CN103570088A - System device for preparation of fresh water and salt by all-weather seawater self-pumping power generation for heating and condensation - Google Patents

Abstract

The invention discloses a system device for preparation of fresh water and salt by all-weather seawater self-pumping power generation for heating and condensation; according to the system device, a dual-use waterwheel pulse pump can improve the water level to more than one hundred meters by use of single set or multiple sets of flowing water-pushed series-connected pumps, the dual-use waterwheel pulse pump is actually an unpowered water pump for providing water used for farmland of a no-power region, or for a shaft-type hydroelectric generator for all-weather power generation and for all-weather seawater desalting for preparation of the fresh water and the salt; When seawater flows past a gravity evaporation condensation vacuum pump, the seawater can be instantaneously evaporated or condensed, salt particles in seawater desalination steam can be collected by self-gravity descending, high temperature steam and a low temperature vapor phase collide to condense into the fresh water to flow out, and the fresh water flows past a connected water purifier and an ozone sterilizer to produce safe drinking water, the seawater can be instantaneously evaporated or condensed into the fresh water without any electric energy, seawater desalination equipment is simple in manufacturing, low in cost, high in seawater desalination efficiency and low in seawater desalination cost, can be widely popularized and applied, is a most effective and green economic approach and strategic guideline for thorough seawater desalination of water resources of the whole world, and for attracting foreign capital investment and solving domestic water resources.

Description

The system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration and salt

Affiliated technical field: water resources; Sea water desaltination.

Background technology:

Tellurian fresh water content only accounts for 2.53% of global total Water, and wherein 68.7% belongs to solid glacier, is distributed in the high mountain and the polar regions that are difficult to utilization, and part fresh water is buried underground, is difficult to exploitation.

At present, the fresh water that the mankind can directly utilize is taken from underground water, lake fresh water and river bed water, and along with going from bad to worse of environment, it is more and more rare that these Freshwater resources are just becoming, especially in desert and Island.

Earth table is gathered around face 70% area, ocean, and the population that Shang He coastland, island lacks fresh water is more.

But human survival and social development need sufficient Freshwater resources, can only develop at present the huge never exhausted seawater preparing fresh resource that on the earth, natural, ecological has, i.e. sea water desaltination meets the demand of human society to fresh water.

Sea water desaltination English name: sea water desalination; Desalination of seawater

Definition 1: the saltiness of removing seawater is produced the process of satisfactory fresh water.

Definition 2: remove the salinity in seawater and obtain the technological process of fresh water.

As the water of physical form, on the earth and have no lack of, seawater especially.If seawater can be made to fresh water by effective, economically viable technique means, the mankind just can fundamentally solve shortage of water resources, scarcity or exhausted problem.

Sea water desaltination is mainly also can be produced as byproduct with agricultural water and edible salt in order to supply drinking water.

Sea water desaltination utilizes sea water desalinization to produce fresh water.The most effective strategic measure and the technique means that realizes never exhausted seawater preparing fresh resource, can increase fresh water total amount, and be not subject to space-time and weather effect, water quality is good, price is gradually reasonable, can ensure the stable water supplies such as coastal Drinking Water for Residents, agricultural water and process water.From seawater, obtain the process meaning sea water desaltination of fresh water.Method for desalting seawater used has seawater freezing method, electroosmose process, distillation method, reverse osmosis method now, and the reverse osmosis method of reverse osmosis membrane is mainly applied in countries in the world at present.

Solve the strategy plan-sea water desaltination of worldwide fresh water crisis

Fresh water scarcity has become current many countries and regions large problem urgently to be resolved hurrily.At present many countries are all carrying out sea water desaltination experiment, and the general method adopting is reverse osmosis membrane, utilizes seawater and fresh water concentration difference, to seawater, exerts pressure and becomes fresh water by anti-seepage membrane.But this method high cost, needs often to clean permeable membrane, safeguards that huge device difficulty is also very high, and seawater utilization rate also only has 30%, and light Water was as precious as oil.

Sea water desaltination is the dream that the mankind have pursued the centuries.Before more than 400 years, British royal family was just once put on someone's head and was solicited economical method for desalting seawater.

Sea water desaltination substitutes and increment technique as Freshwater resources, more and more comes into one's own and supports, becomes feasible scheme and the important channel of not solving water crisis.

According to the report of the World Bank, in low-income groups in the world, there is 1/4th population cannot obtain the necessary minimum water consumption (20 liters) of surviving.Along with the aggravation of climate change, the scarcity of water resources will make increasing national seawater development desalination techniques, particularly the country of the arid in Middle East.At present sea water desaltination water only accounts for 1% of whole world tap water total amount, but according to the statistic data of international sea water desaltination federation, from 1994 to 2004, has increased twice many between the throughput of sea water desaltination.

According to statistics, there are in the world more than 150 countries and regions to carry out sea water desaltination work, total approximately 14000 desalimtors.Global Seawater desalination day output has reached more than 6,300 ten thousand tons, and soaring in the speed with annual 10%～30%, and wherein 80% for tap water, has solved people's water supply problem more than 100,000,000.

The desalination technology adopting has in the world reached ten plants, and suits measures to local conditions to meet the mankind's production, living needs according to different advantages and feature.This wherein, distillation method, electroosmose process, reverse osmosis method have reached commercial scale production application, mostly are large-scale sea water desaltination project and adopt.Reverse osmosis technology great advantage is energy-conservation, and energy consumption is only 1/2 of electroosmose process, 1/40 of distillation method.Therefore, from Qi， Mei,Deng developed country in 1974, successively development center of gravity is turned to reverse osmosis method.

The main resistance that desalination technology is promoted not is environmental factors, but energy consumption.

Zander says that American National Science committee has set up panel of experts, wishes desalination technology to be improved, thereby reduces its cost.But they find that the efficiency of this technology has reached the current limit.This report prediction, desalimtor now can only reduce at most 15% energy consumption.In tap water prepared by utilization " reverse osmosis " desalination technology, the content of boron has surpassed the standard of World Health Organization's defined.Experimentation on animals proves, the huge uptake of boron can cause the pathology of rat, mouse and dog class testis.In the U.S., due to boron content overproof, stopped examining desalimtor.

According to < < 21 century sustainable development of China water resources strategic research > > report, to 2010 Nian， China water requirement 7,300 hundred million m ³, and the water yield that can supply is 6200～6500m ³, water deficit approximately 1,000 hundred million m ³.What lack of water was the most serious is the coastal region in east China, western Kucheng's water area and large-and-medium size cities, inland.Along with the development of China's economic society, while estimating that the year two thousand thirty, China's population peaked, the situation that Freshwater resources are in short supply will be severeer.Therefore, research and development utilize Discussion about Unconventional Water Resources (seawater, brackish water, Zhong Shui) practical technique, and appropriateness exploitation brackish water has been the task of top priority.

The Party Central Committee, the leading comrade of State Council very payes attention to water resources problems, repeatedly require to support with the sustainable use of water resources the Sustainable development of economic society, for realizing Utilization of Seawater by Solar, the policy of the Discussion about Unconventional Water Resources such as slightly salty, issued the water-saving technology of < < current national encourage growth, equipment (product) catalogue > > (first), this catalogue has comprised seawater, brackish water utilizes equipment at 6 interior series products, every exploitation, development, produce and use the equipment of listing catalogue in, to give preferential tax revenue support by relevant regulations.China plans 2005, and newly-increased seawater and brackish water utilization reach 5,000,000,000 mw.

According to statistics, by 20 end of the centurys, domestic and imported film product and embrane method engineering of water treatment annual sales amount have reached 2,000,000,000 Renminbi.Estimate that 2005 Nian， China film market requirements will be more than 5,000,000,000 yuan, average annual growth rate continues to remain on 15% left and right, and 2015, the film market requirement was expected to surpass 20,000,000,000 yuan, will account for 10%～15% left and right of world's total amount.

Current China membrane technique is compared with advanced country in the world still larger gap, is mainly that the kind of film is few, poor performance, and now primary is to develop as early as possible the various high performance membranes that reach international standards, and makes it to realize as early as possible industrialization; Strengthen cooperation with international counterparts simultaneously, strive breaking through early in the world still unsolved some gordian technique, as: new cheap energy technology, heat transfer technology, material technology and new process Deng，Shi China world standard that forereaches as early as possible.The requirement of situation, leader's attention, strong policy, wide market, shows the prospect of the exploitation of China's brackish water.

In future, utilizing the new technologies such as sun power, nanotechnology is that sea water desaltination reduces costs the trend of moving towards maximization.

The General Office of the State Council issues < < about accelerating development the suggestion > > of sea water desaltination industry a few days ago.To 2015 Nian， China sea water desaltination abilities, reached for 2,200,000～260 ten thousand stere/days; Sea water desaltination starting material, equipment are manufactured autonomous innovation rate and are reached more than 70%; Set up comparatively perfect sea water desaltination industrial chain, research and development and the manufacturing capacity of gordian technique, equipment, material are reached advanced world standards.

