KR102338182B1 - Nano-bubble based water purification apparatus with renewable energy production function - Google Patents

Abstract

The present invention relates to a nanobubble-based water purification apparatus with a renewable energy production function, which comprises: a mounting plate installed to float in a water surface environment to provide a water purification function thereto and providing at least one installation space on an upper side thereof; a rotating part including a rotating pillar part protruding up and down in a center of the installation space of the mounting plate and installed to be rotatable, a first power generation part connected to an upper part of the rotating pillar from an upper side of the mounting plate to convert power according to the rotational motion of the rotating pillar part into electrical energy to generate power, a rotation driving part connected to an upper part of the rotating pillar part from the upper side of the mounting plate to provide a driving force necessary for the rotational movement of the rotating pillar part, and a rotational blade part having the same height and length from a lower end of the rotating pillar part to both sides in left and right directions and extending in a plate shape of an upright structure with respect to the water surface; a power storage part electrically connected to the first power generation part to store power generated from the first power generation part and outputting the stored power to be used for providing driving force through the rotation driving part; and nanobubble generating parts respectively connected to both ends of the rotational blade part in left and right directions and rotating in conjunction with the rotational movement of the rotating pillar part and rotational blade part under the water surface by driving of the rotation driving part to discharge the generated nano-bubbles into the water surface. The present invention secures the performance and safety of the battery by securing the adhesive force between a lead tab film and a pouch film to prevent leakage of electrolyte, permeation of gas from the outside, and intrusion of moisture.

Description

{NANO-BUBBLE BASED WATER PURIFICATION APPARATUS WITH RENEWABLE ENERGY PRODUCTION FUNCTION}

The present invention relates to a nano-bubble-based water purification device having a renewable energy production function.

Nano-Bubble is an ultra-fine bubble with a size of 0.1 μm to 10 μm, which is large enough to contain 3 to 4 hydrogen molecules. This will provide an efficient water purification and restoration function.

The small zeta potential acting on the surface of particles suspended in water means that the ionized hydration layer on the surface of the particle is thin. The size of the bubbles should be small, the amount of bubbles should be large, and the ion affinity between the particles and the bubbles should be strong.

In this regard, looking at the mechanism of action of nanobubbles, when the size of the bubbles is reduced to a nano size, the adhesion to particles with large potential properties is excellent, and the amount of oxygen per unit volume increases, so that the effect of cleaning and sterilization is further increased.

As a result, the fineness of the bubble size maximizes the effect of cleaning or beaking, and the increase in the dissolved oxygen amount according to the generation of fine bubbles leads to a sterilization effect. .

Accordingly, various techniques for providing a water purification function using nanobubbles have been proposed, and further, various attempts are being made to expand the functional efficiency and application range of water purification provided through nanobubbles.

In this regard, after collecting and collecting wastewater that has been cleaned or purifying, sterilizing/purifying/disinfecting it, and regenerating it into nanobubble water, use of nanobubble water implemented so that it can be reused as nanobubble water again In the prior literature on the prior art prepared to provide a purification system, there is a "purification system using nano-bubble water" (hereinafter referred to as 'prior art') of Korean Patent Publication No. KR 10-1779356.

However, in the case of nano-bubble-based water purification devices including the prior art, they are fixedly arranged in one place and purify only the water quality within a certain radius. was not efficient and had many limitations.

In addition, in the case of nanobubble-based water purification devices including the prior art, a lot of energy is required in the process of trying to purify water using nanobubbles, so there is a problem in that the efficiency of energy consumption is not good compared to providing functions.

The present invention was created to solve the above problems, and an object of the present invention is to effectively provide a water purification function using nano bubbles even when applied in an environment in which the flow of water is limited or not large, as well as a water purification function It is to provide a nano-bubble-based water purification device that has significantly improved its expression efficiency and application range.

Furthermore, an object of the present invention is to provide a driving force related to the performance of the water purification function through the production of renewable energy in the process of performing water purification using nanobubbles, as well as various additional management and management and An object of the present invention is to provide a nano-bubble-based water purification device with an environmental advantage by supplementing the electrical energy required for the performance of monitoring functions to increase energy efficiency in performing various functions.

