KR20100042804A - Small water power generation equipment using discharging water of sewage disposal plant - Google Patents

Abstract

PURPOSE: A small water power generation equipment using discharging water of a sewage disposal plant is provided to implement a continue generation without restriction of discharge flow of water by installing little water-power generating equipment on the sidewall of a discharge tub. CONSTITUTION: A small water power generation equipment using a discharging water of a sewage disposal plant includes a vertical interlocking unit(110) and a fixing unit(120). The vertical interlocking unit includes a water turbine, a rotary shaft(115), and a frame(117). A generator converts power produced from the water turbine into the electricity. The rotary shaft interlinks the water turbine and the generator. A frame holds the water turbine, the generator, and the rotary shaft. The fixing unit comprises a height controlling device and a guide unit.

Description

Small Water Power Generation Equipment using Discharging Water of Sewage Disposal Plant

The present invention relates to a hydrophobic power plant, and more particularly, to the hydrophobic power plant capable of adjusting the height of the hydrophobic power plant so that the water level is changed according to the discharge amount of the discharge water discharged from the discharge tank of the sewage treatment plant. By providing it on the side wall of a discharge tank, it is related with the small hydro power plant which can generate continuous power, without being restricted by the discharge amount of discharged water.

In general, power generation methods such as hydroelectric generation, thermal power generation, and nuclear power generation require large-scale power generation facilities, and in order to operate such power generation facilities, a huge amount of energy source is also required. And this power generation method has a lot of restrictions in the installation place. Among them, fossil fuels such as petroleum and coal used for thermal power generation are the main causes of global warming and environmental pollution, and their dependence is very high compared to other fuels, which leads to exhaustion of resources and development of alternative energy to replace them. The problem is also seriously emerging. On the other hand, eco-friendly and permanent power generation methods using natural energy such as solar, tidal, wave, and wind power have been developed and applied, but they account for only a small portion of the total energy supply. It is not free from restrictions on environment, installation location and cost.

Under these circumstances, in recent years, attention has been paid to a small hydro power generation method capable of continuously generating electricity while being relatively limited in installation location. Small-scale power generation is a small-scale power generation method that generates electricity by using irregular or small amounts of water flowing from small rivers, large buildings, and sewage treatment plants, and generates electricity by installing predetermined power generation facilities at the ends of the above places and facilities. Way. These small hydro power generation is only small compared to the general hydro power generation, the power generation principle or driving method is the same.

On the other hand, the sewage treatment plant, the drop of the effluent is not very large, but can be stably supply the effluent used for hydropower generation, so the use value among the various places and facilities capable of hydropower generation is relatively large. This sewage treatment plant is provided with a plurality of purification modules, a pair of sedimentation tank for sedimentation and a discharge tank for receiving and discharging the overflowing water from the sedimentation tank. Each discharged water that is discharged after being purified from a plurality of purification modules is discharged to the outside through a drainage path connecting them to one. At this time, the water level is changed in accordance with the discharge amount of the discharge water discharged from the plurality of purification modules.

Here, when the conventional fixed hydropower plant is installed in a sewage treatment plant having the structure as described above, various problems will occur.

First, the conventional hydropower plant is limited in the installation position according to the water level of the drain. That is, since the water level of the drainage path where the discharged water is collected and discharged to the outside is variable according to the discharge amount of the discharged water, the conventional fixed hydropower plant should be installed at a point higher than the highest point of the drainage level. However, this reduces the drop in discharged water, which lowers the power generation efficiency. Furthermore, when the discharged amount of the discharged water decreases, the power generation itself may become difficult.

Second, the conventional hydropower plant does not consider a problem in which a large amount is scattered before the discharged water flows into the aberration when the discharged water falls. That is, when the conventional hydropower plant is installed in the sewage treatment plant, a large amount is scattered while the effluent falls, so that the amount of effluent flowing into the aberration is relatively small compared to the discharge amount of the effluent. And in terms of resource recycling, overlooking this scattering problem in hydroelectric power generation, which generates electricity using a small amount of waste water, does not fit the original intent of hydropower generation.

In addition, above all, most sewage treatment plant effluent is discharged as it is, the available energy is simply discarded.

The present invention has been made in view of the above-mentioned problems, and the discharge of the hydrophobic power generation equipment which can adjust the height to correspond to the drainage path in which the water level is changed according to the discharge amount of the discharged water discharged from the discharge tank of the sewage treatment plant. By providing it on the side wall of a tank, it aims at providing the hydrophobic power generation facility which can generate continuous power without being restrict | limited by the discharge amount of discharged water.

