CN112049188A

CN112049188A - Air power water generator

Info

Publication number: CN112049188A
Application number: CN202010766004.6A
Authority: CN
Inventors: 张莉
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-08-03
Filing date: 2020-08-03
Publication date: 2020-12-08
Anticipated expiration: 2040-08-03
Also published as: CN112049188B

Abstract

The invention relates to an aerodynamic water generator which comprises an upper mounting plate, a support column, a filter, a connecting pipe, a communicating pipe, a valve, a funnel, a filter plate, a distillation tank, a water level detector, a heating module, a wind driven generator, a side support, a timer, a rotating speed detector, a collecting tank, a distillation plate, a support column and a control module. The rainwater in nature is received, and the rainwater is distilled in a wind power generation mode, so that the efficient utilization of natural resources is realized; meanwhile, the control module is provided with the preset region plan matrix A, the corresponding region plan Ai is selected according to the wind speed and the average rainfall of the region where the equipment is located, the control module can adjust the preset operation parameters of each part according to the Ai plan, the fact that the resources utilized by each part just can finish distillation of the specified amount of rainwater during operation is guaranteed, the situations of surplus resources or insufficient resources cannot occur, and therefore the water generator can efficiently prepare distilled water for different environments.

Description

Air power water generator

Technical Field

The invention relates to the technical field of distilled water preparation, in particular to an aerodynamic water generator.

Background

The distilled water refers to water subjected to distillation and condensation operations, wherein twice distilled water is called redistilled water, and three times distilled water is called triple-distilled water. The water with low oxygen consumption is obtained by adding potassium permanganate and acid industrial distilled water by a distilled water method.

The traditional distilled water is produced by adopting electric power and burning energy generated by other substances to generate heat energy, so that the water is distilled, the energy loss is increased, and the environment is polluted.

In the prior art, distilled water can be prepared by using natural energy, however, for most of the existing apparatuses, the apparatuses can only prepare distilled water under a single environment, and when the environment changes, the apparatus cannot effectively cope with the changed environment, thereby causing the loss of natural resources, and meanwhile, due to the change of the environment, in the process of preparing distilled water by the apparatuses, the loss of distilled water due to the influence of the environment in the processes of preparation and transportation is easily caused, thereby not ensuring the efficient preparation of distilled water.

Disclosure of Invention

Therefore, the invention provides an aerodynamic water generator which is used for overcoming the problem that the prior art cannot adapt to different environments.

In order to achieve the above object, the present invention provides an aerodynamic water generator, comprising:

the four corners of the upper mounting plate are respectively provided with a support column, and the surface of the upper mounting plate is provided with a through hole;

the filter is arranged in the through hole of the upper mounting plate, one end of the filter is provided with a connecting pipe, the other end of the filter is provided with a communicating pipe, and a valve is arranged at the joint of the filter and the communicating pipe and used for controlling the opening and closing of the communicating pipe;

the funnel is connected with the connecting pipe and used for receiving rainwater, and a filter plate is arranged on the funnel and used for filtering insoluble particles in the rainwater;

the distillation tank is arranged on one side of the upper mounting plate and used for receiving rainwater, a water inlet is formed in the side wall of the distillation tank, the filtered rainwater is conveyed into the distillation tank through the water inlet by the communicating pipe, and a water level detector is arranged in the distillation tank and used for detecting the water level in the distillation tank in real time;

the heating module is arranged on the bottom surface of the distillation tank and used for heating rainwater in the distillation tank, the heating module can store a specified amount of electric power, and after the specified electric power is stored in the heating module, the heating module starts to heat the rainwater in the distillation tank;

the wind driven generator is connected with the heating module through a connecting circuit and used for converting wind energy into electric energy, a side bracket is further arranged on the wind driven generator and connected with the other side wall of the distillation tank and used for fixing the wind driven generator at a specified position, and a timer and a rotating speed detector are further arranged in the wind driven generator and used for respectively detecting the rotating time and the rotating speed of fan blades of the wind driven generator;

