• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The present invention relates to a windmill type oxygen supply for improving water quality, while using wind power as a power source and supplying oxygen to the water to prevent eutrophication of the water system, and having a predetermined width and size, and is formed inside the body. A space part 11 is provided, and a fitting groove 12 is located at the center of the upper body, and a casing 10 having a discharge port 13 formed at the lower part of the body; A subsidiary body 20 installed outside the casing 10 to allow the casing 10 to rise above the surface of the water; It is installed upright in the fitting groove 12 of the casing 10 so that the upper part of the body protrudes to the outside of the casing 10, the lower part of the body is located inward, the air induction groove 31 is formed in the body The upper body, the rotary shaft 30 is provided with an external air inlet groove 32; A fixed shaft 40 installed at the bottom of the rotary shaft 30 to support the rotary shaft 30 and having a connection groove 41 communicating with the air guide groove 31 inside the body; A power generating member (50) installed outside the upper portion of the rotating shaft (30) to drive the rotating shaft (30) by wind power; A power transmission unit 60 formed at a lower portion of the body of the rotating shaft 30 to transmit a driving force of the rotating shaft 30 driven by the power generating member 50 in a lateral direction; A driving shaft 70 formed at both sides of the power transmission unit 60 and operated by a driving force of the rotating shaft 30, and having a rotating plate 71 as a body end; An oxygen supply unit 80 which is installed eccentrically to the outside of the rotating plate 71 of the drive shaft 70 and moves up and down by rotation of the drive shaft 70 to generate oxygen; A connection hose 90 installed in the connection groove 41 of the oxygen supply unit 80 and the fixed shaft 40 to move external air to the oxygen supply unit 80; In order to discharge the air generated from the bottom of the oxygen supply unit 80 to the outside, a check valve 110 is provided at the center of the body is composed of a discharge hose 100 which is installed in the outlet 13 of the casing 10 Therefore, the oxygen is supplied while driving the wind power as a power source, it is possible to improve the water quality by preventing eutrophication of the water system. Therefore, it is a very useful invention that can improve the reliability and commerciality of the product.
    公开号:KR20000059186A
    申请号:KR1020000041709
    申请日:2000-07-20
    公开日:2000-10-05
    发明作者:소용호
    申请人:소용호;
    IPC主号:
    专利说明:

    Fan-driven oxygen supply system for water improvement
    The present invention relates to a windmill type oxygen feeder for water quality improvement, and more particularly, it is invented to prevent eutrophication of water quality by supplying oxygen into water while using wind power as a power source.
    In general, domestic sewage and factory wastewater contain a large amount of substances such as phosphorus and nitrogen, and the water of rivers and seas where such domestic sewage and factory wastewater flows increases nutrient salts such as phosphates and nitrates, causing eutrophication. do.
    In addition, when water is eutrophiced, phytoplankton suddenly occurs largely, red tide occurs, and dissolved oxygen (DO) decreases, causing fish and shellfish to die.
    Therefore, in order to prevent eutrophication of water systems such as rivers and lakes, sewage and wastewater should be treated with advanced technology, and it is recommended to use detergents with low phosphorus content and to control waste disposal in urban or rural areas. It should also be prepared.
    On the other hand, in order to prevent eutrophication of the water system, it is necessary to increase the amount of dissolved oxygen in the water, and for this purpose, the aeration method is mainly used.
    The aeration method is roughly divided into a water agitation method such as aberration and an underwater acid method such as an air blow.
    In addition, the selection of the aeration system should carefully consider the equipment cost, maintenance cost, operation method, installation and movement of the equipment, the type of power source.
    The oxygen generator for preventing the eutrophication of the conventional water system configured as described above is formed to supply oxygen using electric power in most cases, and there are many problems in maintenance and management for long-term use.
    In addition, although a chemical material may be used in addition to a device for supplying oxygen by electric power, the operation cost is expensive at this time, and in some cases, adverse effects of water quality may be required.
    SUMMARY OF THE INVENTION An object of the present invention is to provide a windmill type oxygen feeder for water quality improvement that can prevent eutrophication of water quality by supplying oxygen into water while using wind power as a power source.
    Another object of the present invention is to provide a windmill type oxygen feeder for water quality improvement to improve the reliability and commerciality of the product.
    1 is a cross-sectional view showing the durability configuration of the present invention water quality windmill oxygen supply.