In addition, another object of the present invention is to provide a hydrophobic power generation facility that can maximize the power generation efficiency by reducing the discharged water to be prevented, by preventing the falling discharged water is scattered.

In addition, another object of the present invention is to provide a hydrophobic power generation facility capable of converting simply discarded energy into useful energy by producing electricity by using discharged water from a sewage treatment plant.

In order to achieve the above object, a hydrophobic power generation facility using effluent from a sewage treatment plant according to the present invention includes a purification module 10 including a sedimentation tank 11 and a discharge tank 13, and a plurality of the purification modules 10 as one. In the hydrophobic power generation equipment 100 using the discharge water of the sewage treatment plant 1 including the drainage path 20 to be connected, the hydrophobic power generation equipment 100 uses a drop of the discharge water to generate power by using aberration 111 ), A generator 113 for converting the power generated from the aberration 111 into electricity, a rotation shaft 115 connecting the aberration 111 and the generator 113, and the aberration 111 and the A vertical linkage unit 110 including a generator 113 and a frame 117 integrally fixing the rotation shaft 115; And a height adjusting device 121 for adjusting the height of the vertical linkage part 110 and a guide part 123 for fixing the frame 117 and installed in the purification module 10 to provide the vertical direction. Fixing portion 120 for supporting the interlocking portion 110; but made of, the height adjusting device 121 adjusts the height of the vertical interlocking portion 110 automatically or manually according to the water level of the drainage path (20) Characterized in that.

Here, a funnel-shaped connection channel 130 for guiding the discharge water may be formed between the side wall of the discharge tank 13 in which the discharge water falls and the drain path 20.

On the other hand, the aberration 111 is formed below the connection channel 130, the generator 113 is formed on one side of the rotary shaft 115 corresponding to the aberration 111, the rotary shaft 115 May be formed to penetrate the inside of the connection channel 130, and the frame 117 may be formed to surround an outer wall of the connection channel 130.

In addition, a cylindrical shatterproof film 111a protruding upward may be formed at the edge of the aberration 111.

In this case, the scattering prevention film 111a is larger than the outer diameter of the connection channel 130 and may be formed to be fitted to the outside of the connection channel 130.

As described above, according to the present invention, the side wall of the discharge tank in which the discharge water falls in the hydrophobic power generation equipment that can adjust the height so as to correspond to the drainage path in which the water level is changed according to the discharge amount of the discharge water discharged from the discharge tank of the sewage treatment plant By installing in the above, continuous development can be performed without being limited by the amount of discharged water.

In addition, according to the present invention, by preventing the falling effluent to be scattered, it is possible to reduce the effluent lost to maximize the power generation efficiency.

In addition, according to the present invention, by producing electricity by using the discharge water of the sewage treatment plant, it is possible to simply convert the energy that is discarded into useful energy.

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

1 is a flow chart showing a discharge flow of a general sewage treatment plant, Figure 2 is a plan view schematically showing a sewage treatment plant is installed hydrophobic power plant according to a preferred embodiment of the present invention, Figure 3 according to a preferred embodiment of the present invention Perspective view showing the vertical linkage of the hydropower plant. In addition, Figure 4a is a perspective view showing a hydrophobic power plant installed in the purification module according to a preferred embodiment of the present invention, Figure 4b is a front view of Figure 4a, Figure 4c is a cross-sectional view taken along the line I-I of Figure 4b.

First, as shown in Figure 1, the sewage treatment plant (1) is a water purification facility for collecting and purifying the sewage flowing out of the home or factory, and then flowing to the river or the sea, to collect and store the sewage flowing through the various paths Sewage storage step, and a sewage treatment step to disinfect using chemicals to remove harmful substances and impurities contained in the sewage stored through the sewage storage step, and the first disinfected sewage is introduced into the sewage The sedimentation step of sedimenting the remaining impurities on the floor and overflowing the sewage from which the impurities have been removed to the next step in an overflow method, and the discharge step of discharging the purified sewage flowing in from the sewage sedimentation step down. And a drainage step of draining the discharged water discharged from the discharge step to a river or the sea. Thereby purifying the water in various sewage through a sewage treatment step. The sewage treatment plant 1 may be formed with a plurality of purification modules 10 formed by pairing the settling tank 11 and the discharge tank 13. In addition, one side of the plurality of purification module 10 is formed with a drainage passage 20 connecting them to one.

Here, the discharged water discharged by the discharge step in the structure of the sewage treatment plant 1 is dropped for the progress of the drainage step. Therefore, in a preferred embodiment of the present invention, there is provided a hydropower plant 100 capable of producing electricity by using a drop of sewage treatment plant 1 discharged water. And since the hydrophobic power generation equipment 100 according to the present invention is installed in each individual purification module 10, the sewage treatment plant 1 may be provided with as many hydrophobic power generation equipment 100 as the number of the purification module (10). .