the collecting tank is arranged on one side of the distillation tank and is used for collecting condensed water;

the distillation plate is arranged above the distillation tank and the collection tank, is connected with the distillation tank through a support column, and is used for condensing water vapor of the distillation tank and conveying the condensed water to the collection tank;

and the control module is respectively connected with the valve, the water level detector, the heating module, the timer and the rotating speed detector, a preset region plan matrix A (A1, A2, A3 and A4) is arranged in the control module, wherein A1 is a first region plan for low rainfall and low wind speed, A2 is a second region plan for high rainfall and low wind speed, A3 is a third region plan for low rainfall and high wind speed, A4 is a fourth region plan for high rainfall and high wind speed, when the water generator is placed, a corresponding plan Ai is selected from the preset region plan matrix A according to the region where the water generator is located, wherein i is 1, 2, 3 and 4, and the control module can adjust the operating parameters of each component according to the selected region plan Ai.

Furthermore, a preset water level matrix H0(H1, H2, H3 and H4) is also arranged in the control module; the method comprises the following steps that H1 is a first preset water level of a distillation tank when a control module selects an A1 plan, H2 is a second preset water level of the distillation tank when a control module selects an A2 plan, H3 is a third preset water level of the distillation tank when a control module selects an A3 plan, and H4 is a fourth preset water level of the distillation tank when a control module selects an A4 plan;

after control module selects region plan Ai, control module is Hi with the predetermined water level regulation in the retort, works as when the filter carries the rainwater through communicating pipe to the retort, water level detector can real-time detection rainwater water level H in the retort and carry water level information to control module, and control module compares H and Hi:

when H is less than Hi, the control module controls the valve to be opened so that the filter continuously conveys rainwater to the distillation tank;

when H ═ Hi, the control module controls the valve to close.

Further, a preset energy storage matrix C0(C1, C2, C3, C4) is further arranged in the control module, wherein C1 is a first preset electric energy storage amount of the heating module when the control module selects the a1 plan, C2 is a second preset electric energy storage amount of the heating module when the control module selects the a2 plan, C3 is a third preset electric energy storage amount of the heating module when the control module selects the A3 plan, and C4 is a fourth preset electric energy storage amount of the heating module when the control module selects the a4 plan;

when the control module determines the plan Ai, the control module selects a specified electric energy storage quantity Ci from a preset energy storage matrix C0 as a preset electric energy storage quantity of the heating module; when wind blows during aerogenerator, the rotational speed v of rotational speed detector meeting real-time detection flabellum, the rotation time t of time-recorder meeting real-time detection flabellum, time-recorder and rotational speed detector can carry detection data to control module in real time when detecting, and control module calculates the electric energy C that this time flabellum transmission produced according to rotational speed v and rotation time t, and well accuse module can compare C and preset electric energy Ci:

when C is larger than Ci, the control module controls the heating module to start to heat the rainwater, and meanwhile, the redundant electric energy C is calculated according to C and Ci, recorded and stored until the next heating; when the control module selects Ci and the heating module also stores the reserved electric energy c, the control module corrects the electric energy Ci required by the heating module according to Ci and c;

when C is Ci, the control module controls the heating module to start to heat the rainwater;

when C is less than Ci, the control module calculates the residual required electric energy Ci1 of the heating module according to C and Ci, and corrects the electric energy Ci required by the heating module to be Ci 1; when the wind driven generator generates the electric energy C again, the control module compares the C ' with the Ci1, if the C ' is less than the Ci1, Ci1 is corrected to be Ci2 according to the residual required electric energy, and the control module continuously corrects the internal energy Cin required by the heating module until the electric energy C ' n generated by the wind driven generator is equal to Cin.

