KR102637477B1 - Small hydro power generation system in response to changes in farm discharge water flow rate - Google Patents

Abstract

The present invention relates to a small hydro power generation system in response to changes in the flow rate of discharged water from a fish farm. The configuration of the present invention includes: an aquaculture tank having an inlet formed on one side into which water is introduced, and an outlet formed on the other side of the inlet through which stored water is discharged; a tube body whose end is connected to the outlet of the aquaculture tank and through which water stored in the aquaculture tank moves in one direction by operation of a pump; It is connected to the other end of the pipe body and is regularly arranged around the center centered on the center, and the inside is divided into a plurality of water movement spaces by a bundle of pipes formed in the longitudinal direction from one end to the other end. A power generation control module that is divided and is equipped at each entrance of the pipes with a control valve designed to vary the inflow of water by adjusting the degree of opening according to the amount of water discharged from the aquaculture tank; A support plate detachably coupled to both sides of the power generation control module and having a plurality of penetrating portions formed on its surface to allow each of the pipes to pass through and support them; and a control unit that calculates the control opening amount of the control valve according to the amount of water moved from the aquaculture tank and applies an opening amount signal according to the control opening amount to the control valve.

Description

Small hydro power generation system in response to changes in farm discharge water flow rate}

The present invention relates to a small hydro power generation system in response to changes in the flow rate of discharged water from a fish farm. More specifically, the discharge path of the discharged water passing through the bundle-type power generation control module is appropriately varied according to the change in flow rate to ensure fluidity of power generation and at the same time, power generation efficiency. It is about a small hydro power generation system that responds to changes in the flow rate of fish farm discharge water, which can be expected to improve.

In general, hydroelectric power generation generates power by naturally inducing the flow of a river or reservoir located at a high point, converting the drop, which is potential energy, into kinetic energy, and using the converted kinetic energy as a driving force to rotate a water wheel directly connected to the generator. produces.

The drop is the maximum vertical distance available, and the larger the drop, the larger the power generation facility capacity and the corresponding increase in power. At this time, the output of hydroelectric power can be calculated as hydraulic power output [kW] = 9.8 (gravitational acceleration) × flow rate (㎥/s) × drop (m) × turbine generator efficiency (%).

Meanwhile, recently, the need for small hydro power generation has emerged due to the local energy supply project, renewable energy supply system (RPS), and carbon emission reduction project, which are part of the government's new and renewable energy supply policy, and the need for small hydro power generation has increased, such as through control dams and pumped water. A lot of investment and effort is being made to develop small-scale hydro power generation using lower dams of power plants, agricultural reservoirs, sewage treatment plants, and cooling water from thermal power plants.

However, small hydro power generation has had the problem of showing a low operation rate of about 35% due to seasonal bias in rainfall as well as various civil complaints from areas surrounding development.

In particular, small hydro power plants applied to marine or land-based aquaculture farms have shown relatively high operation rates when the drop is large due to the ebb and flow of the tide, but when the drop is small, the power generation efficiency is low due to the low operation rate, which is far below the maximum capacity of the power generation facility. There was a problem of rapid deterioration.

Registered Patent Publication No. 10-1256823 (small hydro power generation device, announced on April 23, 2013) Publication of Patent No. 10-2011-0010269 (Small hydroelectric power generation device, published on February 1, 2011) Public Patent Publication No. 10-2011-0103564 (small hydro power generation system, published on September 21, 2011)

The present invention is intended to solve the problems of the prior art as described above. One purpose of the present invention is to secure fluidity of power generation by appropriately varying the discharge path of the discharged water passing through the bundle-type power generation control module according to the change in flow rate. At the same time, it provides a small hydro power generation system that responds to changes in the flow rate of fish farm discharge water, which can be expected to improve power generation efficiency.

Another object of the present invention is to provide a small hydro power generation system that responds to changes in the flow rate of fish farm effluent that can be mass-produced all at once and has a modular structure that can be installed without being greatly restricted by the area of the installation location.