Engineering and the complexes of each links such as active research seawater development desalination water intaking, pre-treatment, desalination water aftertreatment, strong brine comprehensive utilization and discharge disposal.

Summary of the invention:

Dual-purpose waterwheel pulse pump of the present invention is three use; 1) in mobile seawater, pumpable goes out seawater and floods more than 10 meters for round-the-clock of shaft type hydroelectric generator store battery and the commercial power socket that then charging-discharging controller connects that be electrically connected.2) for sea water desaltination of the present invention, produce salt and fresh water.3), for the radiating and cooling of sea water desaltination facility of the present invention, exhaustless seawater returns to sea bed.

More dual-purpose waterwheel pulse pump of the present invention, without other energy, utilizes mobile water to overlap series connection and can flood more than hundred meters.

Thermoelectric generator of the present invention and do not having the gentle breeze-driven generator that the sun or night are used to guarantee round-the-clock power supply.

The high-order pump water of dual-purpose waterwheel pulse pump, for the round-the-clock generating of shaft type hydroelectric generator, supplies the pre-place of the rising pipe connection device of shaft type hydroelectric generator to connect seawater main valve of the present invention, and the pipeline that seawater main valve is connecting is connecting seawater desalination system device of the present invention.

Gravity evaporation and condensation vacuum-energy pump of the present invention can make seawater flash evapn or condense when flowing through, salt grain in sea water desaltination steam declines and collects by deadweight, when high-temperature steam is collided with low temperature, dewfall becomes fresh water, through connecting water purifier and ozone sterilizer, flows out safe and reliable tap water.

In the present invention, be connected with electric heating pump and electromagnetic pump or utilize self power generation or civil power carries out round-the-clock sea water desaltination work.

Use of seawater desalination process: in the flow of seawater pump pulse AD- dual waterwheel includes A- dug sequentially connected tubing bailer of B4- axis B- axis tube connecting tubing the shock tube C2- C4- C1- tube high waters of the C- terminal connected to the water pipe connected to the output port is connected by a tube connected C3- inclined tube connecting the outlet pipe connected to the C5- port connection with E- shaft E0- hydroelectric inlet port connected to the drain connected to the E3- seat connected XF- preprocessor includes the XF0- inlet pipe connected to the XF1- filler connection XF2- outlet pipe connected to the F ① through FY- the water main valve connected to the Y1- tee all the way to sequentially connected to the F ② F80- pipe F ③ connected FU1- inlet pipe F ④ FUA- seawater cooling bucket connected to the FU0- sealed bucket is attached, with the FU2- outlet F ⑤ connection with F82- pipe F ⑥ connected to the Y2- tee connection with F84- pipe F ⑦ connection with the Y3- tee F ⑧ way connected with the F85- pipe F ⑨ connection with the FHA- sea radiator FH0- seal tank the FH1- connected to the inlet pipe F <img TranNum = "91" file = "BSA00000757283600031.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait "wi =" 40 "/> FH2- outlet connection F <img TranNum =" 92 "file =" BSA00000757283600032.GIF "he =" 40 "img-content =" drawing "img-format =" tif "inline = "yes" orientation = "portrait" wi = "41" /> connection with the F87- pipe F <img TranNum = "93" file = "BSA00000757283600033.GIF" he = "40" img-content = "drawing" img- format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected to the Y4- tee pipe connected to the F89- F <img TranNum = "94" file = "BSA00000757283600034.GIF "he =" 41 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> connection with the Y6- tee F <img TranNum = "95" file = "BSA00000757283600035.GIF" he = "40" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connection with the F7 - F72- F70- nozzle spray spray claw connected connection F71- jet head claw connection ; another F FY- way valve connected to the water a total of Y1- tee <img TranNum = "96" file = "BSA00000757283600036.GIF "he =" 41 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 41 "/> in turn connected to the F81- water pipes connected to the FUB - FU1- F seawater cooling water inlet pipe connected to the barrel of FU0- sealed buckets connected <img TranNum = "97" file = "BSA00000757283600037.GIF" he = "40" img-content = "drawing" img-format = "tif "inline =" yes "orientation =" portrait "wi =" 40 "/> by FU2- outlet F <img TranNum =" 98 "file =" BSA00000757283600038.GIF "he =" 40 "img-content =" drawing " img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connection with the F83- pipe F <img TranNum = "99" file = "BSA00000757283600039.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> F84- F ⑦ pipes connected to the tee connection Y2- Y3- three connected through the tube F <img TranNum = "100" file = "BSA000007572836000310.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40 "/> F86- water connection is connected to Y5- tee F <img TranNum =" 101 "file =" BSA000007572836000311.GIF "he =" 42 "img-content =" drawing "img-format =" tif "inline = "yes" orientation = "portrait" wi = "40" /> all the way through F <img TranNum = "102" file = "BSA000007572836000312.GIF" he = "41" img-content = "drawing" img-format = " tif "inline =" yes "orientation =" portrait "wi =" 41 "/> FHB- connected to the water radiator connection with the FH0- sealed tank through the inlet pipe connection FH1- F <img TranNum =" 103 "file =" BSA000007572836000313.GIF "he =" 41 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 41 "/> connected to the FH2- outlet F <img TranNum = "104" file = "BSA000007572836000314.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected F88- pipe connected to Y4- tee F <img TranNum = "105" file = "BSA000007572836000315.GIF" he = "43" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "61" /> Y5- tee F <img TranNum = "106" file = "BSA000007572836000316.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> another path F <img TranNum = "107" file = "BSA000007572836000317.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connected to the mains through F43- F31- pipe F <img TranNum = "108" file = "BSA000007572836000318.GIF" he = "41 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> is connected to the steam chamber is connected FD4- F40- F43- tank wall is connected to the inlet pipe by F40- F44- tank wall is connected to the outlet pipe F <img TranNum = "109" file = "BSA000007572836000319.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes "orientation =" portrait "wi =" 41 "/> connection with the F32- pipe F <img TranNum =" 110 "file =" BSA000007572836000320.GIF "he =" 40 "img-content =" drawing "img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected to Y6- tee .

Accompanying drawing explanation:

Fig. 1: dual-purpose waterwheel pulse pump schematic diagram.

Fig. 1-1: dual-purpose waterwheel pulse pump diagrammatic cross-section;

Fig. 1-2: dual-purpose waterwheel pulse pump sectional schematic diagram.

Fig. 2: gravitational force ball-valve pipe schematic diagram.

Fig. 2-1: valve pipe schematic three dimensional views;

Fig. 2-2: ball valve pipe vertical cut-away schematic view;

Fig. 2-3: ball valve pipe horizontal section schematic diagram.

Fig. 3: dual-purpose waterwheel pulse pump pump line wooden dipper spoon schematic diagram.

Fig. 3-1: pump line wooden dipper spoon diagrammatic cross-section;

Fig. 3-2: pump line wooden dipper spoon schematic three dimensional views;

Fig. 3-3: waterwheel pulse pump pump line wooden dipper spoon principle of work diagram.

Fig. 4: dual-purpose waterwheel pulse pump connects generator and supplies sea water desaltination schematic diagram.

Fig. 4-1: the high-order pump water of dual-purpose waterwheel pulse pump sectional schematic diagram;

Fig. 4-2: the high-order pump water of dual-purpose waterwheel pulse pump sketch;

Fig. 4-3: starlike connection human skull connects gravity valve block schematic diagram;

Fig. 4-4: shaft type water rushes generator and connects pre-place device diagram;

Fig. 4-5: shaft type water rushes generator sketch;

Fig. 4-6: dual-purpose waterwheel pulse pump gravity valve block pump water sectional schematic diagram;

Fig. 4-7: the high-order pump water of dual-purpose waterwheel pulse pump connects shaft type hydroelectric generator section sketch.

Fig. 5: vacuum-energy pump diagram.

Fig. 5-1: semiconductor chip connects pump face schematic diagram;

Fig. 5-2: schematic diagram at the bottom of semiconductor chip connection pump face connection pump;

Fig. 5-3: pump cone schematic diagram;

Fig. 5-4: pump line schematic diagram;

Fig. 5-5: pump cone connects pump line schematic diagram;

Fig. 5-6: pump line connects calrod schematic diagram;

Fig. 5-7: pump line connects the solenoid schematic diagram of electromagnetic stove;

Fig. 5-8: single pump vacuum-energy pump schematic diagram;

Fig. 5-9: double pump semiconductor chip connects pump face schematic diagram;

Fig. 5-10: double pump vacuum-energy pump schematic diagram;

Fig. 5-11: double pump vacuum-energy pump diagrammatic cross-section;

Fig. 6: vacuum-energy pump power generation assembly schematic diagram.