Further, a preset rotation speed matrix V0(V1, V2, V3, V4) is further arranged in the rotation speed detector, wherein V1 is a first preset rotation speed of the fan blade of the wind driven generator when the control module selects an a1 plan, V2 is a second preset rotation speed of the fan blade of the wind driven generator when the control module selects an a2 plan, V3 is a third preset rotation speed of the fan blade of the wind driven generator when the control module selects an A3 plan, and V4 is a fourth preset rotation speed of the fan blade of the wind driven generator when the control module selects an a4 plan;

when the control module selects the region plan Ai, the control module selects a corresponding preset rotating speed Vi from a preset rotating speed matrix V0; when electric energy C in the heating module stores to appointed value Ci, the rotational speed detector can detect the rotational speed of flabellum in real time and carry the detected value to control module, and control module can compare rotational speed V with predetermineeing rotational speed Vi:

when V is less than Vi, the control module controls the heating module to start to heat the rainwater;

when V is larger than or equal to Vi, the control module does not start the heating module.

Further, a distilled water level preset matrix h (h1, h2, h3 and h4) is further arranged in the water level controller, wherein h1 is a first distilled preset water level of the distillation tank when the control module selects an A1 plan, h2 is a second distilled preset water level of the distillation tank when the control module selects an A2 plan, h3 is a third distilled preset water level of the distillation tank when the control module selects an A3 plan, and h4 is a fourth distilled preset water level of the distillation tank when the control module selects an A4 plan;

when the control module selects the region plan Ai, the control module selects the corresponding distillation preset water level hi from the distillation water level preset matrix h; when heating module heats the rainwater in the retort, water level detector can real-time detection retort in rainwater water level h and will detect data and carry to control module, control module can compare h and hi:

when h is larger than hi, the control module controls the heating module to continue heating the rainwater in the distillation tank;

and when h is less than or equal to hi, the control module controls the heating module to stop heating and controls the valve to be opened so that the filter sends water to the distillation tank.

Further, the distillation plate comprises:

the main body is obliquely arranged above the distillation retort and is used for receiving the water vapor output by the distillation retort and condensing the water vapor into distilled water;

the guide plate is obliquely arranged on the end face of the main body, and a guide groove is formed in the inner surface of the guide plate and used for guiding the distilled water to the collecting tank.

Further, a plurality of through holes are formed in the surface of the filter plate, so that rainwater can enter the funnel.

Furthermore, the through holes are uniformly formed in the surface of the filter plate.

Further, the stilling plate is arranged on the pillar in a bayonet manner.

Further, the surface of the distillation plate is subjected to sterilization and disinfection treatment.

Compared with the prior art, the invention has the beneficial effects that the rainwater in nature is received, the wind driven generator is connected with the heating module through the connecting circuit, and the rainwater is distilled in a wind power generation mode to prepare distilled water, so that the efficient utilization of natural resources is realized; meanwhile, the control module is provided with the preset region plan matrix A (A1, A2, A3 and A4), the corresponding region plan Ai is selected according to the wind speed and the average rainfall of the region where the equipment is located, the control module can adjust the preset operation parameters of each part according to the Ai plan, the resources utilized by each part in the operation process can be guaranteed to just finish the distillation of the specified amount of rainwater, the condition of redundant resources or insufficient resources can not occur, and therefore the water generator can efficiently prepare distilled water for different environments.

Furthermore, a preset water level matrix H0(H1, H2, H3 and H4) is further arranged in the control module, the control module can select Hi as the preset water level of the distillation retort after selecting the Ai plan, the total amount of the prepared distilled water is determined by adjusting the preset water level, and the control module can select the corresponding single-distillation rainfall amount according to the average rainfall amount of the region where the control module is located, so that the problem that the rainwater is excessively accumulated or the rainwater to be distilled is insufficient in the distillation process of the equipment is effectively prevented, and the applicability of the water generator to different environments is further improved.

Particularly, a valve is further arranged between the filter and the communicating pipe, the control module is used for detecting the rainwater amount in the distillation tank in real time and controlling the valve to be opened and closed according to a detection value, the total amount of the rainwater to be evaporated can be accurately controlled, and the wind power resource collected by the wind driven generator can be used for distilling the rainwater to be distilled in a specified amount, so that the utilization rate of the water generator to natural resources is improved.