In order to achieve the above object, the nano-bubble-based water purification device having a renewable energy production function of the present invention is installed to float on a water surface environment to provide a water purification function, and at least one installation space is provided on the upper side. Installation plate provided; a rotating pole which protrudes up and down in the center of the installation space of the mounting plate and is rotatably installed; a first power generation unit connected to the upper portion of the rotating pillar at the upper side of the mounting plate to convert power according to the rotational motion of the rotating pillar into electrical energy to generate power; a rotation driving unit connected to an upper portion of the rotating pillar on the upper side of the mounting plate to provide a driving force necessary for the rotational movement of the rotating pillar; Rotating unit including a; rotational blades having the same height and length on both sides in the left and right directions from the lower end of the rotational column and extending in a plate shape of an upright structure with respect to the water surface; a power storage unit electrically connected to the first power generation unit to store power generated from the first power generation unit, and output the stored power to be used for providing driving force through the rotation driving unit; And each of the rotary blades is connected to both ends of the left and right sides of the reference outer side and rotates in conjunction with the process of rotating the rotary pillar and the rotary blades under the water surface by driving the rotary driving unit to discharge the generated nanobubbles into the water surface. A pair of nano-bubble generating units; includes.

In addition, the nano-bubble-based water purification device includes: a second power generation unit that converts solar heat into electrical energy to generate electricity by constructing a predetermined frame structure so that a plurality of solar power generation plates are placed above the installation space of the installation plate; And by constructing a structure in which a plurality of propellers rotating in the wind along the upper outer rim of the installation space of the installation plate and installation posts for arranging them at a predetermined height are arranged at the same distance from each other, converting wind power into electrical energy to produce power It further includes a third power generation unit; wherein the power storage unit is electrically connected to the second power generation unit to the third power generation unit to store power generated from the second power generation unit to the third power generation unit, and the stored power is output to be used for providing a driving force through the rotation driving unit.

In addition, the nano-bubble-based water purification apparatus is located on the upper side of the installation space of the installation plate and the upper side of the rotation unit. A monitoring unit that is installed to observe the external state of the second power generation unit, the third power generation unit, and the power storage unit to photograph image information, and transmits the captured image information in real time to a preset management terminal through a pre-established wireless communication network ; and a power control unit configured to store power generated through the first to third power generation units in the power storage unit, and to control the power output required for the operation of the rotation driving unit and the monitoring unit from the power storage unit. and an operation control unit for controlling the operation types of the rotation driving unit and the monitoring unit receiving power through the power control unit based on a preset control command or a control command received from a preset management terminal through a pre-established wireless communication network. It further includes; a control unit comprising a.

And the nano-bubble generating unit, a cylindrical shape having a predetermined accommodating space therein, the installation body portion provided with an open nano-bubble outlet to connect the accommodating space and the outside on the rear side; and a nano-bubble generating unit that is installed in the receiving space of the installation body and sprays the generated nano-bubbles toward the rear side so that the nano-bubbles can be discharged to the outside through the nano-bubble outlet. The bubble-based water purification apparatus further includes a pair of floaters each connected to the left and right outer side surfaces of the installation body to provide a predetermined floating force to each of the pair of nano-bubble generating units, The installation body portion of each of the pair of nano-bubble generating units is located at both ends of the outer side of the rotary wing unit in the left and right direction, with the front facing the rotational direction based on the rotational direction of the rotating wing, and the rear facing the opposite direction of rotation It is installed so that the nano-bubbles sprayed and discharged through the nano-bubble outlet are provided to provide an additional driving force to drive the rotational motion of the rotary wing unit.

Here, the installation body is provided with a plurality of first water microinlets on one side so that water on the water surface in which the nanobubble generating unit is disposed can be introduced into the receiving space of the installation body through the first water microinlets, , The nano-bubble generating unit is provided with a plurality of open second water micro-inlets on one side so that the water introduced through the water micro-inlet into the receiving space of the installation body is introduced to the inside and used to generate nano-bubbles, The nano-bubble generating unit is provided with an open nano-bubble injection port on one side to discharge the nano-bubbles generated from the inside to the outside using the water introduced through the second water micro-inlet, and the nano-bubble generating unit is the nano-bubble generating unit. The injection port is installed in the receiving space within the installation body so as to face each other toward the nano-bubble outlet.