Fig. 6-1: vacuum-energy generating pump principle schematic;

Fig. 6-2: single pump vacuum-energy pump profile schematic diagram;

Fig. 6-3: double pump vacuum-energy pump profile schematic diagram;

Fig. 6-4: vacuum-energy generating pumping unit connection diagram;

Fig. 6-5: vacuum-energy generating pump profile schematic diagram.

Fig. 7: gravity evaporation and condensation pump schematic diagram.

Fig. 7-1: rectangular schematic diagram;

Fig. 7-2:180 degree revolving fragment schematic diagram;

Fig. 7-3:180 degree revolving fragment is connected in series schematic diagram by 90 degree;

Fig. 7-4: pipe diagram;

Fig. 7-5:180 degree revolving fragment is connected in series rear insertion pipe diagram by 90 degree;

Fig. 7-6: gravity evaporation and condensation pipe schematic diagram.

Fig. 8: gentle breeze-driven generator diagram.

Fig. 9: the system and device diagram of round-the-clock vacuum-energy pump pyrogenicity refrigeration dewfall preparing fresh and salt.

Fig. 9-1: the system and device sketch of round-the-clock vacuum-energy pump pyrogenicity refrigeration dewfall preparing fresh and salt;

Fig. 9-2: the process flow diagram of the system of vacuum-energy pump pyrogenicity refrigeration dewfall preparing fresh and salt.

Figure 10: the system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration and salt.

Figure 10-1: the system and device schematic diagram of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration and salt;

Figure 10-2: the process flow diagram of the system and device of round-the-clock seawater preparing fresh and salt.

In figure: the dual-purpose waterwheel pulse pump of AD-; A-digs water ladle pump line; A1-gravitational force ball-valve; A06-spheroid, A2-pump line, A3-water ladle, A4-network interface, A5-pushing assisted plate, A6-clamping rings circle; B0-star human skull, B01-centre hole, B02-centre hole; B-pump line central siphon, B1-sealing pipe end, B2-human skull front end, B3-human skull rear end, B4-axis go to sea water end (W.E.), B51-bearing, B52-bearing, B6-sealing bearing; The defeated seawater pipe of C-, C1-pipe are pressed mouth, the high-order pipe of C2-, C3-inclined tube, C4-impact tube, C5-effluent pipe mouth; D-base, D1-seat legs and feet, D2-seat legs and feet, D3-bearing support, D4-support; At the bottom of the seawater that X-seawater, the X1-water surface, X2-water body, X3-pump, X4-locate seawater, XX-sea bed in advance; Section, the A02-hypomere valve mouth of pipe, A03-lower nozzle, the A04-epimere valve mouth of pipe, A05-upper orifice are leaked in A00-ball valve pipe, A01-hole; A21-pump line, A22-pump line, A23-pump line, A24-pump line; AL-gravity valve block; E-shaft type hydroelectric generator, E0-water inlet pipe mouth, E1-Striker, E2-impeller, E3-draining base, E4-motor shaft, E5-generator, VK0-power output socket, XF-locate device in advance; DCV-charging-discharging controller, DV-store battery, Y-civil power; The mono-pump vacuum-energy of FA-pump, FAQ-double pump vacuum-energy pump, F18-solenoid, the supply socket of VK5-solenoid, F20-U type pipe, F21-calrod, the supply socket of VK6-calrod; The mono-vacuum-energy pump of U1-face, U2-double pump vacuum-energy pump face, U3-pump drain pan, U4-cone, U5-duplex pump line, U6-side's pump, FX-sealing cover end; At the bottom of 0-pump face, 1-pump face, at the bottom of 2-cone, the 3-conical surface, 4-connection piece, 5-hole, T-bolt, 6-drain pan, 7-front cover, 8-opening end, 9-bottom surface, 10-cone frame, 11-cone mouth, 12-pump line deutostoma, 13-coiled pipe, 14-pump line front end, 15-pump port lid, 16-opening cone, 17-opening, 18-side's pump line, 19-side's pump, 20-side's pump face, U5V-electric heating pump, U5U-electromagnetic pump; BB0-vacuum-energy liquid; FA1-heat build-up end, the defeated hot arc of FA2-, FA3-radiating end, FA4-gravity evaporation pump; FB1-inhales cold junction, defeated cold section of FB2-, FB3-cold scattering end; FC1-inhales cold junction, defeated cold section of FC2-, FC3-cold scattering end; FD1-inhales cold junction, defeated cold section of FD2-, FD3-gravity dewfall pump, FD4-steam seawater condensing chamber; F1-heat build-up electric organ; F10-heat build-up pump line, F11-heat collector, F12-vacuum pipe, F13-para-curve reflection shield, F14-framework, U-shaped, F15-motor, F16-light regulate two-position controller, VK3-supply lead, F18-electromagnetic stove coil, F21 calrod, F19-supply lead, F22-supply lead, F101-pump line cover, L support, F23-base, the folding legs and feet of F24-; T-bolt, FHA-seawater scatterer, FH0-staving, FH1-water inlet pipe, FH2-rising pipe; FUA-cooled with seawater bucket; FUB-cooled with seawater bucket; FU0-staving, FU1-water inlet pipe, FU2-rising pipe; FAB-thermoelectric generator, FV-semiconductor thermoelectric generator, Z-thermal insulation layer; E-gravity evaporation and condensation pump; Recess, E2-180 degree revolving fragment, E21-revolving fragment, E22-revolving fragment, E23-revolving fragment, E24-revolving fragment, E25-revolving fragment, E30-revolving fragment, the outer pipe of E3-, E30-pipe, E31-upper orifice, E32-lower nozzle under rectangular of E1-, E11-upper notch, E12-; F4-gentle breeze-driven generator, F40-blade, F41-axle, F42-speed-up generator, F43-socket, F44-montant; FAD-low-temperature receiver device; K30-pipe wall, the upper pump of K31-connect pump under disk, K32-and connect disk; F2-evaporative desalination device, K30-pipe wall, the upper pump of K31-connect pump under disk, K32-and connect disk; The F20-steam vertex of a cone, the F201-cone end, F202-epicone footpath, F203-cone mouth; At the bottom of FD4-sweating room, F40-bucket wall, F41-bucket, F42-bung, F43-water inlet pipe, F44-rising pipe, FD5-back taper top, the FD50-vertex of a cone; F7-sprinker, F70-shower nozzle, F71-spray pawl head, F72-spray pawl; The F60-desalination cone end, F61-go out the salt mouth of pipe; F6-salt travelling belt; F9-fresh water cone, the F90-cone end, F91-Taper Pipe mouth, F92-outlet, F93-pipe, F94-fresh water valve, 000-fresh water; FU-cooled with seawater bucket; FU0-sealing water pail, FU1-water inlet pipe, FU2-rising pipe; FHA-seawater scatterer, FHB-seawater scatterer; FH0-sealing radiator, FH1-water inlet pipe, FH2-rising pipe; FY-seawater main valve, FV-semiconductor temperature differential generating sheet, FD-semiconductor chilling plate; VK0-shaft type hydroelectric generator power output socket, VK1-thermo-electric generation power output socket, VK2-gentle breeze-driven generator power output socket, VK3-light regulate two-position controller power input socket, VK4-semiconductor chilling plate power input socket; XF0-water inlet pipe, XF1-filler, XF2-rising pipe, FD5-condensation cone bucket, FD50-condensation cone, EW-seawater steam, EQ-salt grain, FP-desalination steam, FQ-condensing water droplet; Y-Y-tube, Y1-Y-tube, Y2-Y-tube, Y3-Y-tube, Y4-Y-tube, Y5-Y-tube, Y6-Y-tube; F80-water pipe, F81-water pipe, F82-water pipe, F83-water pipe, F84-water pipe, F85-water pipe, F86-water pipe, F87-water pipe, F88-water pipe, F89-water pipe; R-water purifier, P-ozone sterilizer, M-framework.

Embodiment:

In Fig. 1,2,3,4: the dual-purpose waterwheel pulse pump of AD-; A-digs water ladle pump line; A1-gravitational force ball-valve; A06-spheroid, A2-pump line, A3-water ladle, A4-network interface, A5-pushing assisted plate, A6-clamping rings circle; B0-star human skull, B01-centre hole, B02-centre hole; B-pump line central siphon, B1-sealing pipe end, B2-human skull front end, B3-human skull rear end, B4-axis go to sea water end (W.E.), B51-bearing, B52-bearing, B6-sealing bearing, section, the A02-hypomere valve mouth of pipe, A03-lower nozzle, the A04-epimere valve mouth of pipe, A05-upper orifice, the defeated seawater pipe of C-, C1-pipe are leaked by mouth in A00-ball valve pipe, A01-hole, the high-order pipe of C2-, C3-inclined tube, C4-impact tube, C5-effluent pipe mouth; D-base, D1-seat legs and feet, D2-seat legs and feet, D3-bearing support, D4-support; A21-pump line, A22-pump line, A23-pump line, A24-pump line; AL-gravity valve block; E-shaft type hydroelectric generator, E0-water inlet pipe mouth, E1-Striker, E2-impeller, E3-draining base, E4-motor shaft, E5-generator, VK0-power output socket, XF-locate device, XF0-water inlet pipe, XF1-filler, XF2-rising pipe in advance; DCV-charging-discharging controller; At the bottom of the seawater that X-seawater, the X1-water surface, X2-water body, X3-pump, X4-locate seawater, XX-sea bed in advance.

