KR101563946B1 - Sleeping structures for condensate collection - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water surface structure for collecting condensed water. More particularly, the present invention provides water and water for rapidly collecting water vapor evaporated from the water surface into the air.
Generally, the moisture that is generated in the air from the sea surface of rivers, reservoirs or coastal areas will emerge into the air, and rain will form due to the difference between low pressure and temperature.
Therefore, as an invention for solving the problem described above,
A book 25 fixed to the end of the frame 21 protruding to both sides of the working line 10 provided with the storage tank 22 protruded by the guide plate 23 and the control device 14, Wow; A heating pipe 32 having a jet port 33 supported by a fixing table 45 on a water surface 11 which is a section between the working line 10 and the load unit 25,
A jacket 40 provided with a photovoltaic power generation plate 20 protruding in a curved shape at the one side of the loader 25 and an induction plate 46 projecting obliquely from the other side of the load 25;
A movement section 47 formed by a shielding film 29 for providing an inner section at both ends of the jacket 40 and the induction plate 46,
A discharge port 19 provided in the interval between the jacket 40 and the upper end of the induction plate 46; a wind power generator 60 provided in the discharge port 19; A cool air bag 15 provided with a jet table 16 connected by a shown pressurizing pump, In a condensate water collecting apparatus provided with a long oil guide plate (65) for guiding a condensate protruding from an end of a storage tank (22)
A support wall 56 fixed to the outside of the ends of the guide plate 46 and the jacket 40 provided on both sides of the discharge port 19 and a support wall 56 fixed to the upper end of the support wall 56 A rotary space 66 which is formed with an inlet 58 and an outlet 59 of the wind power and is linked to the upper side of the discharge port 19,
A condensing section 54 having a wind turbine 60 formed of a rotary drum for extruding a rotary drum 45 to a rotary shaft 70 passing through the rotary space 66, 47) includes a control device (14) provided with a pressurization and suction pump (61, 62) for dividing into a plurality of stages;
A first diaphragm 41 passing through the suction port 57 so as to have an upper evaporation section 51 and a lower pressure section 52 of the heating tube 32,
A second diaphragm 42 provided with a suction pump 61 so as to form a low-pressure section 52 on the upper side of the first diaphragm 41,
A pressurizing pump 62 provided in a pressurizing section 53 formed by a third diaphragm 43 provided on the upper side of the second diaphragm 42 at the end of the storage tank 22 and below the discharge port 19, A spray stage 30 sprayed into the condensation section 54 through the third diaphragm 43 and a spray port 36 and a cool air duct 38 through which fine holes penetrate the spray stage 30 A cold air blowing block 68 formed of sprayed water 39 and pressurized air and a cold air blower 15 provided in the blowing block 16 to cool the hot air blowing block 68 Invention.

The rotary drum 45 of the rotary space 66 is rotated by the high pressure air jetted from the cold air tube 38 of the cold air blowing block 68 to the discharge port 19 of the condensation section 54,
The evaporation section 51 and the low pressure section 52 of the first reduced pressure state and the low pressure section 52 of the first diaphragm 42 are provided in the section between the heating pipe 32 and the moving section 47 for condensing water vapor, (30) for spraying the steam that has been pressurized by the pressurizing pump (62) in the pressurizing section (53), and a spraying section The cooling air blown out from the cooling air bobbin 15 is blown into the cold air blowing block 68 formed by mixing the spray water 39 of the water vapor and the pressurized air blown out from the cooling air pipe 38 supplied from the separate pressurizing device, The water vapor of the spray water 39 sprayed from the spray booth 30 is condensed.

Description

Condensate collecting sleeping structures {Omitted}

 BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water surface structure for trapping condensed water. More particularly, the present invention relates to a water surface structure for trapping condensed water vapor rapidly evaporated on a water surface.

  Generally, the moisture generated from the sea surface of a river, reservoir, or coastal area into the air is emitted to the air, and the rain formed by the difference between the low pressure and the temperature drops down to the ground.

  In addition, the sunlight that shines in the air keeps the southward direction and tilts it obliquely, and also blows the north wind mainly in the cold weather.

As the rainwater is scattered in the air and the cold air and the warm air come into contact with each other while moving in the low pressure state, the water vapor grains mixed with each other gradually turn on due to the formation of the cohesive force, It falls.