Furthermore, a preset energy storage matrix C0(C1, C2, C3 and C4) is further arranged in the control module, the control module selects corresponding preset electric energy Ci according to the selected plan Ai, and the heating module stores the specified electric energy to heat the specified amount of rainwater according to different environments, so that the resource utilization rate of the water generator is further improved.

Further, still be equipped with in the rotational speed detector and preset rotational speed matrix V0(V1, V2, V3, V4), control module can judge the wind speed in the environment of locating through the flabellum rotational speed to according to the opening and shutting of wind speed control heating module, through monitoring the wind speed with the opening and shutting of control heating module, can prevent in the heating process that strong wind blows off the distilled water loss that leads to with steam, improved the system water efficiency of system water machine.

Furthermore, still be equipped with the distillation water level in the water level controller and predetermine matrix h (h1, h2, h3, h4), when water level h is less than predetermineeing water level hi in the retort, control module can control the heating module and stop the heating so as to prevent that the water yield is too little in the retort and consequently lead to the heating module to cause the damage to the retort, improved the life of system water machine.

Furthermore, the distillation plate is also provided with a guide plate provided with a guide groove, and the condensed distilled water is guided to flow in order to finish the directional delivery of the distilled water, so that the distilled water preparation efficiency of the water making machine is further improved.

Furthermore, a plurality of through holes are uniformly formed in the surface of the filter plate, when the water maker receives rainwater, the through holes can filter the rainwater and insoluble particulate matters in the environment, so that sundries except the rainwater are prevented from entering the filter to cause the blockage of the communicating pipe or damage to the distillation retort, and the service life of the water maker is further prolonged.

Further, the surface of the distillation plate is subjected to sterilization and disinfection treatment, so that bacteria can be effectively prevented from entering condensed water when water vapor is condensed, and the preparation efficiency of the water generator on distilled water is further improved.

Drawings

Fig. 1 is a schematic structural view of an aerodynamic water generator according to the present invention;

FIG. 2 is a front view of the aerodynamic water generator of the present invention;

FIG. 3 is a schematic diagram of the structure of the distillation plate according to the present invention.

Detailed Description

In order that the objects and advantages of the invention will be more clearly understood, the invention is further described below with reference to examples; it should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

Preferred embodiments of the present invention are described below with reference to the accompanying drawings. It should be understood by those skilled in the art that these embodiments are only for explaining the technical principle of the present invention, and do not limit the scope of the present invention.

It should be noted that in the description of the present invention, the terms of direction or positional relationship indicated by the terms "upper", "lower", "left", "right", "inner", "outer", etc. are based on the directions or positional relationships shown in the drawings, which are only for convenience of description, and do not indicate or imply that the device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention.

Furthermore, it should be noted that, in the description of the present invention, unless otherwise explicitly specified or limited, the terms "mounted," "connected," and "connected" are to be construed broadly, and may be, for example, fixedly connected, detachably connected, or integrally connected; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood by those skilled in the art according to specific situations.

Please refer to fig. 1 and fig. 2, which are a schematic structural view and a front view of the aerodynamic water generator according to the present invention, respectively. The aerodynamic water generator comprises a funnel 2, a filter 4, an upper mounting plate 5, a distillation plate 8, a wind driven generator 10, a distillation tank 11, a collection tank 12, a heating module 13 and a control module (not shown in the figure). Wherein the filter 4 is disposed on the upper mounting plate 5 for filtering rainwater. The funnel 2 is connected to a filter 4 for collecting rainwater. The distillation plate 8 is obliquely arranged on the distillation tank 11 and is used for condensing water vapor output by the distillation tank 11. The wind power generator 10 is arranged on the side wall of the distillation tank 11 and is used for converting wind energy into electric energy. The distillation retort 11 is arranged on one side of the upper mounting plate 5 and is connected with the filter to receive rainwater output by the filter. The collecting tank 12 is arranged on one side of the distillation tank 11 and is used for collecting the condensed water output by the distillation plate 8. The heating module 13 is arranged at the bottom of the distillation retort 11 and connected with the wind driven generator 10, and is used for receiving electric energy output by the wind driven generator 10 to heat the distillation retort. The control modules are respectively connected with the designated components and used for receiving and adjusting the operating parameters of the corresponding components.