In addition, the installation body portion is connected to the rotary wing portion so that the vertical center point is disposed above the top height of the rotor blade portion, and the bottom height is disposed below the vertical center point of the rotor blade portion, after the installation body portion The cross-section has a structure in which the vertical center point of the nano-bubble outlet is disposed to be biased lower than the vertical center point of the installation body part, and the left-right direction center point to which the floating body is connected rather than the left-right direction center point of the installation body is disposed to be biased outside.

In addition, the outer side to which the installation body part is connected based on the left and right central point of the rotary blade part is curved toward the rear side of the installation body part from the vertical center point toward the upper end, and is bent toward the front side of the installation body part toward the bottom part, Having a part of the propeller wing structure, the inner side to which the rotating pillar is connected based on the left and right central point of the rotating wing is bent toward the front side of the installation body from the vertical center point toward the top and toward the bottom of the installation body It curves towards the rear and forms part of the propeller wing structure.

According to the present invention, there are the following effects.

First, even when applied in an environment where the flow of water is limited or not large, the water purification function using nano bubbles can be effectively provided through the interlocking of the rotation unit and the nano bubble generating unit.

Second, through the interlocking of the rotating unit and the nanobubble generating unit, the form of spraying and discharging of nanobubbles rotates and affects the water flow pattern in the aquatic environment, so the expression efficiency and application range of the water purification function itself can be significantly improved. have.

Third, as the rotating column with certain structural features works in conjunction with the rotational movement, the upper surface water is convectively circulated to the lower deep water side, so that water quality purification across all depths up and down can be made more effectively.

Fourth, as renewable energy produced through the first to third power generation units is accumulated and used again, not only the electric energy required to provide driving force related to the performance of the water purification function, but also various management and monitoring It is possible to supplement the electrical energy required for the performance of functions, thereby increasing energy efficiency in performing various functions and achieving environmental improvement.

1 is a perspective view showing the structure of a nano-bubble-based water purification device according to the present invention.
2 is a front view showing the structure of a nano-bubble-based water purification device according to the present invention.
3 is a plan view showing the structure of a nano-bubble-based water purification device according to the present invention.
4 is a bottom view showing the structure of a nano-bubble-based water purification device according to the present invention.
5 is a front view showing the connection structure of the rotation unit and the nano-bubble generating unit in the nano-bubble-based water purification apparatus according to the present invention.
6 is a plan view illustrating the rotational movement and nanobubble jetting discharge form of the rotation unit and the nanobubble generating unit in the nanobubble-based water purification apparatus according to the present invention.
7 is a perspective view showing the detailed configuration and arrangement between the detailed configurations of the nano-bubble generating unit in the nano-bubble-based water purification apparatus according to the present invention.
8 is a block diagram showing detailed configurations related to the production and use of renewable energy in the nanobubble-based water purification apparatus according to the present invention.
9 is a perspective view showing the structure of the nano-bubble generating unit of the nano-bubble generating unit in the nano-bubble-based water purification apparatus according to the present invention.
10 is a bottom perspective view showing the structure of the nano-bubble generating unit of the nano-bubble generating unit in the nano-bubble-based water purification apparatus according to the present invention.

A preferred embodiment of the present invention will be described in more detail with reference to the accompanying drawings, but already known technical parts will be omitted or compressed for the sake of brevity of description.

<Description of nano-bubble-based water purification device with renewable energy production function>

1 to 7, the nano-bubble-based water purification device 100 having a renewable energy production function of the present invention interlocks the generated nano-bubbles with a rotational motion to have a special discharge shape to purify water quality. Installation plate 110 to enhance the performance of the function, and to provide various functions by continuously generating renewable energy-based power storage while performing the water purification function and utilizing it again as needed; rotation unit 120; a second power generation unit 130; a third power generation unit 140; power storage unit 150; Nano bubble generating unit 160; floating body 170; monitoring unit 180; and a control unit 190;

The installation plate 110 is a configuration of a basic housing that is installed to float on a water surface environment to provide a water purification function and provides at least one installation space on the upper side.

Here, the space to which the mounting plate 110 is applied through installation on the water surface environment is not limited only to the boundary portion with the ground surface that can achieve the supply of electric energy from an external power supply means in a streamlined manner as in the prior art. In the middle of a river, reservoir, or sea, etc., it can be implemented in a form where the entire periphery is surrounded by water.