   In addition, the water quality of the river or lake described above is often subject to various limitations in terms of contamination to the area or use as living water.

   In addition, the sea level in the coastal area is high in salinity and difficult to use as drinking water.

By blowing cold air so as to liquefy the sprayed water particles, a large mass of rainwater particles as much as possible in the molecular state of the water can be obtained by spraying the water vapor inducing evaporation with high- By condensation, the rainwater falls into formation.

 Especially in areas where water is scarce or polluted, the shortage of drinking water is high due to mostly dry areas and local heavy rainfall. In areas where sunlight is high, securing drinking water and water is an important issue.

  In addition, since the sea level of the coastal area is much larger than that of the nearby land due to the difference in temperature, the structure of the solar panel provided with a large area as well as the wind power generation facilitates the collection of the condensed water And to provide it as a practical device.

In addition, in the sprayer 30 'or the sprayer widely used in the prior art, the water droplet 39' of the coarse grains is dropped by its own weight by performing the spraying of the water with the jetting port 36 ' (Fig. 7). In the present invention,

In the present invention, water vapor is generated in the above-described water surface for use as environmentally friendly drinking water in a lake or sea surface, and the water vapor is collected as condensation as condensation water to store water in the reservoir.

  Accordingly, the present invention provides pure water that can be used environmentally friendly in polluted rivers, lakes, and coastal areas.

 In the present invention, water vapor is generated at a low pressure where rainfall occurs.

     In addition, in the present invention, the rotary drum of the wind turbine is rotated by using a rapid discharge to discharge pressurized air for condensate generation in the condensation section to the discharge port.

   That is, in the present invention, the use of sunlight and wind power according to season changes is maximally efficient, and a multistage pressure section for adjusting the moving section and the condensation section of the collecting device, which is the main part of the present invention, Thereby reinforcing the condensation power of the water vapor.

A book 25 fixed to the end of the frame 21 protruding to both sides of the working line 10 provided with the storage tank 22 protruded by the guide plate 23 and the control device 14, Wow; A heating pipe 32 having a jet port 33 supported by a fixing table 45 on a water surface 11 which is a section between the working line 10 and the load unit 25,

  A jacket 40 provided with a photovoltaic power generation plate 20 protruding in a curved shape at the one side of the loader 25 and an induction plate 46 projecting obliquely from the other side of the load 25;

A movement section 47 formed by a shielding film 29 for providing an inner section at both ends of the jacket 40 and the induction plate 46,

A discharge port 19 provided in the interval between the upper end of the jacket 40 and the guide plate 46, a wind power generator 60 provided in the discharge port 19, A cool air bag 15 provided with a jet table 16 connected by a pressurizing pump not shown, In a condensate water collecting apparatus provided with a long oil guide plate (65) for guiding a condensate protruding from an end of a storage tank (22)

  A support wall 56 fixed to the outside of the ends of the guide plate 46 and the jacket 40 provided on both sides of the discharge port 19 and a support wall 56 fixed to the upper end of the support wall 56 A condensation section 54 having an inlet 58 and an outlet 59 for the wind power and a rotary space 66 interlocked with the upper side of the discharge port 19,

 A wind turbine 60 formed of a rotary drum for extruding a rotary drum 45 to a rotary shaft 70 passing through the rotary space 66,

  A control device 14 provided with a pressure and suction pump 61 (62) for dividing the moving section 47 into a plurality of stages;

 A first diaphragm 41 penetrating through the suction pump 61 and the suction port 57 so that the upper evaporation section 51 of the heating pipe 32 is provided,

  A second diaphragm 42 provided with a suction pump 61 so as to form a low-pressure section 52 on the upper side of the first diaphragm 41,

  A pressurizing pump 62 provided in a pressurizing section 53 formed by a third diaphragm 43 provided on the upper side of the second diaphragm 42 at the end of the storage tank 22 and below the discharge port 19, The spray water 39 sprayed into the condensation section 54 in the spray hole 36 of the fine hole passing through the spray stage 30 provided through the third partition plate 43 is sprayed to the cooler The cooling air blowing block 68 sprayed with the cooling air sprayed from the cooling air pipe 38 connected to the blowing fan 38 is provided so as to promote the condensation to the cold air of the cooling air bobbin 15 provided with the blowing fan 16.

