CN212504424U - Landscape seawater desalination platform for leisure/rescue - Google Patents

Abstract

The landscape seawater desalination platform for leisure/rescue comprises a wave-resistant suspension platform, a group-type surge power generation device, a seawater atomization and vaporization device, a mist swallowing device, a multi-pipe cyclone/fiber screen condensation device, a fresh water storage and delivery device, a multidirectional power moving device and an anchor stopping device; the anti-wave suspension platform is an integrated or assembled low-resistance relief anti-wave suspension platform; the group type surge generating device is arranged around the wave-resistant suspension platform and is integrated with the platform or the platform assembly; the seawater atomization and vaporization device is arranged on the movable support at the periphery of the wave-resistant suspension platform and/or the support below the porous deck of the wave-resistant suspension platform. The utility model has the advantages of no need of pretreatment and heating or pressurization for seawater, high efficiency and low cost; the advantages of environmental protection and no secondary pollution; can provide people with a mobile platform for entertainment and rescue for a long time on the sea, and has good investment economy.

Description

Landscape seawater desalination platform for leisure/rescue

Technical Field

The utility model relates to a sea water desalination platform, concretely relates to can supply view nature sea water desalination platform of leisure rescue usefulness.

Background

Nowadays, with the improvement of the quality of life and requirements of people, offshore sightseeing leisure and recreation sports become active day by day, and offshore rescue is also important day by day, but at present, closed cruise ships and yachts are generally adopted in people's offshore sightseeing leisure and recreation sports and rescue, and daily water sources are almost all supplied by land fresh water, so far, no movable landscape offshore leisure/rescue platform is available, and no research and practice report of a landscape seawater desalination platform for leisure/rescue is available.

On the other hand, the per capita water resource amount of China is only 2200 cubic meters, which is only 1/4 on the average level in the world, and is one of the countries with the most scarce per capita fresh water resource in the world, and the fresh water resource of China is extremely unbalanced in spatial distribution, so that an obvious pattern of less east-docetaxel, less south-north, more summer-winter is formed, and the pattern is more obvious in north China, northeast, northwest and coastal areas. The coastal region is the region with the most prosperous economy, the most dense population and the most developed maritime leisure and entertainment in China, but the water shortage phenomenon in the region is increasingly serious along with the increase of population including the surge of tourism population, water source pollution, industrial and agricultural development and the increase of water for ecological environment, so that the rapid development of the economy in the coastal region is severely restricted, and the daily work and life of residents are also seriously influenced.

The development of the seawater desalination industry, which supplies fresh water to inexhaustible sea, is a powerful supplement to coastal region water resources, is an effective measure for increasing fresh water resources, and is an effective way for sustainable utilization of water resources. At present, 142 seawater desalination projects are built in China, and the daily average produced water is more than 120 million tons. The north is mainly large-scale industrial seawater desalination engineering, mainly focuses on high-water-consumption industries such as electric power, steel and the like in Tianjin, Shandong, Hebei and the like, and the south is mainly civil seawater desalination engineering which is mainly distributed in Zhejiang, Fujian, Hainan and the like and mainly takes hundred-ton-grade and thousand-ton-grade engineering.

As is known, most of the salt dissolved in seawater exists in the form of ions, which mainly include cations such as Na +, K +, Ca2+, Mg2+, Sr2+ and anions such as Cl-, SO42-, Br-, HCO 3-and F-, and the salinity of typical seawater is generally between 30 per thousand and 43 per thousand. Currently, the main modes of seawater desalination can be broadly divided into two main categories: firstly, water is directly taken out from seawater, salt is remained in the residual strong brine, and the adopted technical methods mainly comprise a distillation method, a reverse osmosis method, a freezing method, a hydrate method and a solvent extraction method. Secondly, salt is taken out from the seawater, so that the salinity of the seawater is greatly reduced to fresh water, and the adopted technical methods mainly comprise an ion exchange method, an electrodialysis method and a capacitance adsorption method. The existing various seawater desalination methods/techniques can be summarized as follows;

1. method for extracting water from seawater

1.1 distillation method

(1) Multistage flash (MSF)

The heated seawater is evaporated in a plurality of flash chambers with gradually reduced pressure in sequence, and the evaporated steam is used for heating the circulating seawater and condensing the seawater into fresh water. The device has large single machine capacity and good effluent quality, but has high construction and equipment investment, large volume, high energy consumption, higher requirement on seawater pretreatment, smaller operation elasticity of the device, high corrosion speed, and possibility of polluting finished water if leakage occurs, and is generally used for thermal power plants with available waste heat and the like. Meanwhile, the thermal distillation causes thermal pollution to the marine environment, and corrosion products of the thermal distillation have toxic action to the sea.