It is preferable that the mounting plate 110 is structurally divided into three parts, and as shown in FIGS. 1, 3 and 4, the first mounting plate 111, the second mounting plate 112 and the three It is divided into three mounting plate parts 113 to provide different installation spaces for each part.

First, the first mounting plate portion 111 is a space corresponding to the central predetermined area of the mounting plate 110, and ultimately the rotation unit 120 to be described below is connected to the center, and a plurality of first floating means 111F on the bottom surface ) is installed to provide a predetermined floating force.

In addition, it is preferable that the upper side of the first installation plate part 111 has a shape that is covered by the solar plate of the second power generation part 130 .

Next, the second mounting plate part 112 forms a predetermined spaced gap with the first mounting plate part 111 in a space corresponding to the outer edge region of the mounting plate 110, and through the opened gap, the lower water surface provided so that it can be checked.

The frame configuration for placing the solar plate of the second power generation unit 130 and the third power generation unit 140 are installed on the upper surface of the second mounting plate unit 112, and a plurality of second floating means 112F are provided on the bottom surface. It is installed to provide a predetermined floating force.

Finally, the three three mounting plate part 113 is an area corresponding to the area between the outside of the first mounting plate 111 and the inside of the second mounting plate 112, and it is possible to observe the water surface through an open or transparent plate. It is preferable to be provided in the form.

The nano-bubble generating unit 160 connected to the outer both ends of the rotating blade 124 of the rotating unit 120 is positioned under the three three mounting plate parts 113 .

This is to enable the nano-bubble generating unit 160 to be described later to be interlocked with the rotating unit 120 to perform a rotational motion and to monitor the spraying and discharging of the nano-bubbles through the monitoring unit 180 .

The rotation unit 120 rotates the nano-bubble generating unit 160 to form an ejection trajectory of the nano-bubbles, and at the same time, through rotational motion-based power production, to use this as a renewable energy for power generation. It includes a rotating pillar unit 121 , a second power generation unit 122 , a rotation driving unit 123 , and a rotating blade unit 124 .

First, the rotating pillar 121 is a structure that serves as a rotating shaft, and is installed so as to protrude up and down in the center of the installation space of the mounting plate and to be rotatable.

Next, the second power generation unit 122 is connected to the upper portion of the rotating pillar unit 121 from the upper side of the first mounting plate unit 111 to convert power according to the rotational motion of the rotating pillar unit 121 into electrical energy. It corresponds to a power generation module for power-based renewable energy production that produces electricity.

The regenerative power generation performed by the second power generation unit 122 based on the rotational movement with the rotating pillar unit 121 as the rotation axis can be utilized as the operating power of the rotation driving unit 123 to be described below again.

In addition, the rotation driving unit 123 is connected to the upper portion of the rotation pillar part 121 from the upper side of the first mounting plate part 111 as a rotation axis to use the rotation pillar part 121 as a rotation axis to provide a driving force necessary for rotation. corresponds to

Finally, the rotary blade unit 124 has the same height and length on both sides in the left and right directions from the lower end of the rotary column unit 121 and symmetrically extends in a plate shape of a structure upright with respect to the water surface as shown in FIG. 4 . It is formed to provide a structure of a pair of left and right symmetrical wings.

The rotor blade 124 preferably has a propeller blade-type structure so that it can perform a more effective rotational motion even with a little less power energy without being effectively disturbed by the flow of water in the water.

Specifically, as shown in FIG. 4 , the outside to which the installation body 161 is connected based on the center point in the left and right directions of the rotor blade 124 is the rear side of the installation body 161 from the center point in the vertical direction toward the top. It has a portion of the structure of the propeller wing that is bent and twisted toward the front side of the installation body 161 toward the lower end.

In addition, the inner side to which the rotating pillar part 121 is connected based on the left and right center point of the rotary blade part 124 is bent toward the front side of the installation body part 161 from the vertical center point toward the top and installed toward the bottom. A portion of the propeller wing structure that is bent and twisted toward the rear side of the body portion 161 is provided.

As a pair of rotor blades 124 with such structural features are provided as shown in FIG. 4 , the rotational pillar 121 rotates according to the operation of the rotational driving unit 123 and is interlocked to rotate together in water and to be constant. direction, causing convection of water.

