint pipe 63 at the end. This is for the end of the branch pipe 6 to be lower than the surface of the water in order to maintain the siphon principle of the branch pipe 6 according to the flow rate flowing in the pressure feed pipe (5).

2 is a perspective view illustrating a main part cut in the inline turbine according to the present invention, Figure 3 is an exploded perspective view showing an inline turbine according to the present invention. As shown in FIG. 2 and FIG. 3, in the inline turbine 8, the main body 81 that generates electric power by a magnetic field is formed in a circular ring shape. At this time, the main body 81 is a runner 82 of a circular ring shape is inserted into the inner surface. The runner 82 has a wing 821 formed on the inner surface of the runner 82 so that the whole rotates by water flow on the inner surface of the ring in which the permanent magnet is incorporated. In addition, the guide fan 83 is inserted and installed inside the runner 82, the blade 821 is formed, at this time, the guide fan 83 has a rotary blade 831 for inducing water flow to the runner 82 to one side Is formed. The above-mentioned main body 81 forms the casing 84 which fixes the runner 82 and the guide pan 83 to both sides. In addition, a water lubrication bearing 85 is formed between the main body 81 and each casing 84 to seal the main body 81. Here, in order to maximize the speed of the flow rate, the directions of the blades 821 of the runner 82 and the rotary blade 831 of the guide fan 83 are formed to be opposite to each other. That is, as the guide fan 83 rotates, the water flow formed by the rotary blades 831 is formed in the opposite direction to the wings 821 of the runner 82 to further accelerate the rotation of the runner 82 to maximize the amount of power generated.

The first embodiment and the first embodiment according to the present invention can be easily attached and detached, and at least the branch pipe has an effective drop of 2M or more, so that an output of 50kw-100kw can be obtained.

As described above, those skilled in the art will understand that the present invention can be implemented in other specific forms without changing the technical spirit or essential features. It is therefore to be understood that the above-described embodiments are to be considered in all respects as illustrative and not restrictive. The scope of the present invention is defined by the appended claims rather than the detailed description and all changes or modifications derived from the meaning and scope of the claims and their equivalents should be construed as being included within the scope of the present invention.

The following drawings, which are attached in this specification, illustrate the preferred embodiments of the present invention, and together with the detailed description thereof, serve to further understand the technical spirit of the present invention, and therefore, the present invention is limited only to the matters described in the drawings. It should not be interpreted.

1 is a longitudinal cross-sectional view showing a first embodiment of a siphon type hydroelectric power generating apparatus according to the present invention;

Figure 2 is a perspective view of the main cutaway inline turbine according to the present invention.

3 is an exploded perspective view showing an inline turbine according to the present invention;

Figure 4 is a longitudinal cross-sectional view showing a second embodiment of a siphon type hydroelectric power generating apparatus according to the present invention.

<Explanation of symbols for the main parts of the drawings>

1: sea water 2: circulating water pump 3: transfer pipe 4: condenser

5: Pressure feeding line 6: Branch pipe 61: Flow control valve 62: Shut-off valve

63: expansion pipe 7: weir 8: inline turbine 81: main body

82: runner 821: wing 83: guide fan 831: rotary wing

84: casing 85: water lubrication bearing 9: seal

Claims (10)

A circulating water pump (2) installed in the power plant and pumping the seawater (1) after the intake; A condenser 4 connected to the circulation water pump 2 by a transfer pipe 3 to condense the water vapor; A pressure feed pipe (5) connected to the condenser (4) to convey water discharged; A watertight passage (9) formed at an end of the pressure pipe (5) to drain water; A weir (7) formed between the end of the pressure pipe (5) and the waterproof passage (9) to store water; A branch pipe (6) formed at an upper portion of the weir (7) so as to communicate a pressure feed pipe (5) upstream of the weir (7) and the waterproof path (9) downstream of the weir (7); And Siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that it comprises a; inline turbine (8) formed on the pipeline of the branch pipe (6) to siphon hydrophobic power generation. A waterproof passage 9 in the form of a dam or a water channel for discharging water from the power plant to the sea; Weir (7) is formed in the center of the waterproof path (9) for storing water; A branch pipe (6) formed above the weir (7) and transporting water from the upstream side to the downstream side of the waterproof path (9) based on the weir (7); And Siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that it comprises a; inline turbine (8) formed on the pipeline of the branch pipe (6) to siphon hydrophobic power generation. The method according to claim 1 or 2, The branch pipe (6) siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that the inlet for the water inlet is formed at a relatively higher position than the outlet for the water discharge. The method according to claim 1 or 2, Said branch pipe (6) siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that further provided with a flow control valve 61 for adjusting the flow rate in the front end portion. The method according to claim 1 or 2, Said branch pipe (6) siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that the inlet turbine 8 is further provided with a shutoff valve 62 for opening and closing the flow of water on one side or both sides. The method according to claim 1 or 2, Said branch pipe (6) siphon-type hydroelectric power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that the expansion joint pipe 63 is further provided at the end. The method of claim 1, End portion of the branch pipe (6) siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that extending in communication with the interior of the waterproof path (9). The method according to claim 1 or 2, Said branch pipe (6) is a siphon-type hydro-power generating apparatus using an inline turbine for the waterproof path of the power plant, characterized in that provided with two or more inline turbine (8). The method according to claim 1 or 2, The inline turbine 8, A main body 81 having a circular ring shape formed at the center to generate power; A runner 82 having a circular ring shape inserted into an inner surface of the main body 81 and having a blade 821 formed on an inner surface of the inner surface of the ring incorporating a permanent magnet so as to rotate entirely by water flow; A guide fan (83) having a rotary blade (831) formed therein and inserted into the runner (82) with a blade (821) formed therein and inducing water flow to the runner (82); A casing (84) fixing the runner (82) and the guide fan (83) to both sides of the main body (81); And And a water lubrication bearing (85) for sealing between the main body (81) and each of the casings (84). The method of claim 9, The inline turbine 8 is a siphon using an inline turbine for a water resistant path of a power plant, characterized in that the blade 821 direction of the runner 82 and the rotary blade 831 of the guide fan 83 are formed in the opposite direction. Hydropower plant.

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