  The rotary drum 45 of the rotary space 66 is rotated by the high pressure air jetted from the cold air pipe 38 of the cold air blowing block 68 to the discharge port 19 of the condensation section 54,

The evaporation section 51 and the low pressure section 52 of the first reduced pressure state and the low pressure section 52 of the first diaphragm 42 are provided in the section between the heating pipe 32 and the moving section 47 for condensing water vapor, (30) for spraying the steam that has been pressurized by the pressurizing pump (62) in the pressurizing section (53), and a spraying section The cooling air blown out from the cooling air bobbin 15 is blown into the cold air blowing block 68 formed by mixing the spray water 39 of the water vapor and the pressurized air blown out from the cooling air pipe 38 supplied from the separate pressurizing device, The water vapor of the spray water 39 sprayed from the spray booth 30 is condensed.

 The present invention relates to a method for producing condensed water by eco-friendly photovoltaic power generation or the like, effectively storing water condensed as a capture when the water is insufficient due to pollution or drought in a lake or a coastal area, will be.

  In addition, it can be easily installed on a water surface by a charcoal or the like, and it is possible to control the flow path of the water vapor in multiple steps, control the pressurized state, and simultaneously suck and spray the fine particles. It is an eco-friendly device that enhances the effects of photovoltaic power generation, saves operating expenses, and provides water necessary for daily life.

FIG. 1 is a perspective view of a concave portion provided conventionally.
2 is a sectional view taken along the line AA in Fig. 1
Figure 3 is a partially cutaway perspective view of an embodiment of a recess in the present invention;
Figure 4 is an enlarged partial perspective view of the recess in Figure 3;
Figure 5 is an enlarged cross-sectional view of the condition of use for the recess in Figure 4;
Figure 6 is an enlarged partial perspective view of the recess in Figure 5;
Fig. 7 is a partial perspective view of a conventional recess

As an invention to be described in detail with reference to the accompanying drawings, one embodiment for on-site construction according to the present invention described above,

   2 is a cross-sectional view taken along the line A-A in Fig. 1, and Fig. 3 is a partially cut-away partial perspective view of an embodiment of the recess in the present invention. Fig. 4 is an enlarged partial perspective view of the recess in Fig. 3, Fig. 5 is an enlarged sectional view of the recess in use in Fig. 4, Fig. 6 is an enlarged partial perspective view of the recess in Fig. And is a partial perspective view of a recess used conventionally.

 1 and 2, in a water surface 11 of a lake or a coastal area having a large area, a general merchant line, a work line 10, In order to provide robustness while providing buoyancy, an invention in which a frame 21 and a screw or the like are fixed to each other so as to be robustly manufactured by wind or current in a work process on the water surface, is disclosed in Korean Patent Application No. 10-2010-0098022 No. 10-2010-140541.

  That is, in the present invention, in order to reinforce the generation power against the sunlight that slants in an oblique manner, the convexly-projecting jacket is formed by the induction plate 46 which is obliquely inclined at one side and inclined at the other side If you explain the configuration in detail,

 And a controller 14 for controlling the condenser, the freezer, etc. necessary for driving the commercial line 10 and the like.

The slope of the sunlight shining on the water surface is formed by a suspension section 47 formed on the water surface 11 of both side sections of the work line 10 in accordance with the slope, (Hereinafter referred to as "bookkeeping").
The movable section 47 formed between the work line 10 and the cover 25 on one side is provided with a jacket (not shown) provided with the solar power generation plate 20 so as to cover the jacket 25 in a curved state, 40 and the end of the guide plate 46 protruding from the annular groove 25 of the other side of the working line 10 is provided with a spacing section formed in a predetermined section so as to have the jet port 33 give.

A storage water tank 22 having a length along the longitudinal direction is provided on the inner bottom of the working line 10, and at the center of the upper surface of the storage tank 22, An induction plate 23 is formed which is tilted so as to face opposite sides to form an inflow section of water upward.