In addition, in addition to the above-mentioned clear objectives, the present invention may aim to achieve other objectives that can be easily derived by a person skilled in the art from the overall description of the present specification.

In order to achieve the above object, the small hydro power generation system for responding to changes in flow rate of aquaculture discharge water according to the first embodiment of the present invention has an inlet 112 through which water is introduced on one side, and storage on the other side of the inlet 112. A culture tank 110 having an outlet 114 through which water is discharged; A tube body (120) connected at one end to the discharge portion (114) of the aquaculture tank (110) and through which the water stored in the aquaculture tank (110) moves in one direction by the operation of the pump (P); It is connected to the other end of the pipe body 120, and is arranged regularly around the center centered on the center, and the inside is formed by bundle-shaped pipes 132 formed in the longitudinal direction from one end to the other end. It is divided into a plurality of water movement spaces, and each entrance of the pipes 132 is equipped with a control valve 134 designed to vary the amount of water inflow by adjusting the degree of opening according to the amount of water discharged from the aquaculture tank 110. Power generation control module (130); A support plate 140 that is detachably coupled to both sides of the power generation control module 130 and has a plurality of penetrating portions 142 formed on its surface to support each of the pipes 132 through them; And a control unit 150 that calculates the control opening amount of the control valve 134 according to the amount of water moved from the aquaculture tank 110 and applies an opening amount signal according to the control opening amount to the control valve 134. It consists of ;.

According to the small hydro power generation system for responding to changes in the flow rate of fish farm effluent according to the second embodiment of the present invention, a drain hole 144 communicating with the inside of the power generation control module 130 is formed on one side of the edge surface of the support plate 140, and , the drain hole 144 is maintained in an open or closed state according to manual operation of the valve.

According to the small hydro power generation system responding to changes in the flow rate of aquaculture effluent according to the third embodiment of the present invention, the control unit 150 controls at least two pipes that do not meet the maximum allowable design flow rate among the arbitrary pipes 132. In this case, the control valve 134 provided in one pipe is closed and operated.

According to the small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to the fourth embodiment of the present invention, the power generation control module 130 is made in the form of a single module that can be combined with other power generation control modules, and has a power output of 0 - 90 with respect to the ground. Multiple units may be combined in succession within the angle range of °.

According to the small hydro power generation system for responding to changes in flow rate of aquaculture discharge water according to the fifth embodiment of the present invention, the outer surface of the power generation control module 130, excluding one end and the other end, may be formed in an angled tetrahedral or cylindrical shape.

According to the small hydro power generation system for responding to changes in the flow rate of effluent from aquaculture farms according to the present invention, the fluidity of power generation can be secured by appropriately varying the discharge path of the discharge water passing through the bundle-type power generation control module according to the change in flow rate, and at the same time, the power generation efficiency can be improved. There is an effect that can be expected to improve.

In addition, according to the small hydro power generation system for responding to changes in the flow rate of aquaculture discharge water according to the present invention, there is an advantage in that the power generation control modules in the form of modular bundles can be mass-produced at once and can be installed without being greatly restricted by the area of the installation location due to the modular structure. .

Meanwhile, the effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

Figure 1 is an overall schematic diagram showing a small hydro power generation system responding to changes in the flow rate of fish farm effluent according to an embodiment of the present invention;
Figure 2 is a perspective view showing the appearance of a power generation control module, among the elements constituting a small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to an embodiment of the present invention;
Figure 3 is a cross-sectional view for explaining the internal structure of the power generation control module shown in Figure 2;
Figure 4 is a perspective view showing the structure of a support plate among the elements constituting a small hydro power generation system responding to changes in flow rate of aquaculture discharge water according to an embodiment of the present invention;
Figure 5 is a diagram illustrating the opening and closing status of the power generation control module according to the amount of discharged water in a small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to an embodiment of the present invention;
Figure 6 is a diagram illustrating a state in which a plurality of power generation control modules are sequentially combined among the elements constituting a small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to an embodiment of the present invention;
Figure 7 is a flowchart of the process of changing the total opening amount of the power generation control module in a small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to an embodiment of the present invention.