(2) Low temperature multiple effect distillation (LT-MED)

The heated seawater is serially operated by a plurality of evaporators, and the secondary steam evaporated in the previous effect is used as the heating steam of the next effect and is condensed into fresh water. The system has good effluent quality and large system operation elasticity, but has large equipment volume, higher equipment investment, higher requirements on corrosion and scaling, higher requirements on seawater pretreatment and high operation cost, is generally only used in places with waste heat or other heat sources, such as large-scale thermal power plants and the like, and adopts thermal distillation to cause thermal pollution to the marine environment, influence parameters such as seawater level, dissolved oxygen content and the like, and indirectly generate adverse effects on marine organisms and water quality.

(3) Vapor compression distillation (VC)

The steam generated by the heated seawater is pressurized again, the temperature of the steam is increased, and then the steam is used as the heating steam of the evaporator and condensed into fresh water. The device has the advantages of relatively compact structure and higher energy utilization rate, but the device has large volume, high requirement on the sealing property of the system, easy scaling, higher requirement on the pretreatment of seawater and high operation cost, and also has high thermal pollution to the marine environment when being used as a thermal method for treating seawater.

1.2 reverse osmosis (SWRO)

A method for desalinating fresh water by applying pressure to seawater to make the fresh water permeate through a reverse osmosis membrane. The device gets rid of the dependence on waste heat, does not need to consume steam, has large volume and is easy to automatically control, but has strict requirement on seawater pretreatment, and increases the operation cost and the occupied area; the strong brine has high energy carrying away, and the energy utilization rate is low; the operation is unstable, and the water yield is reduced and the water quality is unstable due to easy scaling; the semipermeable membrane needs to be cleaned and replaced regularly, so that the operation cost and the pollution of the chemical cleaning agent to the ocean are increased; the fresh water treatment cost is high.

1.3 freezing method

The freezing method comprises three types, namely a natural freezing method, an artificial freezing method and an exchange crystallization freezing desalting method. The natural freezing method is to freeze sea water and freeze the sea water to ice by using natural environment conditions, and the ice is melted to prepare fresh water, and the method is greatly influenced by natural environment factors such as seasons and the like. The artificial freezing method is to utilize direct or indirect heat exchange between a refrigerant or a refrigerant (n-butane, isobutane, R410A and the like) and seawater to freeze and freeze the seawater, but the artificial freezing method has the problems of larger equipment, high energy consumption in the process of recovering and reusing the refrigerant, high energy consumption in the process of melting ice, low desalting rate and the like. The exchange crystallization freezing desalination method is a heat exchange crystallization method which utilizes precooled seawater and straight-chain hydrocarbon coexisting in a solid-liquid state, and the energy consumption is high due to pressure conversion in the separation process.

1.4 hydrate method

The hydration crystal is formed by hydration agent (monofluoro dichloroethane, methane, carbon dioxide gas, etc.) and water under certain temperature and pressure, the crystal particle is easy to form compression agglomeration and is difficult to clean, and the fresh water is mixed with trace hydration agent, so the quality of the fresh water is relatively low.

1.5 solvent extraction

Extracting with an extractant (such as mixed extractant of methyl diethylamine and triethylamine) to obtain water, and separating solvent with water to obtain fresh water. The method is a liquid-liquid conversion process, and the latent heat of phase change is very small, so that the energy consumption in the process is not large, the corrosion of materials is light, and the scaling problem is not obvious. However, the selection of the extractant, the quality of the fresh water and other technical problems still exist, so the method is in the experimental research stage so far.