When the system water machine is operated, the funnel 2 can receive rainwater and convey the rainwater to the filter 4, and the filter 4 conveys the rainwater to the distillation retort 11 after filtering the rainwater. The fan blades on the wind driven generator 10 rotate when wind blows, kinetic energy is converted into electric energy and the electric energy is transmitted to the heating module 13, and the heating module 13 stores the designated electric energy and then heats rainwater in the distillation tank 11. Rainwater in the distillation tank 11 is heated and evaporated to form water vapor, the water vapor rises to be in contact with the distillation plate 8, the water vapor is condensed after being attached to the distillation plate 8, and the distillation plate 8 drains condensed water condensed on the surface of the distillation plate to the collection tank 12 to finish the preparation of distilled water.

Particularly, funnel 2 upper end mouth department is equipped with filter 1, has evenly seted up a plurality of through-holes on filter 1 surface for the insoluble particulate matter of filtering rainwater. When the funnel 2 collects rainwater, the rainwater enters the funnel through the through holes, and insoluble particulate matters in the rainwater and insoluble particulate matters in the environment where the water making machine is located are filtered out of the filter plate 1. It should be understood that the number of the through holes formed in the filter plate 1 is not particularly limited in this embodiment, as long as the filter plate 1 can filter out insoluble particulate matters.

Specifically, the upper end of the filter 4 is provided with a connecting pipe 3, and the connecting pipe 3 is connected with the funnel 2 for conveying rainwater. A communicating pipe 7 is arranged at the lower end of the filter 4, and the other end of the communicating pipe 7 is connected with the distillation retort 11 and used for conveying the rainwater filtered by the filter 4 to the distillation retort 11. A valve (not shown in the figure) is arranged at the joint of the filter 4 and the communicating pipe 7, and the valve is connected with the control module and used for controlling the opening and closing of the communicating pipe 7. When the control module controls the valve to be opened, the funnel 2 receives rainwater and conveys the rainwater to the filter 4 through the connecting pipe 3, and the filter 4 conveys the filtered rainwater to the distillation tank 11 through the communicating pipe 7 after filtering the rainwater; when the control module controls the valve to close, rainwater is stored in the filter 4. It is understood that the kind of the valve is not particularly limited in this embodiment as long as the valve is satisfied that rainwater cannot enter the distillation tank 11 through the connection pipe 7 when it is closed.

Specifically, the surface of the upper mounting plate 5 is provided with a through hole for loading the filter 4; support columns 6 are respectively arranged at four corners of the bottom surface of the upper mounting plate 5 and used for fixing the filter 4 at a specified height together with the upper mounting plate 5. It is understood that the connection mode of the upper mounting plate 5 and each supporting column 6 is not particularly limited in this embodiment, as long as the supporting column 6 and the upper mounting plate 5 can fix the filter 4 at a specified position.

Specifically, the bottom of the wind driven generator 10 is provided with a side bracket 15, and the side bracket 15 is arranged on the side wall of the distillation tank 11 to fix the wind driven generator 10 at a specified position. The wind driven generator 10 is externally connected with a connecting circuit 14, and the other end of the connecting circuit 14 is connected with the book searching heating module 13 to transmit the electric energy generated by the wind driven generator 10 to the heating module 13. The upper end of the wind driven generator 10 is provided with a fan blade, and a rotation speed detector (not shown in the figure) connected with the control module is arranged in the fan blade and used for detecting the rotation speed of the fan blade and transmitting the rotation speed value to the control module. A timer (not shown) connected to the control module is further disposed inside the wind turbine 10 for recording the rotation time of the fan blades and transmitting the recorded time to the control module. When wind blows over the wind generator 10, the blades rotate, converting kinetic energy into electrical energy and delivering the electrical energy to the heating module 13 via the connection lines. When the flabellum rotates, the rotational speed detector can detect the rotational speed of flabellum in real time and carry the rotational speed value to control module, and the time-recorder can record the rotation time of flabellum and carry the time of record to control module.