    Figure 2 is a plan view showing the shape of the present invention water quality windmill oxygen supply.
    Figure 3 (A), (B) is an enlarged view of the main portion showing the operating state of the drive unit for supplying a power source to the oxygen supply unit.
    * Description of the symbols for the main parts of the drawings *
    10-casing 11-space
    12-fitting groove 13-outlet
    14-fixed face 15-hook
    20-Sphere 30-Spindle
    31-Air guide groove 32-External air inlet groove
    33-Shroud 40-Fixed Shaft
    41-Connecting groove 50-Power generating member
    51-Wings 60-Power Train
    61-Bevel Gear 70-Drive Shaft
    71-rotating plate 80-oxygen generator
    81-connecting rod 82-packing
    83-Sealed tube 90-Connection hose
    100-Exhaust Hose 110-Check Valve
    111-exhaust groove
    The object of the present invention, while using the wind power as a power source, to supply oxygen in the water to prevent the eutrophication of the water system is formed with a predetermined width and size, the space portion 11 is provided inside the body And a fitting groove 12 is positioned at the center of the upper body, and a casing 10 at which the outlet 13 is formed at the lower part of the body;
    A subsidiary body 20 installed outside the casing 10 to allow the casing 10 to rise above the surface of the water;
    It is installed upright in the fitting groove 12 of the casing 10 so that the upper part of the body protrudes to the outside of the casing 10, the lower part of the body is located inward, the air induction groove 31 is formed in the body The upper body, the rotary shaft 30 is provided with an external air inlet groove 32;
    A fixed shaft 40 installed at the bottom of the rotary shaft 30 to support the rotary shaft 30 and having a connection groove 41 communicating with the air guide groove 31 inside the body;
    A power generating member (50) installed outside the upper portion of the rotating shaft (30) to drive the rotating shaft (30) by wind power;
    A power transmission unit 60 formed at a lower portion of the body of the rotating shaft 30 to transmit a driving force of the rotating shaft 30 driven by the power generating member 50 in a lateral direction;
    A driving shaft 70 formed at both sides of the power transmission unit 60 and operated by a driving force of the rotating shaft 30, and having a rotating plate 71 as a body end;
    An oxygen supply unit 80 which is installed eccentrically to the outside of the rotating plate 71 of the drive shaft 70 and moves up and down by rotation of the drive shaft 70 to generate oxygen;
    A connection hose 90 installed in the connection groove 41 of the oxygen supply unit 80 and the fixed shaft 40 to move external air to the oxygen supply unit 80;
    In order to discharge the air generated from the bottom of the oxygen supply unit 80 to the outside, a check valve 110 is provided at the center of the body is composed of a discharge hose 100 which is installed in the outlet 13 of the casing 10 Is achieved.
    Therefore, the windmill oxygen supplier for water quality improvement of the present invention uses wind power as a power source, and thus supplies oxygen while driving the wind power as a power source, thereby improving water quality by preventing eutrophication of the water system.
    Therefore, the reliability and the merchandise of the product can be improved.
    Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.
    1 is a cross-sectional view showing the durable configuration of the windmill oxygen supplier for improving the water quality of the present invention.
    Figure 2 is a plan view showing the shape of the present invention water quality windmill oxygen supply.
    3 (A) and 3 (B) show an enlarged view of main parts of an operating state of a drive unit for supplying a power source to an oxygen supply unit.
    That is, as shown in Figs. 1 to 3, the casing 10 of the present invention for improving water quality of the windmill type oxygen supply, while supplying oxygen to the water while using wind power as a power source, to prevent eutrophication of the water system, It is formed with a width and size of the inside of the body is provided with a space portion 11, the fitting groove 12 is located in the center of the upper body, the outlet 13 is formed in the lower body.
    In addition, the upper side of the casing 10, the subsidiary body 20 is provided so that the casing 10 is floated on the water surface.
    The spherical body 20 is formed so that the casing 10 is floated at a set height from the water surface, and the shape of the spherical body 20 is located on the water surface, so that the outside is not caught in the process of contacting tree branches and the like. It is preferable to mold with.
    In addition, in order to prevent the casing 10 from being floated by rainy weather or wind power, it is preferable to form a separate fastener so as to be fixed to the ground.
    In addition, it is important to set the buoyancy of the sub-sphere 20 so that the casing 10 can be fixed at a height set up and down about the water surface.