Hereinafter, embodiments of the present invention will be described in detail with reference to the attached drawings. For reference, in describing the embodiments of the present invention below, the terms referring to the components of the present invention are named in consideration of the function of each component, and are therefore interpreted to limit the technical components of the present invention. won't work.

Additionally, it should be noted that as used throughout this specification, the singular forms “a,” “an,” and “an” include plural referents unless the content clearly dictates otherwise.

Figure 1 is an overall schematic diagram showing a small hydro power generation system responding to changes in flow rate of fish farm discharge water according to an embodiment of the present invention.

When described with reference to FIG. 1, the small hydro power generation system for responding to changes in flow rate of aquaculture discharge water according to the present invention largely consists of an aquaculture tank 110, a tube body 120, a power generation control module 130, a support plate 140, and a control unit 150. It can be formed separately.

As shown in FIG. 1, the aquaculture tank 110 according to an embodiment of the present invention has an inlet 112 through which water is introduced on one side, and an outlet through which stored water is discharged on the other side of the inlet 112. (114) is formed.

In addition, the tube body 120 according to an embodiment of the present invention is connected at one end to the discharge portion 114 of the aquaculture tank 110, and the water stored in the aquaculture tank 110 is discharged by the operation of the pump (P). It is moved in one direction, that is, toward the power generation control module 130, which will be described later.

Meanwhile, Figure 2 is a perspective view showing the appearance of the power generation control module 130, one of the elements constituting a small hydro power generation system responding to changes in the flow rate of aquaculture discharge water according to an embodiment of the present invention, and Figure 3 is a power generation control module shown in Figure 2 ( This is a cross-sectional view to explain the internal structure of 130).

2 and 3, the power generation control module 130 according to an embodiment of the present invention is connected to the other end of the pipe body 120, and is regularly arranged around the center around the center. The interior is divided into a plurality of water movement spaces by bundle-shaped pipes 132 formed in the longitudinal direction from one end to the other end, and at each entrance of the pipes 132, water discharged from the aquaculture tank 110 is provided. Each control valve 134 is designed to vary the amount of water inflow by adjusting the opening degree according to the amount of water.

According to a further embodiment of the present invention, the outer surface of the power generation control module 130, excluding one end and the other end, may be formed in an angled tetrahedral or cylindrical shape. That is, the exterior may be cylindrical or rectangular.

Figure 6 is a diagram illustrating a state in which a plurality of power generation control modules 130 are sequentially combined among the elements constituting a small hydro power generation system responding to changes in flow rate of aquaculture discharge water according to an embodiment of the present invention.

As shown in Figure 6, the power generation control module 130 according to the present invention is made in the form of a single module that can be combined with other power generation control modules, and is within an angle range of 0° to 90° with respect to the ground. Multiple numbers may be combined in succession.

If another power generation control module is combined with the power generation control module 130 in an angle range of less than 0°, the water passing through the power generation control module will result in being countered by gravity, so the power generation control module 130 ) performance deteriorates rapidly, and when other power generation control modules are combined with the power generation control module 130 at an angle range exceeding 90°, connection with other components may not be smooth due to structural abnormalities. In addition, only the serial connection method is shown in the drawing, but it is of course not limited to this and the parallel connection method can also be applied.

According to the structure in which a plurality of power generation control modules 130 are sequentially combined in the form of a module as described above, convenience of installation can be increased and scalability can be achieved at the same time.

Meanwhile, Figure 4 is a perspective view showing the structure of the support plate 140, one of the elements constituting a small hydro power generation system responding to changes in flow rate of fish farm discharge water according to an embodiment of the present invention.