Specifically, the pair of rotor blades 124, which are rotated in association with the rotation of the rotation pillar 121 according to the operation of the rotation driving unit 123, is the first of the installation environment due to the structural features as described above. As shown in FIG. 5, the surface water, which is relatively richer in oxygen, nutrients, and biological resources, located on the upper side under the mounting plate part 111 is convected (W3) to the lower side, so that circulation through convection of water from the upper part to the lower part is performed. This will increase the functionality of water quality improvement more efficiently and effectively.

As shown in FIG. 1 , the second power generation unit 130 constructs a predetermined frame structure such that a plurality of photovoltaic panels are placed above the installation space of the mounting plate 110 , and converts solar heat into electrical energy to produce electric power. It corresponds to the solar power generation module.

As shown in FIG. 1 , the third power generation unit 140 includes a plurality of propellers rotating in the wind along the upper outer rim of the installation space of the installation plate 110 and installation pillars for arranging them at a predetermined height at the same interval as each other. It corresponds to a wind power generation module that converts wind power into electrical energy by constructing a structure that can be used to generate electricity.

The power storage unit 150 performs electrical storage by receiving electric power by making a wired electrical connection from the outside, or after receiving various types of renewable energy produced by the device itself as shown in FIG. It corresponds to the configuration of the storage battery that provides the stored electric power as operating power to the necessary configuration according to the control command of the control unit 190 .

Specifically, it is electrically connected to the first power generation unit 122 to the third power generation unit 140 to store power generated from the first power generation unit 122 to the third power generation unit 140, and to store the stored power. It outputs so that it can be used to provide a driving force through the rotation driving unit 123 .

Furthermore, the power storage unit 150 may provide the transferred power as the operating power of the nanobubble generating unit 160 , the monitoring unit 180 , and the control unit 190 .

Nanobubble generating unit 160 forms a pair and is respectively connected to both ends of the rotating blade unit 124 in the left and right directions, and is driven by the rotation driving unit 123 to rotate the columnar part 121 and the rotating blade part 124 . It rotates in conjunction with the process of rotation under the water surface and discharges the generated nanobubbles into the water surface.

The floating body 170 is provided as a pair so as to be connected to the left and right reference outer side portions of the installation body 161 in the pair of nano-bubble generating units 160, respectively, to each of the pair of nano-bubble generating units 160 It provides a certain floating force.

As shown in FIG. 7 , the nano-bubble generating unit 160 includes an installation body 161 corresponding to the housing and a nano-bubble generating unit 162 that actually generates and sprays nano-bubbles.

First, the installation body 161 has a cylindrical shape having a predetermined accommodating space therein, and an open nano-bubble outlet 161H is provided on the rear side to connect the accommodating space and the outside.

Here, when the installation body 161 is linked to the rotational motion and the moving direction is set to the front side, and the opposite side is set to the rear side, the front side is the front side when viewed from the plane as shown in FIG. 6 . It is desirable to form a protruding curved surface and to have a structure to minimize frictional force in penetrating and rotating while contacting water preferentially.

In addition, the installation body 161 has a longer length based on a plane than the side corresponding to the side corresponding to the outside (floating body 170 side) in the left and right direction (the side of the rotating pillar part 121) in the left and right direction Due to this, the rear end face of the installation body 161 is inclined at a predetermined angle and the nanobubbles are sprayed and discharged in the lateral direction opposite to the direction of movement each time along the rotational motion trajectory to effectively achieve the addition of driving force and driving force. It is preferable to have

In addition to the structural features described above, the installation body unit 161 has the installation body unit 161 in addition to the structural features described above so that the nano-bubble generating unit 160 can have an excellent movement trajectory more energy-efficiently and effectively through the ejection of nano-bubbles. It is important to specify the connection position of the and the formation position of the nano-bubble outlet 161H.

Specifically, when described with reference to FIGS. 5 to 7 in relation to the specificity of the connection position of the installation body 161, the installation body 161 has the vertical center point C2 of the rotary blade 124. It is arranged above the upper end height (T2), the lower end height (B1) is preferably connected to the rotary wing portion 124 so as to be disposed below the vertical center point (C4) of the rotary blade portion (124).

In addition, when describing with reference to FIGS. 5 to 7 in relation to specifying the formation position of the nano-bubble outlet 161H, the rear end surface of the installation body 161 is the vertical center point C3 of the nano-bubble outlet 161H. ) is disposed to be biased below the vertical center point (C1) of the installation body part 161, and the floating body 170 is connected to the left-right reference outside the left and right central point (C5) of the installation body part 121. It is preferable to have a structure in which it is arranged.