    This is because when the set position of the casing 10 is located too close to the ground, the discharge hose 100 to be described later is clogged due to the injuries such as floating matters, and if it is set too high, it is supplied into the water Since the supply effect of oxygen falls, it is preferable to set the buoyancy force of the substructure 20 in view of the above problems.
    Therefore, the casing 10 is preferably set so that it can be located about 1-2m from the underwater ground.
    On the other hand, in the fitting groove 12 of the casing 10 upright body protrudes to the outside of the casing 10, the lower body is located inward, the air induction groove 31 is formed in the body The upper portion of the body is provided with a rotating shaft 30 is provided with an external air inlet groove (32).
    The air induction groove 31 formed inside the body of the rotating shaft 30 is formed to supply external air to the oxygen supply unit 80 to be described later, and the cover is formed on the upper surface of the outer air inlet groove 32. It is possible to prevent the inflow of water and the like by installing 33.
    In addition, the bottom of the rotating shaft 30 supports the rotating shaft 30, and the inside of the body is provided with a fixed shaft 40 is provided with a connection groove 41 in communication with the air induction groove 31.
    The fixed shaft 40 supports the rotating shaft 30 at the bottom of the rotating shaft 30, and simultaneously moves the external air supplied to the air induction groove 31 of the rotating shaft 30 to the oxygen supply unit 80. , The connecting groove 41 is formed in the body.
    On the other hand, the power generating member 50 for driving the rotary shaft 30 by the wind is installed on the upper outer side of the rotary shaft 30.
    The power generating member 50 is provided with a blade 51, as shown in Figures 1 and 2 so as to drive the rotating shaft 30 by the wind.
    In addition, the blade 51 may be used to bend the end so that the wind can be more easily transmitted to the rotating shaft (30).
    In addition, the wings can be used by painting a fluorescent paint to easily identify the location at night.
    Therefore, the rotary shaft 30 is the blade 51 is a power generating member 50 is installed on the upper body, it can be driven while the blade 51 is rotated by the wind on the water surface.
    On the other hand, the lower portion of the body of the rotating shaft 30 is provided with a power transmission unit 60 for transmitting the driving force of the rotating shaft 30 driven by the power generating member 50 in the transverse direction.
    The power transmission unit 60 is used by installing a pair of bevel gears 61 so as to transmit the driving force of the rotating shaft 30 is installed upright in the transverse direction.
    That is, a pair of bevel gears 61, which are power transmission units 60 formed under the body of the rotating shaft 30, are installed on the driving shaft 70 and the rotating shaft 30 to be described later, respectively, to drive the driving force of the rotating shaft 30. It can be delivered to the drive shaft 70 is positioned in the transverse direction.
    Then, both sides of the power transmission unit 60 is provided with a drive shaft 70 which is interlocked by the driving force of the rotary shaft 30.
    In addition, since the driving shaft 70 is provided with a rotating plate 71 at the end of the body, the rotating plate 71 may be rotated together with the driving of the rotating shaft 30.
    Accordingly, the drive shaft 70 is driven in conjunction with the drive shaft 70 when the rotary shaft 30 is driven by the power transmission unit 60, and the rotary plate 71 formed as an end of the drive shaft 70 also rotates together with the drive shaft 70. Will be.
    On the other hand, the oxygen supply unit 80 for generating oxygen while being moved up and down by the rotation of the drive shaft 70 is installed eccentrically to the outer side of the rotating plate 71 of the drive shaft 70.
    The oxygen supply unit 80 is eccentrically installed on the outer side of the body of the rotating plate 71 is driven up and down while driving the rotating plate 71, so as to generate oxygen, the packing on the outer end of the rotating plate 71 ( A connecting rod 81 having the 82 installed therein is installed, and a sealing tube 83 is formed outside the connecting rod 81.
    Therefore, the connecting rod 81 is driven up and down by the rotation period of the rotating plate 71 when the rotating plate 71 rotates, and the packing 82 generates oxygen while moving up and down inside the sealed tube 83. It can be done.
    In addition, the casing 10 may be moved to the bottom of the sealed tube 83, which is the oxygen supply unit 80, so that the sealed tube 83 may be moved in accordance with the operating cycle of the connecting rod 81 when the connecting rod 81 is operated. Since it is fixed by the fixing surface 14 and the ring 15, it is possible to smoothly operate the connecting rod (81).