  The jacket 40 which is inclined at one side of the booklet 25 described above and the guide plate 46 which is curvedly projected at the other side of the booklet 25 provide a balance The water vapor condensed in the condensation section 54 flows easily into the water storage tank 22 by projecting the induction plate 23 projecting obliquely from the upper end of the water storage tank 22 to the long water guide plate 65 (Fig. 2)

As described above, in order to reinforce the collecting efficiency with respect to the oblique sunlight, the guide plate 23, in which an inflow section of water is formed above the wall of the water storage tank 22, 2, a jacket 40 protruding obliquely from the inside space of the condensed water collecting apparatus, which is a main part of the present invention, and an induction plate 46 protruding from the other adiabatic 25 (Not shown), which is described later, in accordance with the movement section 47 formed on both sides of the condensation section 54, So that the condensed water flows in the condensation section 54. The condensed water in the condensation section 54 is condensed in the condensation section 54 so that condensed water condensed in the condensation section 54 is led to the water storage tank 22, do.

  Therefore, it is possible to collect steam-containing water vapor, which is the object of the present invention, using the above-described working line 10, as condensed water. However, according to the inclination of sunshine or the seasonal change, A water tank 22 for storing water is provided on the inner bottom of the working line 10 in a lengthwise direction. The water tank 22 is provided at the center of the upper surface of the water tank 22. 22, the guide tube 23 is inclined so as to face the both sides of the guide tube 23 and forms an inflow section of the water upward.

  The heating pipe 32 is closely pierced so as to generate steam of high temperature while being immersed in the water surface 11 at both sides in the longitudinal direction of the work line 10 in order to accelerate the generation of water vapor and to condense the water. And a buoy 25 is provided on the outside of the heating pipe 32 in accordance with the longitudinal direction of the work line 10 so as to seal the water surface while providing buoyancy at the water surface 11.

 In addition, in order to provide an environmentally friendly power while providing a space between the attachments 25 provided on both sides at a low pressure, an end portion of the inclined jacket 40, which is inclinedly projected at one of the attachments 25, A discharge port 19 formed at a predetermined spaced interval between ends of the induction plate 46 projecting obliquely from the discharge port 25 and a condensation section 54 connected to the lower side of the discharge port 19 And the wind turbine generator 60, which will be described later, is provided above the discharge port 19.

  This is because the discharge port 19 which is a section between the jacket 40 and the end of the induction plate 46 is provided with water vapor moving in the movement section 47 in the condensation section 54, And is a section for discharging the remaining blown air by the formation of condensed water collected by the cooling air ejected from the blower 16 connected to a cooling pump not shown.

Therefore, it is an invention to provide a wind power generator (60) for generating wind power by blowing wind using the discharge space of the discharge port (19).

A jacket 40 is formed at both ends of the jacket 40 and the jacket 40 is formed at both ends of the guide plate 46. The jacket 40 is formed at both ends of the outlet 19, Which is fixed at a predetermined interval between both ends of the guide plate 46 and the jacket 40 provided with the discharge port 19 and fixed to the outer surface at the end of the guide plate 46, (56) and an outer wall body (49) covering the upper side of the supporting wall body (56), an inlet (58) and an outlet (59) are formed and a section in which the outlet (19) is formed is convexly covered, An inner space 66 is formed between the inlet 58 and the outlet 59 so as to be connected to the outer wall body 49. The inner space 66 is provided with a rotary drum 45, And rotates the rotary drum 45 by the wind force blowing from the air.

 This is because the inlet 58 and the outlet 59 of the wind force are formed on the outer surface of the spaced apart end of the fixed jacket 40 and the induction plate 46 and the wind power generator 60 A plurality of supporting walls 56 provided at a predetermined interval between the spaced apart ends and an upper wall of the supporting wall 56 fixed by an outer wall body 49 to form an inlet 58, The outer wall body 49 forming the section between the inlet 58 and the outlet 59 is convexly curved so that the inlet 58 and the outlet 59 And a shielding film 29 for fixing the opposite ends of the rotation space 66. The rotation space 66 is provided at the upper side of the spaced outlet 19 between the rotary shaft 66 and the rotary shaft 66.

  The wind turbine generator is configured to generate power from a generator (not shown) by a rotational force of a rotary drum (45) provided on a rotary shaft (70) passing through a shielding film (29) provided on both sides of the rotary space (66) (60).