And in order to further maximize the effect due to these structural characteristics, as shown in FIG. 7 , from the vertical center point of the floating body 170 , the top surface height T1 of the installation body 161 and the position of the water surface, The distance D of the installation body 161 is preferably 40 cm under the premise that the installation body 161 is lower than the vertical center point C2.

This energy-efficiently and more effectively provide the power and propulsion required for the rotational movement of the installation body 161 through the injection and discharge tube of the nanobubbles, thereby reducing the degree of providing the driving force through the rotational driving unit 123 to a certain extent, thereby reducing energy consumption efficiency. Nanobubbles that are discharged and sprayed cause self-diffusion over a large area and a wide depth of water through their own Brownian motion, so that the functional area that can perform efficient water purification and restoration functions can be further expanded to the outside. It also affects the effectiveness and efficiency of the provision, and above all, it becomes possible to effectively provide a function even in an installation environment where there is little or no water flow.

Next, the nano-bubble generating unit 162 is installed in the receiving space of the installation body 161, and by spraying the generated nano-bubbles toward the rear side, the nano-bubbles are discharged to the outside through the nano-bubble outlet 161H. make it possible

As shown in FIG. 6 , the nano-bubble generating unit 162 that substantially generates the nano-bubbles in this way is the installation body 161 due to the provision of driving force through the rotating driving unit 123, the rotating pillar unit 121 and The rotary blade 124 is linked to the rotational movement direction (W1) and undergoes rotational movement together, and in addition to this, the driving force of the rotational movement direction (W1) by the injection direction (W2) of the nanobubbles injected and discharged from the rear side and addition of driving force.

In summary, the installation body 161 of each of the pair of nano-bubble generating units 160 is located at both ends of the rotor blade 124 in the left and right directions, respectively, in the forward direction based on the rotational direction of the rotor blade 124 . It faces the rotational direction and is installed so that the rear faces the opposite rotational direction so that the nanobubbles sprayed and discharged through the nanobubble outlet 161H drive the rotational motion of the rotary wing unit 124 so as to provide an additional driving force will be prepared

In addition, as shown in FIGS. 9 and 10 , the nano-bubble generating unit 162 receives water and air from the installation environment and reacts therein to generate nano-bubbles. is installed to accommodate.

And in this regard, an opening or an open path is established to carry out the inflow of water and air from the installation environment.

Specifically, the installation body 161 is provided with a plurality of first water micro inlets (not shown) on one side, so that the water on the water surface in which the nano-bubble generating unit 160 is disposed forms the first water micro inlets (not shown). The nano-bubble generating unit 162 may be introduced into the receiving space of the installation body 161 through the first water microinlet (not shown) in the receiving space of the installation body 161 on one side. A plurality of second water microinlets 162H are provided as shown in FIGS. 9 and 10 that are opened so that water can be introduced therein and used to generate nanobubbles.

In addition, the nano-bubble generating unit 162 has an open nano-bubble injection port 162H' on one side to discharge the nano-bubbles generated inside by using the water introduced through the second water micro-inlet 162H to the outside. provided

In addition, the nano-bubble generating unit 162 is installed in the receiving space within the installation body 161 as shown in FIG. 7 so that the nano-bubble injection hole 162H' faces the nano-bubble discharge port 161H side to each other.

In addition, as shown in FIG. 9, an air inlet 192A is provided on one side of the upper side of the nano-bubble generating unit 162 so that the inlet is exposed above the water surface. A predetermined open space for exposing to the outside is provided.

As a result, the nanobubble generating unit 162 sequentially passes through the first water microinlet (not shown) and the second water microinlet 162H to introduce the water and air inlet 192A from the installation environment from above the water surface. The nano-bubble generating modular pump 162P produces nano-bubbles by using the generated air, and then it is sprayed at a predetermined pressure through the nano-bubble injection port 162H', and eventually the nano-bubble outlet opened at the corresponding position ( 161H), the nanobubbles are discharged and spread widely left and right and up and down with the addition of certain driving force and power, causing a wide range of water purification, while at the same time improving the efficiency of water purification by increasing the fluidity of the water flow around the installation environment. do.