In figure: the dual-purpose waterwheel pulse pump of AD-comprises that connecting B0-star human skull connection A-by B-pump line central siphon digs water ladle pump line, and B-pump line central siphon connects D-base and forms; B-pump line central siphon is connecting in turn B51-bearing and is connecting B2-human skull front end and be connected go to sea water end (W.E.) be connected outside B6-sealing bearing of B52-bearing and B4-axis with B3-human skull rear end; Between the B2-human skull front end in B-pump line central siphon stage casing and B3-human skull rear end, opening B01-centre hole and B02-centre hole; The rear end of B-pump line central siphon is B1-sealing pipe end; B2-human skull front end at B-pump line central siphon is being connected B0-star human skull with on B3-human skull rear end; On B0-star human skull outer ring, connect A-and digging water ladle pump line; A-digs water ladle pump line and comprises that by A2-pump line one end, connecting A3-water ladle connects A4-network interface, and A3-water ladle connects A5-pushing assisted plate, and the other end connects A1-gravitational force ball-valve or AL-gravity valve block; A1-gravitational force ball-valve comprises that by the A00-ball valve pipe connecting in turn, A05-upper orifice, the A04-epimere valve mouth of pipe, A01-hole, leaking section, the A02-hypomere valve mouth of pipe, A03-lower nozzle forms; In A00-ball valve pipe, placing A06-spheroid; The A-that the B0-star human skull connecting at B-pump line central siphon is connecting a circle outward digs in the middle of water ladle pump line two and is connecting A6-clamping rings circle; The B51-bearing connecting at B-pump line central siphon is being connected the D-base that D3-bearing support connects with the lower end of B52-bearing; D-base comprises by D1-seat legs and feet and D2-seat legs and feet; At D1-seat legs and feet, be connected D3-bearing support with D2-seat legs and feet top; On D2-seat legs and feet top, connecting D4-support; Go to sea water end (W.E.) connecting outside B6-sealing bearing of the B4-axis connecting at B-pump line central siphon; At B6-sealing bearing, connecting in turn the high-order pipe of C2-that the C1-interface tube of the defeated seawater pipe of C-connects outward and be connected E0-water inlet pipe mouth, E1-Striker, E2-impeller that E-shaft type hydroelectric generator connecting in turn the C3-inclined tube connecting with C4-impact tube with C5-effluent pipe mouth and connecting E3-draining base that E4-motor shaft, E5-generator, VK0-power output socket connection DCV-charging-discharging controller connecting and connect again XF-and locate in advance device.

In Fig. 5,6: the mono-pump vacuum-energy of FA-pump, FAQ-double pump vacuum-energy pump, F18-solenoid, the supply socket of VK5-solenoid, F20-U type pipe, F21-calrod, the supply socket of VK6-calrod; The mono-vacuum-energy pump of U1-face, U2-double pump vacuum-energy pump face, U3-pump drain pan, U4-cone, U5-duplex pump line, U6-side's pump, FX-sealing cover end; At the bottom of 0-pump face, 1-pump face, at the bottom of 2-cone, the 3-conical surface, 4-connection piece, 5-hole, T-bolt, 6-drain pan, 7-front cover, 8-opening end, 9-bottom surface, 10-cone frame, 11-cone mouth, 12-pump line deutostoma, 13-coiled pipe, 14-pump line front end, 15-pump port lid, 16-opening cone, 17-opening, 18-side's pump line, 19-side's pump, 20-side's pump face, BB0-vacuum-energy liquid; U5V-electric heating pump, U5U-electromagnetic pump; FA1-heat build-up end, the defeated hot arc of FA2-, FA3-radiating end, FA4-gravity evaporation pump; FB1-inhales cold junction, defeated cold section of FB2-, FB3-cold scattering end; FC1-inhales cold junction, defeated cold section of FC2-, FC3-cold scattering end; FD1-inhales cold junction, defeated cold section of FD2-, FD3-gravity dewfall pump, FD4-steam seawater condensing chamber; F1-heat build-up electric organ; F10-heat build-up pump line, F11-heat collector, F12-vacuum pipe, F13-para-curve reflection shield, F14-framework, U-shaped, F15-motor, DCV-charging-discharging controller, DV-store battery, Y-civil power; F16-light regulates two-position controller, VK3-supply lead, F18-electromagnetic stove coil, F21 calrod, F19-supply lead, F22-supply lead, L support, F101-pump line cover, F23-base, the folding legs and feet of F24-; T-bolt, FHA-seawater scatterer, FH0-staving, FH1-water inlet pipe, FH2-rising pipe; FU-seawater low-temperature receiver bucket, FU0-staving, FU1-water inlet pipe, FU2-rising pipe; FAB-thermoelectric generator, FV-semiconductor thermoelectric generator, FAQ-double pump vacuum-energy pump, Z-thermal insulation layer.

In figure: at the bottom of the mono-vacuum-energy pump of U1-face comprises and connecting 1-pump face by 0-pump face, on 0-pump face, connecting the 3-conical surface that 2-facies superior pyramidis is connecting, at the bottom of the 1-pump face connecting at 0-pump face, two are connecting 4-connection piece, are connecting 5-hole, mold strikes out a slice on 4-connection piece; At the bottom of U2-double pump vacuum-energy pump face comprises and connecting 1-pump face by 0-pump face, on 0-pump face, connecting 17-opening above the 16-opening cone 17-opening mold on 16-opening cone and striking out a slice; 18-side's pump line is being tightly connected in 17-opening; The 20-side's pump face being connected with top at the bottom of 19-side's pump that 18-side's pump line is being connected by bottom also seals after interior injection BB0-vacuum-energy liquid; The mono-pump vacuum-energy of FA-pump comprises that the U3-pump drain pan being connected in turn by the mono-vacuum-energy pump of U1-face connects U4-cone and connects U5-duplex pump line; U3-pump drain pan comprises that the 9-bottom surface of the 7-front cover connection being connected by 6-drain pan and the 8-opening end mold of upper end strike out one; U4-cone connects 11-cone mouth mold by 10-cone frame and strikes out one; U5-duplex pump line connects 13-coiled pipe by the 12-pump line deutostoma connecting in turn and connects 14-pump line front end connection 15-pump port lid; FAQ-double pump vacuum-energy pump comprises that the U3-pump drain pan being connected in turn by U2-double pump vacuum-energy pump face connects U4-cone and connects U5-duplex pump line; At the bottom of the 0-pump face that U2-double pump vacuum-energy pump face is connecting is in turn connecting 1-pump face, on 0-pump face, connecting in 17-opening above the 16-opening cone 17-opening on 16-opening cone and connecting 18-side's pump line; U5-duplex pump line connects 13-coiled pipe by the 12-pump line deutostoma connecting in turn and connects 14-pump line front end connection 15-pump port lid and seal after interior injection BB0-vacuum-energy liquid; U5V-electric heating pump is included in the 15-pump port lid that 14-pump line front end that U5-duplex pump line connecting connecting and is connecting F20-U type pipe and connecting in interior insertion the VK6-calrod power plug that F21-calrod is connecting; After injecting BB0-vacuum-energy liquid in U5-duplex pump line, seal; The front end that U5U-electromagnetic pump is included in outside the 14-pump line front end that U5-duplex pump line connecting is inserted in and is being connected F18-solenoid and the VK5-solenoid supply socket being connected with the upper end of 15-pump port lid outside FX-sealing cover end; After injecting BB0-vacuum-energy liquid in U5-duplex pump line, seal; U1-mono-vacuum-energy pump face or U2-double pump vacuum-energy pump face claim FA4-gravity evaporation pump, FD3-gravity dewfall pump, the FD4-steam seawater condensing chamber that FA3-radiating end, FB3-cold scattering end, FC3-cold scattering end, FD3-cold scattering end are being connected with top in the present invention; The 13-coiled pipe that U5-duplex pump line connects claims the defeated hot arc of FA2-, defeated cold section of FB2-, defeated cold section of FC2-, defeated cold section of FD2-in the present invention; The 14-pump line front end that the 13-coiled pipe that U5-duplex pump line connects connects claims that FA1-heat build-up end, FB1-suction cold junction, FC1-inhale cold junction, FD1-inhales cold junction in the present invention; F1-heat build-up electric organ comprises the F14-framework that F13-para-curve reflection shield that F12-vacuum pipe that F11-heat collector that the F10-heat build-up pump line by the FA1-heat build-up end connecting is in turn connecting is connecting is connecting is connecting outward outward outward outward; In U-shaped of F14-framework top, connecting F15-motor is connecting F16-light and regulates two-position controller connecting VK3-supply lead to connect F18-electromagnetic stove coil, F21 calrod and connecting F19, F22-supply lead and connecting the DV-store battery that DCV-charging-discharging controller connecting and connecting Y-civil power; In the bottom of F10-heat build-up pump line, connect F101-pump line cover and be connected on the L support of F14-framework, on F14-framework top, connecting the folding legs and feet of F24-; The folding legs and feet of F24-that F14-framework top is connecting are connected on F23-base; F1-heat build-up electric organ comprises the FA3-radiating end that the defeated hot arc of FA2-that connected in turn by FA1-heat build-up end is connecting; FAB-thermoelectric generator comprises the FB3-cold scattering end of the FAQ-double pump vacuum-energy pump that FV-semiconductor thermoelectric generator that the FA3-radiating end by FAQ-double pump vacuum-energy pump is connecting is in turn connecting; The 5-aperture T-bolt connecting on the 4-connection piece connecting above the 0-pump face that FA3-radiating end connects connects the 5-hole connecting on the 4-connection piece connecting above the 0-pump face of FB3-cold scattering end connection; In the 5-hole on two sides, be connected T-bolt with insertion in the middle of 5-hole; The FB3-cold scattering end that connects FAQ-double pump vacuum-energy pump is connecting FHA-seawater scatterer outward; FHA-seawater scatterer is connecting FH1-water inlet pipe by FH0-staving and is connecting FH2-rising pipe; FH0-staving, FH1-water inlet pipe, FH2-rising pipe; The VK1-thermo-electric generation power output socket that FV-semiconductor thermoelectric generator is connecting is connecting the DV-store battery that DCV-charging-discharging controller connecting and is connecting Y-civil power; The FB3-cold scattering end of AQ-double pump vacuum-energy pump is connecting in turn the defeated cold section of FB1-connecting of FB2-and is inhaling cold junction; FB1-inhales cold junction insertion and is connected in FU-seawater low-temperature receiver bucket; FU-seawater low-temperature receiver bucket is connecting FU1-water inlet pipe and FU2-rising pipe outward by FU0-staving; In FAB-thermoelectric generator outer ring, connecting Z-thermal insulation layer.