2. Method for removing salt from seawater

2.1 ion exchange method

The cation exchanger is used for adsorbing cations in water and releasing hydrogen ions, the anion exchanger is used for adsorbing anions in water and releasing hydroxyl ions, and the anions and the hydroxide ions are neutralized to achieve the purpose of desalting.

2.2 Electrodialysis (ED)

The process of producing fresh water by utilizing the selective permeability of the anion exchange membrane and the cation exchange membrane to the anions and the cations in the seawater and causing the salt and the moisture in the seawater to respectively move directionally under the action of the potential difference generated by the electric field. Compared with reverse osmosis, the method has the advantages of simple pretreatment on seawater, high raw water recovery rate, poor product water quality, high energy consumption and incapability of effectively removing organic matters and bacteria.

2.3 capacitive adsorption method

The method separates ions in seawater by electric double layer discharge to obtain fresh water. The method also deals with experimental research stage, and is not applied industrially.

3. Combined sea water desalination method

3.1, combination with renewable energy sources, the prior art mainly comprises:

(1) solar seawater desalination: the heat generated by solar energy is used for replacing heat sources such as steam and the like to heat and distill the seawater to dilute, the method has large loss of the latent heat of steam condensation, and simultaneously, the problems of scaling inside materials, long-term stable operation of photo-thermal materials, efficient condensation and recovery of water vapor and the like are not considered.

(2) Desalting seawater by using geothermal energy: the method mainly utilizes geothermal resources (waste oil and gas wells) and the like to convert into mechanical energy to pressurize seawater to overcome natural permeation for desalination, needs to be combined with a reverse osmosis method and a low-temperature multi-effect distillation method for application, and can generate new secondary pollution in the utilization process of the waste oil and gas wells.

(3) Wind energy/ocean energy sea water desalination: the seawater desalination method mainly utilizes mechanical energy generated by wind power or mechanical energy converted by tidal energy, wave energy, temperature difference energy and the like in the ocean to pressurize the seawater so as to overcome natural permeation to dilute the seawater, and needs to be combined with a mainstream seawater desalination method for application.

3.2 methods themselves or combinations between methods

Combinations of the processes themselves, such as multistage, reverse osmosis or electrodialysis; the combination of the methods such as the combination of multi-stage flash evaporation and multi-effect evaporation, the combination of nanofiltration, reverse osmosis and multi-stage flash evaporation and the like can improve the recovery rate or the utilization rate of heat and electricity and reduce the cost, but the defects or the shortcomings of the methods cannot be overcome.

Obviously, the existing seawater desalination technologies have the technical problems of high construction cost, large equipment floor area, high requirement on seawater pretreatment, complex process, high energy consumption, high water production cost, low fresh water separation efficiency, low fresh water effluent quality, influence on marine ecological environment and the like.

In addition, the high-frequency oscillation of the fluid is excited by using the oscillation source to generate various ultrasonic effects, such as mechanical effect to destroy the acting force among liquid molecules, thermal effect to enable the molecules to vibrate violently and rub violently to generate heat, cavitation effect to enable a large amount of small bubbles to be generated in the liquid and to expand and burst rapidly, and thixotropic effect to cause the change of the biological tissue combination state, so that the liquid is atomized or bacteria are killed rapidly, but the ultrasonic oscillation method and other methods are mainly used for pretreatment such as scaling prevention and seawater sterilization in the aspect of seawater desalination, and no report in the aspect of research or practice of efficiently desalinating seawater by using oscillation phased array resonance is seen.

Furthermore, for the research of directly utilizing the offshore platform to desalt the seawater, the current technical scheme is limited to the seawater desalination technology utilizing the offshore solar energy, and CN 201610162547.7 provides a solar seawater desalination overwater platform for heating and distilling the seawater by solar energy. It has obvious disadvantages: firstly, the heat generated by the solar heat collecting plate only acts on the surface of seawater, the heat exchange effect is poor, and the efficiency of steam generation is low; secondly, sea wind can only blow through the main shell to cool, the actual cooling effect is very poor, and the water production efficiency is extremely low; thirdly, the pressure is increased by increasing the density of seawater, the sealing sheet is opened for draining, the density of the seawater is very high, the fresh water content is reduced, and the water inlet is intermittent, so that the evaporation efficiency of the seawater is lower, and the water making efficiency is lower; fourthly, the wind wave resistance/the survival ability of the platform are extremely poor, and the platform cannot move autonomously and only can be dragged by a ship to avoid wind waves; fifthly, the function setting of the solar seawater desalination device can be only used for solar desalination of seawater; and sixthly, the buoyancy is provided only by air remained in the main shell, so that the marine floating cage is extremely easy to sink in a complex marine environment.