Hereinafter, a hydrophobic power plant according to a preferred embodiment of the present invention will be described in more detail.

As shown in FIGS. 2 to 3 and 4a to 4c, the hydrophobic power plant 100 according to the preferred embodiment of the present invention is formed to include a vertical linkage 110 and a fixing portion 120. At this time, the vertical linkage 110 is fastened to the height adjusting device 121 of the fixing part (120). On the other hand, the hydrophobic power plant 100 according to a preferred embodiment of the present invention may further include a connection channel 130 for concentrating the falling effluent.

The vertical linkage unit 110 includes an aberration 111, a generator 113, a rotation shaft 115, and a frame 117. In the hydrophobic power generation system 100 according to the present invention, the vertical edge eastern part 110 is configured to adjust the height according to the water level of the drainage path 20, by changing the position of the vertical linkage 110 freely, The power generation efficiency can be maximized without being significantly restricted by the water level of the drainage channel 20 formed in the lower portion according to the discharge amount of the discharged water.

The aberration 111 is a device for producing power using the free fall of the effluent. The present invention performs hydrophobic power generation using a drop of discharged water discharged from the sewage treatment plant (1). Therefore, it is preferable that the aberration 111 uses a Kaplan-type aberration that is easy for hydrophobic power generation. The aberration 111 is formed below the connection channel 130. Here, when the aberration 111 is formed to be spaced apart from the lower portion of the coupling channel 130, the falling discharge water is scattered in a large amount from the space between the aberration 111 and the coupling channel 130 to the outside to actually aberration ( 111) The amount of effluent flowing into can be reduced, which has a big impact on power generation efficiency. Therefore, in the preferred embodiment of the present invention, the shatterproof film 111a may be formed in the aberration 111. The shatterproof film 111a may be formed in a hollow cylindrical shape to protrude upward from the upper edge of the aberration 111. The scattering prevention film 111a is formed to be larger than the lower outer diameter of the connection channel 130 to be fitted to the lower outer side of the connection channel 130. At this time, the length of the anti-scattering film 111a is based on a state in which the lower end of the connection channel 130 is in contact with the upper end of the aberration, than the maximum falling width of the aberration 111 according to the position change of the vertical linkage 110. It should be formed long. This means that even if the aberration falls to the maximum width, the bottom outer side of the connection channel 130 still exists in the form of being fitted into the shatterproof film 111a, so that the space between the connection channel 130 and the aberration 111 is exposed to the outside. This is because the discharged water can be prevented from scattering. As described above, the configuration of forming the anti-scattering film 111a in the aberration 111 in order to prevent the discharged water is scattered well meets the purpose of hydrophobic power generation that generates electricity using a small amount of water.

The generator 113 is a device for producing electricity using the power generated from the aberration 111. The generator 113 is formed on one side of the rotating shaft 115 corresponding to the aberration 111. The electricity produced by the generator 113 may be used to operate the main facilities of the sewage treatment plant 1.

The rotary shaft 115 is formed between the aberration 111 and the generator 113 serves to transfer the power produced from the aberration 111 to the generator 113. That is, the aberration 111 is fastened to one side of the rotary shaft 115, and the generator 113 is fastened to the other side. Here, the rotation shaft 115 may be formed to penetrate the interior of the connection channel 130. In this case, since the rotary shaft 115 is in direct contact with the discharged water when the discharged water is discharged, when the rotary shaft 115 formed of a metal material is repeatedly contacted with the discharged water for a long time and exposed to air, the rotary shaft 115 ) Corrosion may occur. Therefore, in order to prevent corrosion of the rotating shaft 115, it is preferable to form a waterproof member (not shown) to plate the outside of the rotating shaft 115 or surround the circumference of the rotating shaft 115.

The frame 117 serves to integrally fix the aberration 111 and the generator 113. The frame 117 may be formed to surround the outer wall of the connection channel 130.

As described above, the vertical linkage unit 110 according to the present invention, which consists of an integral aberration 111, a generator 113, a rotation shaft 115, and a frame 117, is provided according to the water level of the drainage path 20. Height is adjusted by the height adjusting device 121 of the government 120 can maximize the power generation efficiency without being significantly restricted by the discharge amount of the effluent. As described above, a specific operation of the vertical linkage unit 110 in which the height is changed according to the water level of the drainage path 20 will be described later.