In Fig. 7: E-gravity evaporation and condensation pump; Recess, E2-180 degree revolving fragment, E21-revolving fragment, E22-revolving fragment, E23-revolving fragment, E24-revolving fragment, E25-revolving fragment, E30-revolving fragment, the outer pipe of E3-, E30-pipe, E31-upper orifice, E32-lower nozzle under rectangular of E1-, E11-upper notch, E12-.

In figure: E2-180 degree revolving fragment is to stamp out under E11-upper notch and E12-recess through stamping forming E2-180 degree revolving fragment at rectangular upper and lower ends of E1-; E-gravity evaporation and condensation pump comprises that by one group of mutual 90-degree rotation of (10) E2-180 degree revolving fragment, connecting rear insertion is connected in E30-pipe; E-gravity evaporation and condensation pump comprises that by E21-revolving fragment 90-degree rotation, connecting E22-revolving fragment 90-degree rotation connects one group 10 of E23-revolving fragment 90-degree rotation connection E24-revolving fragment 90-degree rotation connection E25-revolving fragment 90-degree rotation connection E30-revolving fragments.

In Fig. 8: F4-gentle breeze-driven generator, F40-blade, F41-axle, F42-speed-up generator, VK2-socket, F44-montant.

In figure: F4-gentle breeze-driven generator comprises the VK2-gentle breeze-driven generator power output socket that the F42-speed-up generator of the F41-axle connection being connected in turn by F40-blade connects, and is connecting F44-montant in F42-speed-up generator bottom surface.

In Fig. 9,10: FA1-heat build-up end, the defeated hot arc of FA2-, FA3-radiating end, FA4-gravity evaporation pump; FB1-inhales cold junction, defeated cold section of FB2-, FB3-cold scattering end; FC1-inhales cold junction, defeated cold section of FC2-, FC3-cold scattering end; FD1-inhales cold junction, defeated cold section of FD2-, FD3-gravity dewfall pump, FD4-steam seawater condensing chamber; F1-heat build-up electric organ; F10-heat build-up pump line, F11-heat collector, F12-vacuum pipe, F13-para-curve reflection shield, F14-framework, F15-motor, F16-light regulate two-position controller, VK3-supply lead, F18-electromagnetic stove coil, F21 calrod, F19-supply lead, F22-supply lead, F101-pump line cover, F23-base, the folding legs and feet of F24-; FAB-thermoelectric generator, FAD-low-temperature receiver device; E-gravity evaporation and condensation pump; The outer pipe of E3-, E31-upper orifice, E32-lower nozzle; K30-pipe wall, the upper pump of K31-connect pump under disk, K32-and connect disk; The F20-steam vertex of a cone, the F201-cone end, F202-epicone footpath, F203-cone mouth; At the bottom of FD4-sweating room, F40-bucket wall, F41-bucket, F42-bung, F43-water inlet pipe, F44-rising pipe, FD5-back taper top, the FD50-vertex of a cone; F7-sprinker, F70-shower nozzle, F71-spray pawl head, F72-spray pawl; The F60-desalination cone end, F61-go out the salt mouth of pipe; F6-salt travelling belt; F9-fresh water cone, the F90-cone end, F91-Taper Pipe mouth, F92-outlet, F93-pipe, F94-fresh water valve, 000-fresh water; FUA-cooled with seawater bucket; FUB-cooled with seawater bucket; FU0-sealing water pail, FU1-water inlet pipe, FU2-rising pipe; FHA-seawater scatterer, FHB-seawater scatterer; FH0-sealing radiator, FH1-water inlet pipe, FH2-rising pipe; FY-seawater main valve, FV-semiconductor temperature differential generating sheet, FD-semiconductor chilling plate; VK0-shaft type hydroelectric generator power output socket, VK1-thermo-electric generation power output socket, VK2-gentle breeze-driven generator power output socket, VK3-light regulate two-position controller power input socket, VK4-semiconductor chilling plate power input socket; FV-semiconductor thermoelectric generator, DCV-charging-discharging controller, DV-store battery, Y-civil power; XF-locates device, XF0-water inlet pipe, XF1-filler, XF2-rising pipe in advance; R-water purifier, P-ozone sterilizer, M-framework; The dual-purpose waterwheel pulse pump of AD-; A-digs water ladle pump line, B-pump line central siphon, B4-axis and goes to sea water end (W.E.), the defeated seawater pipe of C-, C1-pipe by mouth, the high-order pipe of C2-, C3-inclined tube, C4-impact tube, C5-effluent pipe mouth; E-shaft type hydroelectric generator, E0-water inlet pipe mouth, E1-Striker, E2-impeller, E3-draining base, E4-motor shaft, E5-generator, VK0-power output socket; FD5-condensation cone bucket, FD50-condensation cone, EW-seawater steam, EQ-salt grain, FP-desalination steam, FQ-condensing water droplet; Y-Y-tube, Y1-Y-tube, Y2-Y-tube, Y3-Y-tube, Y4-Y-tube, Y5-Y-tube, Y6-Y-tube; F80-water pipe, F81-water pipe, F82-water pipe, F83-water pipe, F84-water pipe, F85-water pipe, F86-water pipe, F87-water pipe, F88-water pipe, F89-water pipe.