Particularly, retort 11 sets up go up one side of mounting panel 5, can be equipped with the inlet opening at 11 lateral walls of retort, the one end setting of communicating pipe 7 is in inlet opening department, is equipped with pillar 9 at 11 up end of retort, for with distillation plate 8 links to each other, be equipped with at 11 inner walls of retort with the water level detector (not drawn in the picture) that control module links to each other for detect the water level in the retort 11 and carry the detected value to control module. When the distillation tank 11 receives rainwater, the water level detector can detect the water level in the distillation tank 11 in real time and transmit a detection value to the control module, and when the water level reaches a specified value, the control module controls the valve to be closed and controls the heating module 13 to be started when the electric energy stored in the heating module 13 reaches the specified value. When the heating module heats the rainwater, the water level detector can detect the water level in the distillation retort 11 in real time, and when the water level channel reaches a specified value, the control module controls the heating module 13 to stop heating.

Specifically, the heating module 13 is arranged at the bottom of the distillation tank 11 and connected with the connection line 14 to receive the electric energy output by the wind driven generator 10; the heating module 13 is also connected with the control module for the control module to detect the electric energy storage amount in the heating module in real time. When the water maker operates, the wind driven generator 10 transmits electric energy to the heating module 13 through the connecting line 14, the control module can detect the electric energy storage amount in the heating module 13 in real time, and when the electric energy storage amount in the heating module 13 reaches a specified value and a specified amount of rainwater is stored in the distillation retort 11, the control module controls the heating module to start.

As shown in fig. 1 and fig. 2, the control module of the present invention is connected to the valve, the water level detector, the heating module 13, the timer and the rotation speed detector, and a preset regional plan matrix a (a1, a2, A3, a4) is disposed in the control module, where a1 is a first regional plan for low rainfall and low wind speed, a2 is a second regional plan for high rainfall and low wind speed, A3 is a third regional plan for low rainfall and high wind speed, a4 is a fourth regional plan for high rainfall and high wind speed, and when the water generator is completely placed, a corresponding plan Ai is selected from the preset regional plan matrix a according to a region where the water generator is located, where i is 1, 2, 3, 4, and the control module adjusts operation parameters of each component according to the selected regional plan Ai.

Specifically, a preset water level matrix H0(H1, H2, H3, H4) is arranged in the control module; the distillation tank comprises a distillation tank body, a control module, a H1, a H3 and a H4, wherein the H1 is a first preset water level of the distillation tank body when the A1 plan is selected for the control module, the H2 is a second preset water level of the distillation tank body when the A2 plan is selected for the control module, the H3 is a third preset water level of the distillation tank body when the A3 plan is selected for the control module, and the H4 is a fourth preset water level of the distillation tank body when the A4 plan is selected for the control module.

After control module selects region plan Ai, control module is Hi with the predetermined water level regulation in retort 11, works as when filter 4 carries the rainwater to retort 11 through communicating pipe 7, water level detector can real-time detection retort 11 interior rainwater water level H and carry water level information to control module, and control module compares H and Hi:

when H is less than Hi, the control module controls the valve to be opened so that the filter 4 continuously conveys rainwater to the distillation tank 11;

when H ═ Hi, the control module controls the valve to close.

Specifically, a preset energy storage matrix C0(C1, C2, C3, C4) is further arranged in the control module, wherein C1 is a first preset electric energy storage amount of the heating module 13 when the control module selects an a1 plan, C2 is a second preset electric energy storage amount of the heating module 13 when the control module selects an a2 plan, C3 is a third preset electric energy storage amount of the heating module 13 when the control module selects an A3 plan, and C4 is a fourth preset electric energy storage amount of the heating module 13 when the control module selects an a4 plan.