The monitoring unit 180 is provided with a module such as a CCTV, and the upper side of the rotation unit 120 on one side of the upper part of the installation space of the installation plate 110 . The second power generation unit 130, the third power generation unit 140, and the power storage unit 150 are installed so as to be able to observe the external state and take image information, and through a wireless communication network established with a preset management terminal. The captured video information is transmitted in real time.

Through this, the manager using the management terminal operates in real time, without directly visiting the nano-bubble-based water purification device 100 installed in the middle of the water, and various configurations related to the generation and use of electric power and the spraying and discharging of the nano-bubbles are operated properly. It is possible to quickly respond to a problem by visually identifying whether there is a problem or not.

The control unit 190 is a configuration for controlling electrical use and operation of the various components described above, and includes a power control unit 191 and an operation control unit 192 .

First, as shown in FIG. 8 , the power control unit 191 stores power produced through the first power generation unit 122 to the third power generation unit 140 in the power storage unit 150, and the power storage unit ( 150) controls the power output required for the operation of the rotation driving unit 123, the nano-bubble generating unit 160, the monitoring unit 180, and the control unit 190 itself.

In addition, the power control unit 191 is the first power generation unit 122 to the third power generation unit 140 through the renewable energy production status and power storage unit 150, and the rotation driving unit 123, nano-bubble generation The unit 160, the monitoring unit 180, and the control unit 190 detect and record the operating power usage status of the control unit 190 itself, and convert it into data, and use the power-related history information datad in this way as a preset management terminal to use a pre-established wireless communication network. It is transmitted at a preset period through the system so that the manager can check the power-related history information through the management terminal.

Next, the operation control unit 192 is based on a preset control command or a control command received from a preset management terminal through a pre-established wireless communication network for the operation form of the rotation driving unit and the monitoring unit receiving power through the power control unit. put to control

In addition to this, the control unit 190 further includes a sensor-based water quality management unit (not shown) that detects the amount of dissolved oxygen and residual amount of contaminants in the water, and converts changes in various detection values related to water quality into data to generate water quality detection information. In this way, the data-based power-related history information is transmitted to the preset management terminal at preset intervals through the established wireless communication network, so that the administrator can check the corresponding water quality detection information through the management terminal.

The embodiments disclosed in the present invention are intended to explain, not to limit the technical spirit of the present invention, and the scope of the technical spirit of the present invention is not limited by these embodiments. The scope of protection should be construed by the claims below, and all technical ideas within the scope equivalent thereto should be construed as being included in the scope of the present invention.

100: nano-bubble-based water purification device
110: mounting plate
111: first mounting plate part 112: second mounting plate part
113: third mounting plate part
120: rotation unit
121: rotating pillar 122: first power generation unit
123: rotation driving unit 124: rotating blade unit
130: second power generation unit 140: third power generation unit
150: power storage unit
160: nano bubble generating unit
161: installation body 162: nano-bubble generating unit
170: floating body 180: monitoring unit
190: control unit
191: power control unit 192: operation control unit

Claims (7)