Figure : AD- dual waterwheel pulse pump shaft in turn is connected to the E- XF- connected hydroelectric preprocessor is connected with the total FY- sea valves ; E- shaft hydroelectric generators connected to the E5- VK0- connected power outlet is connected to the DV- DCV- battery charge and discharge controller connected electrically connected to the Y- City ; FAB- thermoelectric cooling includes FA3- FV- end in turn connected to the semiconductor thermoelectric generator connected FB3- scattered cold end connected to the evaporation of FA4- gravity pump ; FA3- cooling end connected to FA1- FA2- poly hot side heat transport segment connected down ; FA1- poly connected to the hot end of the F1- poly thermal generators ; FA3- cooling in the upper end is connected to FA4- gravity evaporation pump ; within FA4- gravity pump evaporation from the K30- K31- circular wall is connected to the pump connection wafer and K32- pump connection wafer ; pump connected to the K31- on wafer and wafer- K32- pump connected to an intermediate connection with E- E3- gravity evaporation condensation inside the outer tube is connected to a pump on E31- E32- down nozzle and nozzle ; under the spout in the E32- F60- connected desalination of salt F61- cone bottom nozzle is connected to the lower connection F6- salt conveyor belt ; in K31- connected to the pump connected to the E31- wafer on the upper end of the nozzle sprayers connected F7- F70- nozzle connected to the connection F72- sprayed connected claw claw of F71- jet head ; in K31- on disks connected to the upper end of the pump is connected to the F20- steam apex ; F201- cone bottom , F202- on cone diameter , F203- cone mouth ; F20- steam cone top includes F203- F201- cone cone mouth by the end of the F202- sequentially connected to the cone diameter connected ; FV- semiconductor thermoelectric generator connected to a VK1- thermal power generation is connected to the power outlet DCV- charge controller connected the DV- battery connection with Y- mains ; FB3- scattered cold end connected to the other side of the radiator FHA- sea FH0- sealed water tank connected to the inlet connection of FH1- FH2- outlet ; FB3- heat side down connected to FB1- FB2- lose suction cold side heat seal connector is inserted segment connecting the FU- seawater cooling barrel ; FU1- FU2- inlet and outlet FU- seawater cooling barrel by the FU0- sealed buckets connected ; FAD- cold source includes the FC3- bulk terminal connected to the FD- cold semiconductor refrigeration tablets connected FD1- suck up the cold end is connected sequentially FD2- FD3- gravity segment connecting the output of cold condensation seawater pump and FD4- vapor condensing chamber ; FC3 - scattered cold end connected to the other side of the seal tank FH0- FHB- sea radiator connected to the inlet pipe connection FH1- FH2- outlet ; FC3- heat side down sequentially connected FC2- connected heat transport segment FC1- suction seal attached to the cold end into the FU- seawater cooling barrel ; FU1- FU2- inlet and outlet FU- seawater cooling barrel by the FU0- sealed buckets connected ; VK4- FD- chip semiconductor refrigeration cooling semiconductor chip connections power input socket connector DCV- charge and discharge controller connected to the DV- battery ; FD3- gravitational condensation pump from the K30- K31- circular wall is connected to the pump connection wafer and K32- pump connection wafer ; in K31- the pump is connected wafer and wafer- K32- pump connected to an intermediate connection with E- E3- gravity evaporation condensation inside the outer tube is connected to a pump on E31- E32- down nozzle and nozzle ; pump connected in K31- round nozzle connected to the upper end of the E31- piece connected with FD4- steam room ; FD4- steam chamber includes bottom of the barrel by the F41- F40- tank wall connecting the F42- lid connected to the upper end of the outlet pipe connected to the lower end of F44- F43 connected - into the water in the F40- FD5- tank wall connected to the top of the FD50- inverted cone apex ; gravitational condensation pumps in FD3- F9- freshwater lower connections cone ; F9- cone including freshwater connected by the end of the upper side of the F90- cone the F91- cone nozzle is connected to the lower end of F92- F93- tube is connected to the outlet connector 000 - freshwater outflow of freshwater F94- valve ; among F20- steam apex cone connected to the F203- F9- port connection with cone connection freshwater with the F91- cone nozzle integrally connected ; in the flow of seawater AD- dual waterwheel includes a- pulse pump tubing bailer dig sequentially connected to the B- B4- axis pump tube in tube connection axis of the shock tube C4- C1- C2- high end of the tube is connected to the sea C- lose seawater pipes connected by a tube connecting the mouth to connect C3- inclined tube connecting the outlet pipe connected to the C5- E- port connected to the shaft E0- type hydroelectric inlet port connected to the drain connected to the E3- seat connected XF- preprocessor includes the XF0- inlet pipe connected to the XF1- filler connection XF2- outlet pipe connected to the F ① through FY - the water main valve connected to the Y1- tee all the way in turn connected to the F ② F80- pipe F ③ connected FU1- inlet pipe F ④ FUA- seawater cooling bucket connected to the FU0- sealed bucket is attached, with the FU2- out pipe F ⑤ connected F82- pipe F ⑥ connected to the Y2- tee connected F84- pipe F ⑦ connected to the Y3- tee F ⑧ way connected with F85- pipe F ⑨ connected to the FHA- sea radiator FH0- sealing FH2- F tank outlet pipe connected to the inlet pipe F ⑩ FH1- connected <img TranNum = "175" file = "BSA00000757283600091.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connection with the F87- pipe F <img TranNum = "176" file = "BSA00000757283600092.GIF" he = "40" img-content = "drawing" img -format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connected to the Y4- tee pipe connected to the F89- F <img TranNum = "177" file = "BSA00000757283600093.GIF "he =" 40 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> connection with the Y6- tee F <img TranNum = "178" file = "BSA00000757283600094.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected to the F72- F70- claw spray spray nozzle connected F7- F71- connected claw spray head connected ; FY- sea water main valve connected to another road F Y1- tee <img TranNum = "179" file = " BSA00000757283600095.GIF "he =" 40 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 41 "/> in turn connected to the F81- water pipes connected to the FU1- F FUB- sea water inlet pipe connected to a cooling bucket bucket FU0- sealed connections <img TranNum = "180" file = "BSA00000757283600096.GIF" he = "40" img-content = "drawing" img-format = " tif "inline =" yes "orientation =" portrait "wi =" 41 "/> by FU2- outlet F <img TranNum =" 181 "file =" BSA00000757283600097.GIF "he =" 41 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 41 "/> connection with the F83- pipe F <img TranNum =" 182 "file =" BSA00000757283600098.GIF "he =" 40 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> F84- F ⑦ pipes connected to the tee connection Y2- Y3- connected tee F <img TranNum = "183" file = "BSA00000757283600099.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = " 41 "/> F86- water connection is connected to Y5- tee F <img TranNum =" 184 "file =" BSA000007572836000910.GIF "he =" 41 "img-content =" drawing "img-format =" tif " inline = "yes" orientation = "portrait" wi = "41" /> all the way through F <img TranNum = "185" file = "BSA000007572836000911.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> FHB- connected to the water radiator connection with the FH0- sealed tank through the inlet pipe connection FH1- F <img TranNum = "186" file = "BSA000007572836000912.GIF" he = "40" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connected to the FH2- outlet F < img TranNum = "187" file = "BSA000007572836000913.GIF" he = "41" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connection the F88- water pipes connected to Y4- tee F <img TranNum = "188" file = "BSA000007572836000914.GIF" he = "43" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "60" /> Y5- tee F <img TranNum = "189" file = "BSA000007572836000915.GIF" he = "40" img-content = "drawing" img-format = "tif "inline =" yes "orientation =" portrait "wi =" 41 "/> another path F <img TranNum =" 190 "file =" BSA000007572836000916.GIF "he =" 40 "img-content =" drawing "img- format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected to the mains through F43- F31- pipe F <img TranNum = "191" file = "BSA000007572836000917.GIF" he = " 40 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> is connected to the steam chamber is connected FD4- F40- F43- tank wall is connected to the intake pipe connected to the tank wall by the F40- F44- outlet F <img TranNum = "192" file = "BSA000007572836000918.GIF" he = "40" img-content = "drawing" img-format = "tif" inline = " yes "orientation =" portrait "wi =" 40 "/> connection with the F32- pipe F <img TranNum =" 193 "file =" BSA000007572836000919.GIF "he =" 41 "img-content =" drawing "img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connected to Y6- tee ....

Claims (5)