When the control module determines the predetermined pattern Ai, the control module further selects a specified electric energy storage quantity Ci from the preset energy storage matrix C0 as a preset electric energy storage quantity of the heating module 13; when wind blows during aerogenerator 10, the rotational speed v of rotational speed detector meeting real-time detection flabellum, the rotation time t of time-recorder meeting real-time detection flabellum, time-recorder and rotational speed detector can carry detection data to control module in real time when detecting, and control module calculates this time the electric energy C that the flabellum transmission produced and compares C and predetermine electric energy Ci according to rotational speed v and rotation time t:

when C is larger than Ci, the control module controls the heating module 13 to be started to heat the rainwater, meanwhile, the redundant electric energy C is calculated according to C and Ci, and the redundant electric energy C is recorded and stored until the next heating; when the control module selects Ci and the heating module 13 also stores the reserved electric energy c, the control module corrects the electric energy Ci required by the heating module 13 according to Ci and c;

when C is Ci, the control module controls the heating module 13 to start to heat the rainwater;

when C is less than Ci, the control module calculates the residual required electric energy Ci1 of the heating module according to C and Ci, and corrects the electric energy Ci required by the heating module 13 to be Ci 1; when the wind driven generator 10 generates the electric energy C again, the control module compares C ' with Ci1, and corrects Ci1 to Ci2 according to the remaining required electric energy when C ' < Ci1, and the control module continuously corrects the internal energy Cin required by the heating module until the electric energy C ' n generated by the wind driven generator 10 is equal to Cin.

Specifically, a preset rotation speed matrix V0(V1, V2, V3, V4) is further arranged in the rotation speed detector, wherein V1 is a first preset rotation speed of blades of the wind driven generator 10 when an a1 plan is selected for the control module, V2 is a second preset rotation speed of blades of the wind driven generator 10 when an a2 plan is selected for the control module, V3 is a third preset rotation speed of blades of the wind driven generator 10 when an A3 plan is selected for the control module, and V4 is a fourth preset rotation speed of blades of the wind driven generator 10 when an a4 plan is selected for the control module;

when the control module selects the region plan Ai, the control module selects a corresponding preset rotating speed Vi from a preset rotating speed matrix V0; when electric energy C in the heating module 13 is stored to appointed value Ci, the rotational speed detector can detect the rotational speed of flabellum in real time and convey the detected value to the control module, and the control module can compare rotational speed V with preset rotational speed Vi:

when V is less than Vi, the control module controls the heating module 13 to be started to heat the rainwater;

when V is larger than or equal to Vi, the control module does not start the heating module 13.

Specifically, a distilled water level preset matrix h (h1, h2, h3 and h4) is further arranged in the water level controller, wherein h1 is a first distilled preset water level of the distillation tank 11 when the control module selects the A1 scheme, h2 is a second distilled preset water level of the distillation tank 11 when the control module selects the A2 scheme, h3 is a third distilled preset water level of the distillation tank 11 when the control module selects the A3 scheme, and h4 is a fourth distilled preset water level of the distillation tank 11 when the control module selects the A4 scheme;

when the control module selects the region plan Ai, the control module selects the corresponding distillation preset water level hi from the distillation water level preset matrix h; when heating module 13 heats the rainwater in to retort 11, rainwater water level h in water level detector can real-time detection retort 11 and will detect data and carry to control module, control module can compare h and hi:

when h is larger than hi, the control module controls the heating module 13 to continue heating the rainwater in the distillation tank 11;

and when h is less than or equal to hi, the control module controls the heating module 13 to stop heating and controls the valve to be opened so that the filter 4 sends water into the distillation tank 11.

Please refer to fig. 3, which is a schematic structural diagram of a distillation plate according to the present invention. The distillation plate 8 of the present invention includes a main body 801 and a guide plate 802. Wherein the main body 801 is connected with the support 9 in a snap-fit manner to fix the distillation plate 8 at a designated position, and the guide plate 802 is obliquely arranged at the end of the main body 801 to output condensed water into the collection tank 12. When the water generator operates, water in the distillation tank 11 is heated and evaporated to form water vapor, the water vapor rises and adheres to the main body 801, the water vapor is condensed on the main body 801 to form liquid drops, the liquid drops slide to the guide plate 802 along the main body 801 under the action of gravity, and the liquid drops are output to the collection tank 12 under the drainage of the guide plate 802.