The fixing part 120 may be fixed to side walls of both settling tanks 11 of the purification module 10. The fixing part 120 is formed to include a height adjusting device 121 and the guide portion 123. The fixing part 120 serves to support the movement or shaking of the vertical linkage 110.

The height adjustment device 121 is a device for automatically or manually adjusting the height of the vertical linkage unit 110, the vertical linkage unit 110 by detecting a change in the water level of the drainage channel 20 with a water level sensor (not shown). ) To be positioned at the optimum height for small hydro power generation. That is, the height adjusting device 121 is pulled up so that the vertical linkage unit 110 is located at a high point when the water level of the drainage passage 20 under the purification module 10 is high, and the drainage passage under the purification module 10 ( 20) When the water level is low, the vertical linkage unit 110 is lowered to a low point so that the aberration 111 of the vertical linkage unit 110 is positioned at the lowest point in order to secure a larger drop. At this time, the height adjustment of the height adjustment device 121 can be carried out in a variety of ways, such as a hydraulic cylinder, rope, pulley, chain, it is not particularly limited to any one of the height adjustment method in the present invention.

The guide part 123 may be formed in a pipe shape fixed to both side walls of the settling tank 11. The guide part 123 accommodates both frames 117 of the vertical linkage part 110 in the pipe and supports it, thereby preventing the vertical linkage part 110 from being shaken by the hydraulic pressure of the discharge water. That is, the height adjustment device 121 serves to adjust or fix the vertical linkage 110 moving in the vertical direction, the guide portion 123, the vertical linkage 110 is shaken in the horizontal direction It serves to fix things.

The connection channel 130 is formed in the form of a funnel between the side wall of the discharge tank 13 in which the discharge water falls and the drainage channel 20 provided below the side wall of the discharge tank 13. That is, the connection channel 130 is formed to have a wide inner diameter of the inlet to the discharge water is formed in a structure capable of minimizing the lost discharge water, such a wide inner diameter is formed in a structure gradually narrowed toward the bottom, This is to ensure that the aberration 111 exhibits the maximum efficiency because the discharged water is concentrated in the aberration 111, which has a large amount of discharge of the discharged water. Therefore, the upper side of the connection channel 130 is preferably formed to have a predetermined width that can accommodate all of the discharge amount of the discharge water discharged from the discharge tank 13, the connection channel 130 The lower side of is preferably formed of the same size as the aberration 111. As described above, the lower sidewall of the connection channel 130 is formed to be accommodated in the scattering prevention film 111a of the aberration 111. The connection channel 130 is one of the fixing structures of the hydro power plant 100, which is fixed to the purification module 10 of the sewage treatment plant 1, like the fixing unit 120.

Hereinafter, the operation of the hydro power plant according to a preferred embodiment of the present invention will be described.

Figure 5a is a front view showing a hydropower plant according to a preferred embodiment of the present invention when the drainage level is the lowest, Figure 5b is a front view showing a hydrophobic power plant according to the preferred embodiment of the present invention when the level of the drainage is the highest. . (Where h ₁ is the lowest level of the drainage, h ₂ is the highest level of the drainage, L ₁ + ΔL is the maximum length of the top of the frame, and L ₁ is the minimum length of the top of the frame.)

First, as shown in FIG. 5A, when the discharge amount of the discharge water discharged from the discharge tank 13 is small and the drainage path shows the lowest water level h ₁ , the height adjusting device 121 according to the present invention provides the maximum amount of discharged water that falls. The vertical linkage unit 110 is lowered down manually or automatically so that the vertical linkage unit 110 is positioned as low as possible so as to have a drop in the range. In this case, since the lower side of the coupling channel 130 is located inside the upper portion of the scattering prevention film 111a, the falling effluent water does not have to be scattered. When the position of the vertical linkage 110 is adjusted, the upper end of the frame 117 fastened to the height adjusting device 121 represents the length of L ₁ + ΔL. As described above, when the position of the vertical linkage unit 110 is adjusted to match the water level of the drainage passage 20, the hydrophobic power generation equipment 100 according to the preferred embodiment of the present invention uses the maximum drop of the discharge water to generate power generation efficiency. It can be maximized.

On the other hand, as shown in Figure 5b, when the discharge amount of the discharged water discharged from the discharge tank 13 is increased, for example, a plurality of purification module 10 to discharge the discharged water at a time or when the heavy rain falls down the drainage path (20) ) Can be raised by the highest level h ₂ . In this case, by operating the height adjusting device 121 so that the aberration 111 of the vertical linkage unit 110 does not touch water and pulls up the vertical linkage unit 110 by ΔL length, the upper end of the frame 117 is at the maximum. The length L ₁ + ΔL decreases by ΔL to represent the minimum length L ₁ . At this time, the lower side of the coupling channel 130 is formed adjacent to the upper end of the aberration 111, there is no fear that the discharged water falling by the anti-scattering film (111a). In the conventional fixed hydropower plant, the aberration had to be stopped when the water level of the drainage was increased, but the hydropower plant 100 according to the preferred embodiment of the present invention has a vertical linkage unit 110 including an aberration 111. By spaced apart from the water filled in the drainage passage 20, it is possible to continue to generate power without any restrictions.