    In addition, a connection hose 90 is installed between the sealed tube 83 of the oxygen supply unit 80 and the connecting groove 41 of the fixed shaft 40 to supply external air to the sealed tube 83.
    In addition, the connection hose 90 is preferably formed of a flexible hose so that the position can be fixed to the gap generated during the operation of the connecting rod (81).
    On the other hand, the bottom surface of the oxygen supply unit 80 is provided with a check valve 110 in the center of the body so that the air generated by the driving of the connecting rod 81 to the outside is provided with a discharge port 13 of the casing 10 Is installed in the discharge hose (100).
    As shown in FIG. 1, the discharge hose 100 has a plurality of discharge grooves 111 formed at an end thereof to smoothly supply oxygen into the water.
    And, the check valve 110 is installed in the body center portion of the discharge hose 100 can prevent the phenomenon of water flow back into the discharge hose (100).
    Therefore, the windmill oxygen supplier for water quality improvement of the present invention can supply oxygen to the water by using wind power, thereby improving water quality by preventing eutrophication.
    According to the present invention as described above, because wind power is used as a power source, unmanned management is possible, maintenance and management is easy and economical.
    It can also be used as a buoy for underwater position (height and position) adjustment.
    And, because it uses the wind power without using power, it is possible to continuously supply oxygen, it is a very useful invention that can improve the water quality by preventing eutrophication.
    权利要求:
    Claims (3)
    [1" claim-type="Currently amended] While using wind power as a power source, it is formed to have a predetermined width and size so as to supply oxygen into the water to prevent eutrophication of the water system, and the space portion 11 is provided inside the body, A fitting groove 12 is positioned, and a casing 10 having an outlet 13 formed at a lower portion of the body;
    A subsidiary body 20 installed outside the casing 10 to allow the casing 10 to rise above the surface of the water;
    It is installed upright in the fitting groove 12 of the casing 10 so that the upper part of the body protrudes to the outside of the casing 10, the lower part of the body is located inward, the air induction groove 31 is formed in the body The upper body, the rotary shaft 30 is provided with an external air inlet groove 32;
    A fixed shaft 40 installed at the bottom of the rotary shaft 30 to support the rotary shaft 30 and having a connection groove 41 communicating with the air guide groove 31 inside the body;
    A power generating member (50) installed outside the upper portion of the rotating shaft (30) to drive the rotating shaft (30) by wind power;
    A power transmission unit 60 formed at a lower portion of the body of the rotating shaft 30 to transmit a driving force of the rotating shaft 30 driven by the power generating member 50 in a lateral direction;
    A driving shaft 70 formed at both sides of the power transmission unit 60 and operated by a driving force of the rotating shaft 30, and having a rotating plate 71 as a body end;
    An oxygen supply unit 80 which is installed eccentrically to the outside of the rotating plate 71 of the drive shaft 70 and moves up and down by rotation of the drive shaft 70 to generate oxygen;
    A connection hose 90 installed in the connection groove 41 of the oxygen supply unit 80 and the fixed shaft 40 to move external air to the oxygen supply unit 80;
    In order to discharge the air generated from the bottom of the oxygen supply unit 80 to the outside, the check valve 110 is provided at the center of the body is composed of a discharge hose 100 which is installed in the outlet 13 of the casing 10 Windmill-type oxygen supply for improving water quality.
    [2" claim-type="Currently amended] 2. The windmill type oxygen supplier for water quality improvement according to claim 1, wherein a pair of bevel gears (61) is used as the power transmission unit (60).
    [3" claim-type="Currently amended] The method of claim 1, wherein the oxygen supply unit 80 is fixed to the end of the outer circumferential surface of the rotating plate 71, the bottom of the body connecting rod 81 is provided with a packing (82);
    Windmill type oxygen supply for improving the water quality, characterized in that consisting of a closed tube (83) located on the outside of the connecting rod (81).
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    同族专利:
    公开号 | 公开日
    KR100380185B1|2003-04-14|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    法律状态:
    2000-07-20|Application filed by 소용호
    2000-07-20|Priority to KR20000041709A
    2000-10-05|Publication of KR20000059186A
    2003-04-14|Application granted
    2003-04-14|Publication of KR100380185B1
    优先权:
    申请号 | 申请日 | 专利标题
    KR20000041709A|KR100380185B1|2000-07-20|2000-07-20|Fan-driven oxygen supply system for water improvement|
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