Specifically, the surface of the guide plate 802 is provided with a guide groove 803 for confining the liquid droplets. When the liquid droplets flow to the guide plate 802, the liquid droplets enter the guide groove 803 and are output to the collection tank 12 under the restriction of the guide groove.

Specifically, the surface of the distillation plate is sterilized and disinfected to prevent condensed liquid drops from being contaminated with bacteria.

So far, the technical solutions of the present invention have been described in connection with the preferred embodiments shown in the drawings, but it is easily understood by those skilled in the art that the scope of the present invention is obviously not limited to these specific embodiments. Equivalent changes or substitutions of related technical features can be made by those skilled in the art without departing from the principle of the invention, and the technical scheme after the changes or substitutions can fall into the protection scope of the invention.

The above description is only a preferred embodiment of the present invention and is not intended to limit the present invention; various modifications and alterations to this invention will become apparent to those skilled in the art. Any modification, equivalent replacement, or improvement made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims

1. An aerodynamic water generator, comprising:

2. The aerodynamic water generator of claim 1, wherein a preset water level matrix H0(H1, H2, H3, H4) is further provided within the control module; the method comprises the following steps that H1 is a first preset water level of a distillation tank when a control module selects an A1 plan, H2 is a second preset water level of the distillation tank when a control module selects an A2 plan, H3 is a third preset water level of the distillation tank when a control module selects an A3 plan, and H4 is a fourth preset water level of the distillation tank when a control module selects an A4 plan;

when H ═ Hi, the control module controls the valve to close.

3. The aerodynamic water generator of claim 1, wherein a preset energy storage matrix C0(C1, C2, C3, C4) is further provided in the control module, wherein C1 is a first preset amount of electric energy stored in the heating module when the a1 schedule is selected for the control module, C2 is a second preset amount of electric energy stored in the heating module when the a2 schedule is selected for the control module, C3 is a third preset amount of electric energy stored in the heating module when the A3 schedule is selected for the control module, and C4 is a fourth preset amount of electric energy stored in the heating module when the a4 schedule is selected for the control module;

4. The aerodynamic water generator of claim 3, wherein a preset rotation speed matrix V0(V1, V2, V3, V4) is further provided in the rotation speed detector, wherein V1 is a first preset rotation speed of the blades of the wind driven generator when the a1 schedule is selected for the control module, V2 is a second preset rotation speed of the blades of the wind driven generator when the a2 schedule is selected for the control module, V3 is a third preset rotation speed of the blades of the wind driven generator when the A3 schedule is selected for the control module, and V4 is a fourth preset rotation speed of the blades of the wind driven generator when the a4 schedule is selected for the control module;

5. The aerodynamic water generator as claimed in claim 4, wherein a distilled water level preset matrix h (h1, h2, h3, h4) is further provided in the water level controller, wherein h1 is a first distilled preset water level of the distillation tank when the control module selects the A1 scheme, h2 is a second distilled preset water level of the distillation tank when the control module selects the A2 scheme, h3 is a third distilled preset water level of the distillation tank when the control module selects the A3 scheme, and h4 is a fourth distilled preset water level of the distillation tank when the control module selects the A4 scheme;

6. The aerodynamic water generator of claim 1, wherein the distillation panel comprises:

7. The aerodynamic water generator of claim 1, wherein the filter panel has a plurality of apertures formed in a surface thereof to allow rain water to enter the funnel.

8. The aerodynamic water generator of claim 7, wherein each of the through holes opens uniformly in the surface of the filter plate.

9. The aerodynamic water generator of claim 1, wherein the distillation plate is arranged on the struts in a bayonet manner.

10. The aerodynamic water generator of claim 9, wherein the distillation plate surface is sterilized and disinfected.