The description of the embodiment for generating power to the wind turbine generator 60 includes a rotating space 66 provided above the discharge port 19 and a rotating space 66 provided for rotating the rotating space 66 The rotary drum 45 is formed so as to make wind power generation.
The cool air duct 38 of the spray plate 30 for the cool air ejection block 68 provided at the upper side of the condensation section 54 and the cool air duct 38 provided with the spray plate 16 connected by a pressurizing pump 15, the high-pressure air supplied to the pressurizing pump discharges at a high discharge rate, thereby providing power generation by the rotational force of the rotary drum 45 for the wind turbine generator 60.

  This is an invention for enhancing economical efficiency by supplying power for collecting condensed water for the purpose of the present invention in a weather condition or a windless weather.

Also, in the condensation section 54, the pressurized air for generating condensed water rotates the rotary drum of the wind turbine generator at a high discharge speed at the discharge port 19.

 (Figure 3) by rotating the rotary drum (45) of the wind power generator (60) by injection of high-pressure air supplied by a pressurizing pump (not shown)

  Thus, for a detailed description of the invention,

A shielding film 29 for rotating an end portion of a rotating shaft 70 that penetrates the rotating space 66 and a rotating drum 45 fixed to the rotating shaft 70, 60).

As described above, the inlet 58 and the outlet 59 protruding from both sides of the rotary space 66 forming the wind turbine generator 60 are arranged such that the blowing direction of the wind blowing in the air is the season Or temperature. In the present invention, wind power generation is provided due to compatibility with north wind in winter or southeastern wind in summer.

  The structure of the discharge port 19 for discharging the high-pressure air supplied from the cold air pipe 38 is provided to reinforce the rotating force of the rotary drum 45 provided in the rotary space 66 of the wind power generator 60 This is an invention to reinforce the wind power generation force by the ejected pressurized air when the wind force is breeze.

A detailed description of the present invention for rapidly and effectively condensing water vapor generated by evaporation in the heating tube 32 of the water surface 11 for the purpose of the present invention will be described with reference to FIGS. 3 to 7 The water vapor evaporated between the condensation sections 54 in the water surface 11 is formed by the jacket 40 formed at an oblique angle and the blocking wall 29 closing the both ends of the jacket 40 So that the solar cell plate 20 is fixed to the jacket 40 in which the movement section 47 is formed. Here, the movement section 47 described above is an invention for enhancing the rapid movement of the steam and the formation of condensed water.

 Accordingly, the moving section 47 is sequentially formed in a multi-stage evaporation and pressurization section; And is provided with separate suction and pressurization pumps 61 and 63 and a control device 14 accordingly.

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  A second diaphragm 42 provided on the upper side of the first diaphragm 41 to provide a suction pump 61 to form a low pressure section 52,

  A pressurizing section 53 provided on the upper side of the second diaphragm 42 with a third diaphragm 43 provided at an end of the storage tank 22 below the discharge port 19, The pressurized air pressurized by the pressurizing pump 62 provided in the suction port 57 connected to the third partition plate 43 is sprayed onto the condensation section 54 with the spray stage 30 provided on the third partition plate 43 And the multi-step section is formed in the movement section 47. [

  The spray stage 30 provided in the third diaphragm 43 formed to jet out into the condensation section 54 continuously and repeatedly passes through the spray nozzle 36 through which the fine holes pass, To the spray number 39 of the cool air sprayed in the spray nozzle 36,

It is preferable that fine spray water sprayed from the spray booth 30 is condensed by blowing cool air supplied from a cooling device (not shown) in a cold air pipe 38 provided in the cold air blowing block 68 .

The water vapor evaporated in the heating pipe 32 provided in the water surface 11 is supplied to the discharge port 19 through the discharge port 19, (Hereinafter referred to as a " moving section 47 ") for collecting for the formation of condensed water, which will be described later.

 The structure of the barrier membrane 29 is integrally fixed to the jacket 40 which is inclined and projected obliquely while the sealed structure formed so as to be submerged in the water surface 11 as a lower section is formed by a heating tube 32, So that the steam can be guided to the movement section 47.

 The photovoltaic element 50 provided on the outer surface of the solar photovoltaic plate 20 described above replenishes the power used in the working line 10 due to sunlight.

  The cooled air ejected from the ejection table 16 provided at the lower side of the ejection port 19 is formed on the upper side of the induction plate 23 and formed by the condensation of the water vapor ejected from the ejection platform 30 Thereby allowing the condensate to flow into the storage tank 22 for storage.