Referring to FIG. 4, the support plate 140 according to an embodiment of the present invention is detachably coupled to both sides of the power generation control module 130, and is provided on the surface so that each of the pipes 132 penetrates and supports them. A plurality of penetrating portions 142 are formed.

According to the structure of the support plate 140 as described above, it not only firmly supports the pipes 132 in a bundle shape accommodated inside the power generation control module 130, but also prevents vibration caused by the flow of water. Damage to the pipes 132 can be prevented in advance.

According to a further embodiment of the present invention, a drain hole 144 communicating with the inside of the power generation control module 130 may be formed on one side of the edge surface of the support plate 140.

The drain hole 144 functions to remain open or closed according to manual operation of the valve.

The control unit 150 according to an embodiment of the present invention calculates the control opening amount of the control valve 134 according to the amount of water moved from the aquaculture tank 110, and sends an opening amount signal according to the control opening amount to the control valve. Authorized to (134). In addition, the control unit 150 is connected to a pump (not shown) provided at the inlet 112 to enable wired/wireless communication to collect the amount of water flowing into the inlet 112 and to be discharged. By predicting the amount in advance, it is possible to establish an overall operation plan for the small hydro power generation system according to the present invention.

In addition, according to the control unit 150, the amount of water flowing into the inlet 112 and the amount of water discharged from the power generation control module 130 are compared, and if the amount of water flowing in and the amount of water discharged are the same, it is normalized. The system is determined and the operation of the system is maintained. However, if, for example, the amount of water is different from the amount of water discharged, this is judged to be an abnormality and a control command is generated to immediately stop the operation of the system.

As an additional embodiment of the control unit 150, the control unit 150 is a control provided in one of the pipes 132, limited to at least two pipes that do not meet the maximum allowable design flow rate. The valve 134 can be operated closed.

As described above, among the plurality of arbitrary pipes 132, at least two pipes that do not meet the maximum allowable design flow rate are closed by the control valve 134 to prevent the movement of water in any one pipe. The reason is to increase the power generation efficiency of the pipe by dispersing or changing the movement of water to adjacent pipes.

Meanwhile, Figure 5 is a diagram illustrating the opening and closing state of the power generation control module 130 according to the amount of discharged water in a small hydro power generation system responding to changes in the flow rate of discharged water from a fish farm according to an embodiment of the present invention, and Figure 7 is a diagram illustrating the opening and closing state of the power generation control module 130 according to the amount of discharged water. This is a flowchart of the process of changing the total opening amount of the power generation control module 130 in a small hydro power generation system in response to changes in the flow rate of aquaculture discharge water according to an example. For reference, the arrangement of the power generation control module 130 shown in FIG. 5 is originally in a downward sloping diagonal form, but is shown in a horizontal form for convenience of explanation.

Before explaining the opening and closing state of the power generation control module 130 according to the change in the flow rate of discharged water with reference to FIGS. 5 and 7, each corresponding number of the pipes 132 accommodated inside the power generation control module 130 is shown. It is assumed as in the drawing shown in 5.

First, open all control valves 134 and measure the performance of the power generation control module for each pipe 132 accommodated inside the power generation control module 130. For example, when all of the discharge water flows into the pipe 132, the performance of the power generation control module is 100% of the target efficiency, and when about half of the discharge water flows into the pipe 132, the performance of the power generation control module is 40 to 50%, and the performance of the power generation control module is 40 to 50%. When about 1/4 of the discharged water flows into (132), the performance of the power generation control module is calculated to be 20 to 25%.

Next, if the performance of pipes 6 and 7 is at maximum performance, that is, 100%, all control valves (134) are opened, but if the performance is less than 100%, the control valve (134) of pipe 7 is closed. I order it.

When the control valve 134 of the 7th pipe is closed as described above, the performance of the 3rd, 4th, and 5th pipes is measured, and if the measured performance is the maximum performance, the current state is maintained, but if the performance does not reach the maximum performance, If this is not possible, close the control valve (134) of pipes 5 and 6.