To date, no research and practice report is available on landscape seawater desalination platforms for leisure/rescue.

Disclosure of Invention

The utility model aims to solve the technical problem that, overcome prior art's not enough, provide a portable, anti marine stormy wave viability strong, can directly utilize wave energy etc. to carry out the high-efficient desalination of low energy to the sea water, and the sea water need not preliminary treatment, pollution-free, low running cost to can provide the view nature sea water desalination platform of leisure rescue usefulness simultaneously.

The technical scheme adopted by the utility model for solving the technical problems is that the landscape seawater desalination platform for leisure/rescue comprises a wave-resistant suspension platform, a group-type surge power generation device, a seawater atomization and vaporization device, a mist swallowing device, a multi-pipe cyclone/fiber screen condensation device, a fresh water storage and delivery device, a multidirectional power moving device and an anchor stopping device; the anti-wave suspension platform is an integrated or assembled low-resistance relief anti-wave suspension platform; the group type surge generating device is arranged around the wave-resistant suspension platform and is integrated with the platform or the platform assembly;

the seawater atomization and vaporization device is arranged on a movable support at the periphery of the wave-resistant suspension platform and/or a support below a porous deck of the wave-resistant suspension platform, and can be dynamically adjusted to be at a proper water immersion position or be lifted up and down and/or be stored;

the mist swallowing device is arranged on the wave-resistant suspension platform in a landscape form, and the mist swallowing device in the landscape form sucks and snatchs high-concentration water vapor-containing gas in a negative pressure manner; the multi-tube cyclone/fiber wire mesh water condensation device is arranged in a cabin of the wave-resistant suspension platform and/or arranged on the platform in a landscape form, and an inlet of the multi-tube cyclone/fiber wire mesh water condensation device is communicated with an air outlet of the mist swallowing device through a pipeline;

the fresh water storing and conveying device is arranged in a bin of the wave-resisting suspension platform or on the platform, and a water inlet of the fresh water storing and conveying device is communicated with a fresh water outlet of the multi-tube cyclone/fiber screen water condensing device through a pipeline; the multidirectional power moving device is arranged at the lower part of the periphery of the wave-resistant suspension platform and/or in the suspension piece of the platform or on the platform; the anchoring device is arranged on the periphery of the wave-resistant suspension platform.

Further, the seawater atomization and vaporization device adopts an ultrasonic array atomization device and/or a high-frequency excitation atomization device and/or a spraying device; the ultrasonic array atomization device or the high-frequency excitation atomization device comprises an oscillation phased array plate and a self-lifting/containing support, wherein the oscillation phased array plate is composed of a plurality of ultrasonic sources or high-frequency excitation sources arranged according to the conventional sound wave resonance/superposition principle; the self-lifting/storage support is arranged around the wave-resisting suspension platform and/or under the porous deck of the platform.

Further, the multidirectional power moving device is a multidirectional water spraying moving device and/or a vortex propeller and/or a wind power pushing device; the multidirectional water spraying moving device comprises a water pump, an electromagnetic valve and water spraying pipes, wherein the water pump is communicated with the water inlet of the electromagnetic valve through a pipeline, the water outlet of the electromagnetic valve is connected with the water spraying pipes, and the water spraying pipes are distributed around the landscape seawater desalination platform, so that the landscape seawater desalination platform can move in any direction.

Furthermore, the wave-resisting suspension platform is an integrated or assembled marine wave-resisting suspension platform made of corrosion-resistant high-molecular polymer flexible materials and/or rigid metal materials and/or inflatable materials, and is one or more of a circle, an ellipse, a polygon, an animal shape, a mountain shape, a palace and a pavilion corridor shape.