  That is, with respect to the inner section of the jacket 40 fixed at the buoy 25 floating on the water surface 11 on both side edges described above, in order to reinforce the jacket 40 by the operation of the unillustrated exhaust duct, The present invention provides a state in which a shielding film 29 descending from the both end faces of the plate 20 is locked to the water surface 11 down to both sides of the heating tube 32. The jacket 40 ) Is sealed with the outside.

   A control unit 14 such as a condenser, a freezer and a heater is fixed to the worktable 10 for work on the water surface 11 by a frame 21 or the like, (10)

  A heating pipe 32 having a jet port 33 is provided below the water surface 11 on both sides of the working line 10 to evaporate the water on the water surface 11 by heated steam or the like, In order to reinforce the stability against the oscillation of the water surface 11 and the hermeticity of the jacket 40, both sides of the boiler 25 floating on the outer periphery of the steam jetting heating pipe 32 And a discharge port 19 is protruded from the center protruding portion 18 so as to protrude from the central portion of the condensing section 20 of the inner side of the jacket 40 54) is condensed and then discharged to the outside.

  The jacket 40 is provided integrally with the photovoltaic power generation plate 20. The jacket 40 has a shielding film 29 covering the opposite ends of the jacket 40 to form a low pressure section, .

The discharge port 19 is provided at a lower portion of the jacket 40 for discharging the air from the discharge port 19 of the protruding portion 18 so as to promote the condensation of water vapor having a high moisture content. (16) for spraying low-temperature cooling air to reinforce the formation of condensed water in the condensed water,

 And is provided to be stored in the storage tank 22 provided in the work line 10 by the guide plate 23 through which the formed water flows.

 In addition, the present invention is provided to reinforce the collecting force in the field use in the above-described condensate water collecting apparatus, wherein the water is evaporated by the heating of the heating tube 32 for generating steam in the submerged state on the water surface 11 The water vapor is moved upward while being moved up in the section in which the water vapor moves toward the discharge port 19 (hereinafter referred to as the moving section 47) so that the pressurized water vapor is injected into the condensation section 54 A spray nozzle 39 in which cooling air is mixed in a cool air pipe 38 connected to a cooler not shown in the drawings, a spray nozzle 39 in which water vapor is sprayed to the spray nozzle 30, A cold air blowing block 68 injected into the cold air blowing block 68 and a cold air bundle 15 provided with a blower 16 in the cold air blowing block 68 to reinforce the cohesive force.

 This is because the multi-step low pressure difference is formed in the moving section 47 to accelerate the evaporation of water and perform the injection with the pressurization in the condensation section 54; A booster stage 30 continuously and repeatedly provided in the third partition plate 43 so as to blow out the grains of water vapor flowing into the condensation section 54 in the moving section 47 and a plurality of And a cold air tube 38 connected between the atomizer 36 and the atomizer through a separate pressurizing pump 62 so that the air is blown out from the atomizer and the cold air tube into the condensation section 54 at the same time, As a zoom, a cold air jetting block 68 is caused to jet into the condensation section 54.

  The configuration of the steam pipe 36 connected to the pump 30 not shown and the cold air tube 38 connected to the pressure pump 62 (not shown) A cold air tube (38) provided in an alternating manner in a section between a plurality of spray nozzles (36) passing through the body, wherein high pressure air cooled between the water particles ejected from the spray nozzle (36) And a jet blower 16 connected to the cold air jetting block 68 through which the jetting force of the water particles is reinforced by a separate cooling device fixed to the upper side of the condensation section 54 is provided And the water vapor mixed in the cold air blowing block 68 is condensed into condensed water by the cooling air ejected from the cold air block 15.

  Therefore, the present invention is not limited to the above-described embodiments, and the detailed description based on the accompanying drawings is not intended to limit the scope of the present invention, as shown in FIGS. 3 to 7, (Not shown) is installed at the end of the heating pipe 32, and a shielding film 29 provided downward is provided at the end of the heating pipe 32 Thereby interrupting the range of water heated on the water surface 11 so as to reinforce the heating effect of the heating tube 32.

   Accordingly, when the water vapor generated from the water surface 11 is moved to the movement section 47, the following description will be given with reference to the attached drawings.