As described above, the present invention provides a hydro power plant 100 using the discharged water of the sewage treatment plant (1). That is, the present invention provides a hydrophobic power generation apparatus 100 capable of adjusting the height to correspond to the drainage path 20 in which the water level is changed according to the discharge amount of the discharge water discharged from the discharge tank 13 of the sewage treatment plant 1. Therefore, according to the present invention, the power generation can be continuously carried out without being restricted by the discharge amount of the discharged water, and by preventing the discharged water from scattering through the scattering prevention film 111a formed in the aberration 111, the discharged water is reduced and the power generation is reduced. The efficiency can be maximized. And according to the present invention, by producing electricity by using the discharged water of the sewage treatment plant 1, it is possible to simply convert the waste energy into useful energy.

Although the technical spirit of the present invention has been described in detail according to the above-described preferred embodiment, it should be noted that the above-described embodiment is for the purpose of description and not of limitation. In addition, those skilled in the art will understand that various embodiments are possible within the scope of the technical idea of the present invention.

1 is a flow chart showing the discharge flow of a typical sewage treatment plant.

Figure 2 is a plan view schematically showing a sewage treatment plant is installed hydrophobic power plant according to a preferred embodiment of the present invention.

Figure 3 is a perspective view showing a vertical linkage of the hydropower plant according to a preferred embodiment of the present invention.

Figure 4a is a perspective view showing a hydro power plant installed in the purification module according to an embodiment of the present invention.

4B is a front view of FIG. 4A.

4C is a cross-sectional view taken along the line I-I of FIG. 4B.

Figure 5a is a front view showing a hydropower plant according to a preferred embodiment of the present invention when the water level of the drainage is low.

Figure 5b is a front view showing a hydropower plant according to a preferred embodiment of the present invention when the drainage level is high.

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

Sewage Treatment Plant: 1 Purification Module: 10

Sedimentation tank: 11 Discharge tank: 13

Drainage: 20 Small Hydro Power Plant: 100

Vertical linkage: 110 Aberration: 111

Shatterproof film: 111a Generator: 113

Rotation axis: 115 Frame: 117

Fixing part: 120 Height adjusting device: 121

Guide part: 123 Channels: 130

Claims (5)

Small-scale power generation equipment using the effluent from the sewage treatment plant (1) comprising a purification module (10) comprising a sedimentation tank (11) and a discharge tank (13), and a drainage passage (20) connecting the plurality of purification modules (10) to one. In 100, The hydro power plant 100, The aberration 111 for generating power using the free fall of the discharge water, the generator 113 for converting the power generated from the aberration 111 into electricity, the aberration 111 and the generator 113 A vertical linkage unit 110 including a rotating shaft 115 to connect and a frame 117 integrally fixing the aberration 111 and the generator 113 and the rotating shaft 115; And It is formed to include a height adjusting device 121 for adjusting the height of the vertical linkage unit 110, and a guide portion 123 for fixing the frame 117 is installed in the purification module 10 and the vertical linkage Fixed portion 120 for supporting the portion 110; consisting of, The height adjustment device 121 is hydrophobic power generation facility, characterized in that for adjusting the height of the vertical linkage 110 automatically or manually according to the water level of the drainage passage (20). The method of claim 1, A hydrophobic power generation facility, characterized in that between the side wall of the discharge tank (13) in which the discharge water falls and the drainage passage (20) is formed a funnel-shaped connecting water passage 130 for guiding the discharge water. The method of claim 2, The aberration 111 is formed below the connection channel 130, the generator 113 is formed on one side of the rotary shaft 115 corresponding to the aberration 111, the rotary shaft 115 is The hydrophobic power generation facility is formed in a shape that penetrates through the connection channel 130, the frame 117 is formed to surround the outer wall of the connection channel 130. The method according to any one of claims 1 to 3, Hydrophobic power generation equipment, characterized in that the cylindrical shatterproof film (111a) protruding upward in the edge of the aberration (111). The method of claim 4, wherein The scattering prevention film (111a) is larger than the outer diameter of the connection channel 130, hydrophobic power generation equipment characterized in that it is formed in the form of being fitted to the outside of the connection channel (130).

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