1 all-weather sea water from the condensate pump power caused by thermally induced freshwater and salt Preparation System devices, including AD-dual-pulse pump water tankers, E-shaft hydroelectric, FV-film semiconductor thermoelectric power generation, F4-wind generators, DCV-charge and discharge controller, DV-battery, FD-semiconductor refrigeration tablets, F18-magnetic coil, F21-electric rods, Y-mains, F16-automatic light adjustment control, F15-motor, XF-preprocessor, a The total FY-sea valves, FA-single vacuum pump can pump, FAQ-dual vacuum pump can pump, FD3-gravitational condensation pump, FD4-steam condensing chamber seawater, F1-poly thermal generators, FHA-sea radiator, FHB - the water radiator, FUA-seawater cooling barrel, FUB-seawater cooling barrel, FAB-thermoelectric generators, E-gravity evaporation condensation pump, F2-evaporation desalter, FD4-steam room, F7-sprayers, F60-desalination cone Bottom, F6-salt conveyors, F9-fresh cone, R-purifier, P-Ozone Sterilizer, M-frame; characterized; AD-dual sequential pulse pump connected to the waterwheel E-shaft hydroelectric Connect with XF-preprocessor is connected with the total FY-sea valves; E-shaft hydroelectric generators connected to the E5-VK0-connected power outlet is connected to the DV-DCV-battery charge and discharge controller connected Y-connected electricity; FAB-thermoelectric cooling includes FA3-end sequentially connected FV-semiconductor thermoelectric generator connected FB3-scattered connected to the cold end of FA4-gravity evaporation pump; FA3-heat side down connected to FA1-poly hot end FA2-heat transport segment connected; FA1-poly hot end connected to the F1-poly thermal generators; at the top FA3-heat side of the connection with FA4-gravity evaporation pump; FA4-gravity evaporation pump K30-round by the wall of the pump is connected to the K31-K32-connected wafer and wafer pump connected; pump in K31-K32-connected wafer and wafer-pump connection among connected E-gravity evaporation condensation pump The outer tube is connected to the E3-E31-E32-upper and lower nozzle orifice; under the E32-F60-nozzle connected to the desalination conical bottom connection F61-out salt is connected to the lower end of the nozzle F6-salt conveyor belt; in K31-on disks connected to a pump connected to the upper end of the spout E31-connected claw F7-F72-spray sprinklers connected to the nozzle is attached, F70-F71-jet with a claw head; in K31-round connection on the pump F20-piece upper end connected to the steam apex; F201-cone bottom, F202-on cone diameter, F203-cone mouth; F20-vapor cone top, including the F201-cone bottom in turn connected to the F202-F203 connected on a cone diameter - Cone mouth; FV-semiconductor thermoelectric generator connected to a VK1-thermal power generation is connected to the power outlet DCV-charge and discharge controller connected to the DV-battery connection with Y-mains; other side FB3-bulk terminal connected to the cold the FHA-sea radiator FH0-sealed tank connected to the inlet pipe connection FH1-FH2-outlet; FB3-heat side connection suck down a cold end FB1-FB2-connected heat transport segment is inserted in the FU-sealed connection seawater cooling barrel; FU1-FU2-inlet and outlet FU-seawater cooling barrel by the FU0-sealed buckets connected; FAD-cold source includes the FC3-bulk terminal connected to the FD-cold refrigeration semiconductor chip connected FD1- suck up the cold end is connected sequentially FD2-FD3-gravity segment connecting the output of cold condensation seawater pump and FD4-vapor condensing chamber; FC3-scattered cold end connected to the other side of the radiator FHB-sea FH0-sealed tank connection significant outlet FH1-FH2-inlet connection; FC3-heat side down sequentially connected FC1-FC2-lose suction cold side heat seal connector is inserted segment connecting the FU-seawater cooling barrel; FU-seawater cooling FU1-FU2-inlet and outlet pipe barrel by the FU0-sealed buckets connected; VK4-chip semiconductor refrigeration power input socket FD-semiconductor cooling piece attached, DCV-charge and discharge controller connected to the DV-battery; FD3-gravity condensation pump from the K30-K31-circular wall is connected to the pump connection wafer and K32-pump connection wafer; pump connected in K31-K32-wafer and wafer-pump connection is connected to the middle of E-gravity evaporation E3-outer tube condensation inside the pump is connected to the spout and E31-E32-down spout; in K31-on disks connected to a pump connected to the upper end of the spout E31-FD4-connected to the steam room; FD4-steam Rooms include bottom of the barrel by the F41-F40-tank wall is attached, the upper lid of the F42-F44-outlet connector connected to the lower end of the inlet pipe in F43-F40-tank wall is connected to the top of the inverted cone FD5-FD50-cone top; in FD3-gravitational condensation pump freshwater lower connections F9-cone; F9-F90-freshwater cone comprises a conical bottom side is connected to the upper end of the nozzle cone F91-F93-tube is connected to the lower end of F92-000 is connected to the outlet connection - freshwater outflow of freshwater F94-valve; among F20-steam apex cone connected to the F203-F9-port connection with cone connected to the freshwater F91-cone nozzle integrally connected; in seawater AD-dual waterwheel pulse B4-C1-tube includes A-axis pump tubing bailer dig sequentially connects the B-axis pump tube connected to a pipe connected to the water side of the water pipe connected to C-input port is connected by a C2- C4-impact high tube connected C3-inclined tube connecting pipe connected to the C5-outlet port connected to the E-shaft hydroelectric connection inlet port E0-E3-drain connected to the seat connection with XF- preprocessor includes the XF0-inlet pipe connected to the XF1-filler connection XF2-outlet F ① been connected to the FY-sea water main valve connected to the Y1-tee all the way in turn connected to the F ② F80-pipe F ③ connected to FU1-inlet pipe F ④ FUA-seawater cooling barrels connected in FU0-sealed bucket is attached, with the FU2-outlet F ⑤ connection with F82-pipe F ⑥ connected to the Y2-tee connection with F84-pipe F ⑦ connection significant Y3-tee F ⑧ way connected with F85-pipe F ⑨ connected to the FHA-sea radiator FH0-sealed water tank connected to the inlet of FH1-F <img TranNum = "197" file = "FSA00000757283500021.GIF" he = "41" id = "ifm0001" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> FH2-outlet connection F <img TranNum = "198" file = "FSA00000757283500022.GIF" he = "40" id = "ifm0002" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41 "/> pipes connected to the F87-F <img TranNum =" 199 "file =" FSA00000757283500023.GIF "he =" 40 "id =" ifm0003 "img-content =" drawing "img-format =" tif "inline = "yes" orientation = "portrait" wi = "41" /> connected to the Y4-tee pipe connected to the F89-F <img TranNum = "200" file = "FSA00000757283500024.GIF" he = "41" id = "ifm0004" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connection with the Y6-tee F <img TranNum = "201 "file =" FSA00000757283500025.GIF "he =" 40 "id =" ifm0005 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> connection F72-F70-sprayed claw with a spray nozzle connected F7-F71-connected claw spray head connected; another F FY-way valve connected to the water a total of Y1-tee <img TranNum = "202" file = "FSA00000757283500026.GIF" he = "40" id = "ifm0006" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "42" /> sequentially connected FU1-F with F81-inlet pipe connected to the FUB-barrel connected to the seawater cooling FU0-sealed buckets connected <img TranNum = "203" file = "FSA00000757283500027.GIF" he = "40" id = "ifm0007" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> by FU2-outlet F <img TranNum = "204" file = "FSA00000757283500028.GIF "he =" 40 "id =" ifm0008 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> connection with the F83-pipe F < img TranNum = "205" file = "FSA00000757283500029.GIF" he = "41" id = "ifm0009" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = " 41 "/> Y3-tee pipe F ⑦ F F84-Y2-is connected to the tee connection is connected <img TranNum =" 206 "file =" FSA000007572835000210.GIF "he =" 40 "id =" ifm0010 " img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> F86-water connection is connected to Y5-tee F <img TranNum = "207 "file =" FSA000007572835000211.GIF "he =" 41 "id =" ifm0011 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 42 "/> all the way by F <img TranNum = "208" file = "FSA000007572835000212.GIF" he = "42" id = "ifm0012" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> FHB-connected to the water radiator connection with the FH0-sealed tank through the inlet pipe connection FH1-F <img TranNum = "209" file = "FSA000007572835000213.GIF" he = "41" id = " ifm0013 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 41 "/> connected to the FH2-outlet F <img TranNum =" 210 "file = "FSA000007572835000214.GIF" he = "40" id = "ifm0014" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connection with F88- pipes connected to the Y4-tee F <img TranNum = "211" file = "FSA000007572835000215.GIF" he = "44" id = "ifm0015" img-content = "drawing" img-format = "tif" inline = " yes "orientation =" portrait "wi =" 61 "/> Y5-tee F <img TranNum =" 212 "file =" FSA000007572835000216.GIF "he =" 41 "id =" ifm0016 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> Another path F <img TranNum =" 213 "file =" FSA000007572835000217.GIF "he =" 40 "id = "ifm0017" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connected to the mains through F43-F31-pipe F <img TranNum = " 214 "file =" FSA000007572835000218.GIF "he =" 41 "id =" ifm0018 "img-content =" drawing "img-format =" tif "inline =" yes "orientation =" portrait "wi =" 40 "/> connected to the steam chamber is connected FD4-F40-F43-tank wall is connected to the inlet pipe connected to the tank wall by the F40-F44-outlet F <img TranNum = "215" file = "FSA000007572835000219.GIF" he = "41" id = "ifm0019" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "40" /> connection with the F32-pipe F <img TranNum = "216" file = "FSA000007572835000220.GIF" he = "41" id = "ifm0020" img-content = "drawing" img-format = "tif" inline = "yes" orientation = "portrait" wi = "41" /> connected Y6-tee.