   The first and second diaphragms 41 and 42 and the low pressure section 52 and the pressure section 53 formed by the third diaphragm 43 formed in the moving section 47 where the steam moves move to the storage tank A jacket 40 for forming a movement section 47 suitable for the purpose of the present invention is formed on the inner side surface of the jacket 40 for forming the movement section 47 at both sides of the work line 10 provided with the operation section 22 40 on the inner side of the jacket 40 for forming the movement section 47 on the inner side thereof.

  In order to provide the evaporation section 51 by providing the first diaphragm 41 through which a plurality of suction ports 57 are continuously and repeatedly passed to the upper side of the installation section of the heating pipe 32,

  A suction pump 61 installed on a second diaphragm 42 provided on an upper section of the first diaphragm 41 and a second diaphragm 41 provided on the water surface 11 by a suction force of the suction pump 61, The low pressure section 52 and the evaporation section 51 are formed by the suction of the air in the space between the water surface 11 and the water surface 11 to enhance the steam evaporation force.

 Pressure section 52 so as to form a low-pressure section 52 between the first and second diaphragms 41 and 42 in order to maintain the low-pressure state with respect to the evaporation section 51, A first step of promoting the evaporation of water on the water surface 11 by the suction force of the suction pump 61 provided on the second diaphragm 42 so as to suck the first diaphragm 41 through the pipe;

  The structure of the second diaphragm 42 described above has a closed plate structure. When the pressure reducing section 52 is provided with a reduced pressure state, the pressure section 53, which will be described later, (62) so that the pressure section (53) is pressurized by suction by the pump in the pressure reduction section (52).

  In order to reinforce the spraying force of the water vapor sprayed to the condensation section 54 described above, the spray stage 30 is provided with the minute size sprayer 36 and the cool air passage 38, As an invention provided to further reinforce the pressure,

  A second diaphragm 42 which is hermetically sealed in an upper section of the first diaphragm 41 and a third diaphragm 43 which is provided in a separate third diaphragm 43 for providing a separate pressure section 53, In order to spray the spray water 39 from the spray nozzle 36, the spray nozzle 30 is provided to be continuously and repeatedly installed over the area of the third partition plate 43.

 The pressurizing pump 62 is installed in the pressurizing section 53 while passing through the closed second diaphragm 42 in order to supply steam in the pressurizing section 53 in the pressurizing section 52, So that the amount of water vapor generated in the pressure reduction section 52 is sucked up by acceleration.

Thereby elevating the evaporation force at the blast water surface 11 and strengthening the blast section 30 so as to be sprayed into the condensation section 54 in a state of being pressurized by the pressure section 53

 That is, it is preferable to provide the control device 14 provided with the pressurizing pump 62 or the like so that the amount of water vapor evaporating from the water surface is provided in a state more than the pressurized state for pressurization.

In addition, a device for providing water vapor in a reduced pressure state on the water surface so as to elevate the evaporation force on the water surface 11 is provided. A heating tube 32 in which an air outlet 33 is fixed so as to heat the water surface 11 in an inner section of the heating tube 32 and a water surface heated by the heating tube 30 and the water surface outside the blocking film 29 The water is generated appropriately by proper mixing with the external water surface by lowering the shutoff membrane appropriately so as to purify the water of the water surface caused by the water surface.

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A jet port 19 formed in the upper section of the condensation section 54 so that the jet number 39 of water vapor contained in the cold air jetting block 68 sprayed into the condensation section 54 is condensed, The steam particles contained in the cold air blowing block 68 can be discharged to the condensed water more quickly by the cooling air injected from the cold air table 15 provided with the spray table 16 connected by a pressurizing pump It is an invention to provide.
As shown in FIG. 3, in the embodiment of the present invention, as shown in FIG. 3, the blowing port 19, which is a substantial part of the present invention described above, And the jetting port 19 is fixed in a curved state so as to be fixed to the lower side of the rotary space 66 of the wind turbine generator 60 provided for the condensation section 54, And the rotation drum (45) built in the rotary space (66) is rotated by the discharge output of the high pressure air to be sprayed.
That is, the high-pressure air blown out from the cooling air duct 38 provided in the condensation section 54 and the jetting table 16 on the discharge port 19 provided above the condensation section 54, It is preferable to provide the wind turbine generator 60 with power to rotate the wind turbine generator 45.