a mounting plate installed to float on a water surface environment to provide a water purification function to provide at least one installation space on the upper side;
a rotating pole which protrudes up and down in the center of the installation space of the mounting plate and is rotatably installed; a first power generation unit connected to the upper portion of the rotating pillar at the upper side of the mounting plate to convert power according to the rotational motion of the rotating pillar into electrical energy to generate power; a rotation driving unit connected to an upper portion of the rotating pillar at an upper side of the mounting plate to provide a driving force necessary for the rotational movement of the rotating pillar; Rotating unit including a; rotational blades having the same height and length on both sides in the left and right directions from the lower end of the rotational column and extending in a plate shape of an upright structure with respect to the water surface;
a power storage unit electrically connected to the first power generation unit to store power generated from the first power generation unit, and output the stored power to be used for providing driving force through the rotation driving unit; and
As long as the rotor blades are connected to both ends of the left and right sides of the reference outer side and rotate in conjunction with the rotational movement of the rotation pillar and the rotor blades under the water surface by the driving of the rotation drive unit, the generated nano-bubbles are discharged into the water surface. A pair of nano-bubble generating units;
The nanobubble generating unit,
An installation body portion having a cylindrical shape having a predetermined accommodating space therein, and provided with an open nano-bubble outlet to connect the accommodating space and the outside to the rear side; and
It includes; a nano-bubble generating unit that is installed in the receiving space of the installation body and sprays the generated nano-bubbles toward the rear side so that the nano-bubbles can be discharged to the outside through the nano-bubble outlet;
The nano-bubble-based water purification device,
A pair of floaters each connected to the left and right outer side surfaces of the installation body to provide a predetermined floating force to each of the pair of nanobubble generating units; further comprising,
The installation body portion of each of the pair of nano-bubble generating units is located at both ends of the outer side of the rotary wing unit in the left and right direction, with the front facing the rotational direction based on the rotational direction of the rotating wing, and the rear facing the opposite direction of rotation It is installed so that the nano-bubbles sprayed and discharged through the nano-bubble outlet are provided so as to provide an additional driving force to drive the rotational motion of the rotary wing unit.
A nano-bubble-based water purification device with a renewable energy production function.
According to claim 1,
The nano-bubble-based water purification device,
a second power generation unit constructing a predetermined frame structure so that a plurality of photovoltaic panels are placed above the installation space of the mounting plate, and converting solar heat into electrical energy to generate power; and
The propeller rotating in the wind along the upper outer rim of the installation space of the installation plate and the installation poles for arranging them at a certain height are constructed in a structure in which a plurality of installation columns are arranged at the same distance from each other to convert wind power into electrical energy to produce electricity 3 power generation unit; further including,
The power storage unit is electrically connected to the second power generation unit to the third power generation unit to store power generated from the second power generation unit to the third power generation unit, and to use the stored power to provide driving force through the rotation driving unit. Characterized in outputting so that
A nano-bubble-based water purification device with a renewable energy production function.
3. The method of claim 2,
The nano-bubble-based water purification device,
An upper side of the rotation unit on one side of the upper portion of the installation space of the mounting plate. A monitoring unit that is installed to observe the external state of the second power generation unit, the third power generation unit, and the power storage unit to photograph image information, and transmits the captured image information in real time to a preset management terminal through a pre-established wireless communication network ; and
a power control unit configured to store power generated through the first to third power generation units in the power storage unit, and to control the power output required for the operation of the rotation driving unit and the monitoring unit from the power storage unit; and an operation control unit for controlling the operation types of the rotation driving unit and the monitoring unit receiving power through the power control unit based on a preset control command or a control command received from a preset management terminal through a pre-established wireless communication network. A control unit comprising a; characterized in that it further comprises
A nano-bubble-based water purification device with a renewable energy production function.
delete According to claim 1,
The installation body portion is provided with a plurality of first water microinlets on one side so that water on the water surface in which the nanobubble generating unit is disposed can be introduced into the receiving space of the installation body portion through the first water microinlets,
The nano-bubble generating unit is provided with a plurality of open second water micro-inlets so that the water introduced through the first water micro-inlet is introduced into the receiving space of the installation body on one side and used to generate nano-bubbles. ,
The nano-bubble generating unit is provided with an open nano-bubble injection port on one side to discharge the nano-bubbles generated inside using the water introduced through the second water micro-inlet to the outside,
The nano-bubble generating unit is characterized in that it is installed in the receiving space within the installation body so that the nano-bubble injection port faces each other toward the nano-bubble outlet side.
A nano-bubble-based water purification device with a renewable energy production function.
6. The method of claim 5,
The installation body portion is connected to the rotary wing so that the vertical center point is disposed above the top height of the rotary wing portion, and the lower end is disposed below the vertical center point of the rotary wing portion,
The rear end surface of the installation body part is arranged so that the vertical center point of the nano-bubble outlet is biased lower than the vertical center point of the installation body part, and the left-right reference to which the floating body is connected rather than the left-right central point of the installation body part. characterized in that it has a structure that becomes
A nano-bubble-based water purification device with a renewable energy production function.
7. The method of claim 6,
The outer side to which the installation body is connected based on the center point in the left and right directions of the rotary wing is bent toward the rear side of the installation body from the vertical center point toward the top, and is bent toward the front side of the installation body as it goes to the bottom, and propeller blades part of the structure,
The inner side to which the rotating pillar part is connected based on the left and right center point of the rotating blade part is bent toward the front side of the installation body part from the vertical center point toward the upper end, and is bent toward the rear side of the installation body part toward the bottom, and propeller blades characterized by having a part of the structure
A nano-bubble-based water purification device with a renewable energy production function.

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