2. the system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration according to claim 1 and salt, is characterized in that; The dual-purpose waterwheel pulse pump of AD-comprises that by B-pump line central siphon, connecting B0-star human skull connection A-digs water ladle pump line, and B-pump line central siphon connects D-base and forms; B-pump line central siphon is connecting in turn B51-bearing and is connecting B2-human skull front end and be connected go to sea water end (W.E.) be connected outside B6-sealing bearing of B52-bearing and B4-axis with B3-human skull rear end; Between the B2-human skull front end in B-pump line central siphon stage casing and B3-human skull rear end, opening B01-centre hole and B02-centre hole; The rear end of B-pump line central siphon is B1-sealing pipe end; B2-human skull front end at B-pump line central siphon is being connected B0-star human skull with on B3-human skull rear end; On B0-star human skull outer ring, connect A-and digging water ladle pump line; A-digs water ladle pump line and comprises that by A2-pump line one end, connecting A3-water ladle connects A4-network interface, and A3-water ladle connects A5-pushing assisted plate, and the other end connects A1-gravitational force ball-valve or AL-gravity valve block; A1-gravitational force ball-valve comprises that by the A00-ball valve pipe connecting in turn, A05-upper orifice, the A04-epimere valve mouth of pipe, A01-hole, leaking section, the A02-hypomere valve mouth of pipe, A03-lower nozzle forms; In A00-ball valve pipe, placing A06-spheroid; The A-that the B0-star human skull connecting at B-pump line central siphon is connecting a circle outward digs in the middle of water ladle pump line two and is connecting A6-clamping rings circle; The B51-bearing connecting at B-pump line central siphon is being connected the D-base that D3-bearing support connects with the lower end of B52-bearing; D-base comprises by D1-seat legs and feet and D2-seat legs and feet; At D1-seat legs and feet, be connected D3-bearing support with D2-seat legs and feet top; On D2-seat legs and feet top, connecting D4-support; Go to sea water end (W.E.) connecting outside B6-sealing bearing of the B4-axis connecting at B-pump line central siphon; At B6-sealing bearing, connecting in turn the high-order pipe of C2-that the C1-interface tube of the defeated seawater pipe of C-connects outward and be connected E0-water inlet pipe mouth, E1-Striker, E2-impeller that E-shaft type hydroelectric generator connecting in turn the C3-inclined tube connecting with C4-impact tube with C5-effluent pipe mouth and connecting E3-draining base that E4-motor shaft, E5-generator, VK0-power output socket connection DCV-charging-discharging controller connecting and connect again XF-and locate in advance device.

3. the system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration according to claim 1 and salt, is characterized in that; At the bottom of the mono-vacuum-energy pump of U1-face comprises and is connecting 1-pump face by 0-pump face, on 0-pump face, connecting the 3-conical surface that 2-facies superior pyramidis is connecting, at the bottom of the 1-pump face connecting at 0-pump face, two are connecting 4-connection piece, are connecting 5-hole, mold strikes out a slice on 4-connection piece; At the bottom of U2-double pump vacuum-energy pump face comprises and connecting 1-pump face by 0-pump face, on 0-pump face, connecting 17-opening above the 16-opening cone 17-opening mold on 16-opening cone and striking out a slice; 18-side's pump line is being tightly connected in 17-opening; The 20-side's pump face being connected with top at the bottom of 19-side's pump that 18-side's pump line is being connected by bottom also seals after interior injection BB0-vacuum-energy liquid; The mono-pump vacuum-energy of FA-pump comprises that the U3-pump drain pan being connected in turn by the mono-vacuum-energy pump of U1-face connects U4-cone and connects U5-duplex pump line; U3-pump drain pan comprises that the 9-bottom surface of the 7-front cover connection being connected by 6-drain pan and the 8-opening end mold of upper end strike out one; U4-cone connects 11-cone mouth mold by 10-cone frame and strikes out one; U5-duplex pump line connects 13-coiled pipe by the 12-pump line deutostoma connecting in turn and connects 14-pump line front end connection 15-pump port lid; FAQ-double pump vacuum-energy pump comprises that the U3-pump drain pan being connected in turn by U2-double pump vacuum-energy pump face connects U4-cone and connects U5-duplex pump line; At the bottom of the 0-pump face that U2-double pump vacuum-energy pump face is connecting is in turn connecting 1-pump face, on 0-pump face, connecting in 17-opening above the 16-opening cone 17-opening on 16-opening cone and connecting 18-side's pump line; U5-duplex pump line connects 13-coiled pipe by the 12-pump line deutostoma connecting in turn and connects 14-pump line front end connection 15-pump port lid and seal after interior injection BB0-vacuum-energy liquid; U5V-electric heating pump is included in the 15-pump port lid that 14-pump line front end that U5-duplex pump line connecting connecting and is connecting F20-U type pipe and connecting in interior insertion the VK6-calrod power plug that F21-calrod is connecting; After injecting BB0-vacuum-energy liquid in U5-duplex pump line, seal; The front end that U5U-electromagnetic pump is included in outside the 14-pump line front end that U5-duplex pump line connecting is inserted in and is being connected F18-solenoid and the VK5-solenoid supply socket being connected with the upper end of 15-pump port lid outside FX-sealing cover end; After injecting BB0-vacuum-energy liquid in U5-duplex pump line, seal; U1-mono-vacuum-energy pump face or U2-double pump vacuum-energy pump face claim FA4-gravity evaporation pump, FD3-gravity dewfall pump, the FD4-steam seawater condensing chamber that FA3-radiating end, FB3-cold scattering end, FC3-cold scattering end, FD3-cold scattering end are being connected with top in the present invention; The 13-coiled pipe that U5-duplex pump line connects claims the defeated hot arc of FA2-, defeated cold section of FB2-, defeated cold section of FC2-, defeated cold section of FD2-in the present invention; The 14-pump line front end that the 13-coiled pipe that U5-duplex pump line connects connects claims that FA1-heat build-up end, FB1-suction cold junction, FC1-inhale cold junction, FD1-inhales cold junction in the present invention; F1-heat build-up electric organ comprises the F14-framework that F13-para-curve reflection shield that F12-vacuum pipe that F11-heat collector that the F10-heat build-up pump line by the FA1-heat build-up end connecting is in turn connecting is connecting is connecting is connecting outward outward outward outward; In U-shaped of F14-framework top, connecting F15-motor is connecting F16-light and regulates two-position controller connecting VK3-supply lead to connect F18-electromagnetic stove coil, F21 calrod and connecting F19, F22-supply lead and connecting the DV-store battery that DCV-charging-discharging controller connecting and connecting Y-civil power; In the bottom of F10-heat build-up pump line, connect F101-pump line cover and be connected on the L support of F14-framework, on F14-framework top, connecting the folding legs and feet of F24-; The folding legs and feet of F24-that F14-framework top is connecting are connected on F23-base; F1-heat build-up electric organ comprises the FA3-radiating end that the defeated hot arc of FA2-that connected in turn by FA1-heat build-up end is connecting; FAB-thermoelectric generator comprises the FB3-cold scattering end of the FAQ-double pump vacuum-energy pump that FV-semiconductor thermoelectric generator that the FA3-radiating end by FAQ-double pump vacuum-energy pump is connecting is in turn connecting; The 5-aperture T-bolt connecting on the 4-connection piece connecting above the 0-pump face that FA3-radiating end connects connects the 5-hole connecting on the 4-connection piece connecting above the 0-pump face of FB3-cold scattering end connection; In the 5-hole on two sides, be connected T-bolt with insertion in the middle of 5-hole; The FB3-cold scattering end that connects FAQ-double pump vacuum-energy pump is connecting FHA-seawater scatterer outward; FHA-seawater scatterer is connecting FH1-water inlet pipe by FH0-staving and is connecting FH2-rising pipe; FH0-staving, FH1-water inlet pipe, FH2-rising pipe; The VK1-thermo-electric generation power output socket that FV-semiconductor thermoelectric generator is connecting is connecting the DV-store battery that DCV-charging-discharging controller connecting and is connecting Y-civil power; The FB3-cold scattering end of AQ-double pump vacuum-energy pump is connecting in turn the defeated cold section of FB1-connecting of FB2-and is inhaling cold junction; FB1-inhales cold junction insertion and is connected in FU-seawater low-temperature receiver bucket; FU-seawater low-temperature receiver bucket is connecting FU1-water inlet pipe and FU2-rising pipe outward by FU0-staving; In FAB-thermoelectric generator outer ring, connecting Z-thermal insulation layer.

4. the system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration according to claim 1 and salt, is characterized in that; E2-180 degree revolving fragment is to stamp out under E11-upper notch and E12-recess through stamping forming E2-180 degree revolving fragment at rectangular upper and lower ends of E1-; E-gravity evaporation and condensation pump comprises that by one group of mutual 90-degree rotation of (10) E2-180 degree revolving fragment, connecting rear insertion is connected in E30-pipe; E-gravity evaporation and condensation pump comprises that by E21-revolving fragment 90-degree rotation, connecting E22-revolving fragment 90-degree rotation connects one group 10 of E23-revolving fragment 90-degree rotation connection E24-revolving fragment 90-degree rotation connection E25-revolving fragment 90-degree rotation connection E30-revolving fragments.

5. the system and device of the solidifying preparing fresh of round-the-clock seawater self-pumping generating pyrogenicity refrigeration according to claim 1 and salt, is characterized in that; F4-gentle breeze-driven generator comprises the VK2-gentle breeze-driven generator power output socket that the F42-speed-up generator of the F41-axle connection being connected in turn by F40-blade connects, and in F42-speed-up generator bottom surface, is connecting F44-montant.

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