10. Work line 11. Sleep 14. Control device
16. Spout 18. Projection 19. Outlet
20. Solar power plate 21. Frame 22. Storage tank
25. Announcement 29. Barrier 30. Minute stage
31. Minute publication 32. Heating pipe 33. Air outlet 34. Support rod
35. Blocking wall 36. Split nozzle 38. Cooling tube 39. Spray water
40. jacket 41. first diaphragm 42. second diaphragm 43. third diaphragm
45. Rotating drum 49. Outer wall 47. Moving section
51. Evaporation section 52. Low pressure section 53. High pressure section 54. Condensation section
56: Support wall 57. Suction port 58. Inlet 59. Outlet
60. Wind power generator 61. Suction pump 62. Pressure pump
66. Rotation space 68. Cold wind ejection block

Claims (2)

A book 25 fixed to the end of the frame 21 protruding to both sides of the working line 10 provided with the storage tank 22 protruded by the guide plate 23 and the control device 14, Wow; A heating pipe 32 having a jet port 33 supported by a fixing table 45 on a water surface 11 which is a section between the working line 10 and the load unit 25,
A jacket 40 provided with a photovoltaic power generation plate 20 protruding in a curved shape at the one side of the loader 25 and an induction plate 46 projecting obliquely from the other side of the load 25;
A movement section 47 formed by a shielding film 29 for providing an inner section at both ends of the jacket 40 and the induction plate 46,
A discharge port 19 provided in the interval between the jacket 40 and the upper end of the induction plate 46; a wind power generator 60 provided in the discharge port 19; A cool air bag 15 provided with a jet table 16 connected by a shown pressurizing pump, In a condensate water collecting apparatus provided with a long oil guide plate (65) for guiding a condensate protruding from an end of a storage tank (22)
A support wall 56 fixed to the outside of the ends of the guide plate 46 and the jacket 40 provided on both sides of the discharge port 19 and a support wall 56 fixed to the upper end of the support wall 56 A rotary space 66 which is formed with an inlet 58 and an outlet 59 of the wind power and is linked to the upper side of the discharge port 19,
A condensation section 54 formed with a wind turbine 60 formed of a rotary drum for extruding a rotary drum 45 to a rotary shaft 70 passing through the rotary space 66,
A control device 14 provided with a pressure and suction pump 61 (62) for dividing the moving section 47 into a plurality of stages;
A first diaphragm 41 passing through the suction port 57 so as to have an upper evaporation section 51 and a lower pressure section 52 of the heating tube 32,
A second diaphragm 42 provided with a suction pump 61 so as to form a low-pressure section 52 on the upper side of the first diaphragm 41,
A pressurizing pump 62 provided in a pressurizing section 53 formed by a third diaphragm 43 provided on the upper side of the second diaphragm 42 at the end of the storage tank 22 and below the discharge port 19, The spray water 39 sprayed into the condensation section 54 in the spray hole 36 of the fine hole passing through the spray stage 30 provided through the third partition plate 43 is sprayed to the cooler A cold air jetting block 68 sprayed in the form of cooling air sprayed from a cooling air pipe 38 connected to the cooling air duct 38 is provided so as to be accelerated in the cold air of the cool air bag 15 equipped with the jet table 16, . The method according to claim 1,
The rotary drum 45 of the rotary space 66 which is rotated by the high pressure air jetted from the cold air tube 38 of the cold air blowing block 68 to generate electric power is supplied to the discharge port 19 of the condensation section 54,
The evaporation section 51 and the low pressure section 52 of the first reduced pressure state and the low pressure section 52 of the first diaphragm 42 are provided in the section between the heating pipe 32 and the moving section 47 for condensing water vapor, (30) for spraying the steam that has been pressurized by the pressurizing pump (62) in the pressurizing section (53), and a spraying section The cooling air blown out from the cooling air bobbin 15 is blown into the cold air blowing block 68 formed by mixing the spray water 39 of the water vapor and the pressurized air blown out from the cooling air pipe 38 supplied from the separate pressurizing device, Wherein water vapor of the spray water (39) sprayed from the spray booth (30) is condensed to form condensation water.

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