Afterwards, when the control valves 134 of pipes 5 and 6 are closed, the performance of pipes 3 and 4 is measured, and if the measured performance is the maximum performance, the current state is maintained, but if the performance does not reach the maximum performance, the performance of the pipes 3 and 4 is measured. If this is not possible, close the control valve (134) of pipe No. 4.

When the control valve (134) of pipe No. 4 is closed, the performance of pipes No. 1, 2, and 3 is measured, and if the measured performance is the maximum performance, the current status is maintained, but if the performance does not reach the maximum performance, Close the control valves (134) of pipes 2 and 3.

However, the information described above is merely an explanation to help understand the process of changing the overall opening amount of the power generation control module 130, and the present invention is not necessarily limited thereto.

In this way, according to the small hydro power generation system for responding to changes in the flow rate of aquaculture discharge water according to the present invention, the power generation control modules in the form of modular bundles can be mass-produced at once and can be installed without being greatly restricted by the area of the installation location due to the modular structure. This is a very useful invention in the field of small hydro power generation, where the fluidity of power generation can be secured and the power generation efficiency can be expected to improve by appropriately varying the discharge path of the discharged water passing through the bundle-type power generation control module according to the change in flow rate.

As described above, an embodiment of the small hydro power generation system for responding to changes in flow rate of fish farm effluent according to the present invention has been described, but this is an exemplary description of a preferred embodiment of the present invention and is not intended to limit the present invention. In addition, it is obvious to those skilled in the art that various modifications and imitations can be made without departing from the spirit of the present invention.

P: Pump 110: Aquaculture tank
112: inlet 114: outlet
120: Pipe body 130: Power generation control module
132: Pipeline 134: Control valve
140: support plate 142: penetration part
144: Drain hole 150: Control unit

Claims (5)

An aquaculture tank 110 having an inlet 112 through which water is introduced on one side, and an outlet 114 through which stored water is discharged on the other side of the inlet 112;
A tube body (120) connected at one end to the discharge portion (114) of the aquaculture tank (110) and through which the water stored in the aquaculture tank (110) moves in one direction by the operation of the pump (P);
It is connected to the other end of the pipe body 120, and is arranged regularly around the center centered on the center, and the inside is formed by bundle-shaped pipes 132 formed in the longitudinal direction from one end to the other end. It is divided into a plurality of water movement spaces, and each entrance of the pipes 132 is equipped with a control valve 134 designed to vary the amount of water inflow by adjusting the degree of opening according to the amount of water discharged from the aquaculture tank 110. Power generation control module (130);
A support plate 140 that is detachably coupled to both sides of the power generation control module 130 and has a plurality of penetrating portions 142 formed on its surface to support each of the pipes 132 through them; and
A control unit 150 that calculates the control opening amount of the control valve 134 according to the amount of water moved from the aquaculture tank 110 and applies an opening amount signal according to the control opening amount to the control valve 134; It is composed including,
The control unit 150 is characterized in that it closes the control valve 134 provided in one of the pipes 132 for at least two pipes that do not meet the maximum allowable design flow rate. A small hydro power generation system that responds to changes in the flow rate of effluent from aquaculture farms. According to claim 1,
A drain hole 144 communicating with the inside of the power generation control module 130 is formed on one edge of the support plate 140,
The drain hole 144 is a small hydro power generation system in response to changes in the flow rate of fish farm discharge water, characterized in that the drain hole 144 is maintained in an open or closed state according to manual operation of the valve. delete According to claim 1,
The power generation control module 130 is made in the form of a single module that can be combined with other power generation control modules, and responds to changes in the flow rate of fish farm discharge water, characterized in that a plurality of power generation control modules 130 are combined in succession within an angle range of 0 - 90° with respect to the ground. Small hydro power system. According to claim 1,
A small hydro power generation system in response to changes in the flow rate of fish farm discharge water, characterized in that the outer surface of the power generation control module 130, excluding one end and the other end, is made of an angled tetrahedron or cylindrical shape.