Furthermore, the multi-tube cyclone/fiber mesh water condensation device comprises a multi-tube cyclone water condensation device and a fiber mesh water condensation device, wherein the multi-tube cyclone water condensation device consists of a plurality of cyclone tubes;

furthermore, limestone, dolomite or medical stone can be carried in the fiber screen of the fiber screen water condensing device.

Furthermore, the fresh water storage and delivery device comprises a fresh water bin and a fresh water delivery pump, wherein the fresh water delivery pump is communicated with the fresh water bin through a pipeline or is arranged in the fresh water bin by a submersible pump, and the fresh water delivery pump supplies domestic water on the wave-resisting suspension platform and delivers the fresh water in the bin to land through a pipeline.

Furthermore, the fog swallowing device comprises a landscape mechanism, a negative pressure distribution system and a fan, wherein the landscape mechanism is arranged on the platform, the negative pressure distribution system is fixed in the landscape mechanism, and the negative pressure distribution system is communicated with the fan through a pipeline.

The device further comprises an operation and control device, wherein the operation and control device is used for operating or automatically controlling the movement or the static state of the landscape seawater desalination platform and controlling the working conditions of the seawater vaporization and atomization device and the fresh water pump; the solar energy and water power generation system is also provided with a wind energy power generation device, and/or a solar power generation device, and/or other energy storage power generation devices so as to realize self-sufficiency of power utilization to the maximum extent; the landscape seawater desalination platform for leisure/rescue can be provided with a fuel kinetic energy device in the cabin or on the platform.

Further, leisure and recreation facilities, rescue devices and articles are also arranged.

The utility model discloses following positive effect has: (1) the seawater is directly vaporized and atomized by using a specific ultrasonic array resonance and/or high-frequency excitation and/or spraying device and the like in the ocean seawater, the gas containing water vapor is captured by using a mist swallowing device, the high-efficiency condensed water is obtained by using an energy-saving high-efficiency multi-tube cyclone/fiber screen water condensation device, the seawater does not need to be pretreated, and the seawater does not need to be heated or pressurized, so that the efficiency is high, and the cost is low; (2) a large amount of efficient group-type surge power generation devices, wind energy and solar power generation devices and other natural energy sources are mainly used for providing kinetic energy, so that the device has the remarkable advantages of environmental protection and no secondary pollution; (3) the novel offshore platform concept of the offshore landscape leisure entertainment and rescue is created, and is combined with the novel seawater desalination technology, so that the mobile platform for the entertainment and rescue for a long time on the sea can be provided for people, and the mobile platform has good investment economy.

Drawings

Fig. 1 is a schematic structural diagram of embodiment 1 of the present invention;

FIG. 2 is a schematic structural view of the automatic lifting support in embodiment 1 shown in FIG. 1;

FIG. 3 is a schematic structural diagram of an oscillating phased array panel of the ultrasonic wave source in a two-dimensional planar array in example 1 shown in FIG. 2;

FIG. 4 is a schematic view showing the distribution of cyclone tubes in the multi-tube cyclone condensation water apparatus of embodiment 1 shown in FIG. 1;

FIG. 5 is a schematic view showing the construction of the multi-tube cyclone water condensing apparatus in embodiment 1 of FIG. 1;

FIG. 6 is a schematic structural view of the multi-directional power moving apparatus in embodiment 1 shown in FIG. 1;

FIG. 7 is a schematic structural diagram of embodiment 2 of the present invention

FIG. 8 is a schematic diagram of the construction of the perforated deck of embodiment 1/2 of FIG. 7;

fig. 9 is a schematic structural view of embodiment 3 of the present invention.

Detailed Description

The present invention will be described in further detail with reference to the accompanying drawings and examples.

Example 1

Referring to fig. 1-6, the present embodiment includes a wave-resisting suspension platform 1, a group-type surge power generation device 2, a seawater atomization and vaporization device 3, a mist swallowing device 4, a multi-tube cyclone/fiber screen condensation device 5, a fresh water storage and delivery device 6, a multidirectional power moving device 7, an anchor stopping device 8 and a control device 9; the group type surge generating device 2 is arranged around the wave-resistant suspension platform 1, and the stability of the platform is enhanced while the power is generated by utilizing the surge kinetic energy driven by sea waves; the seawater atomization and vaporization device 2 is arranged on a support under a porous deck of the wave-resistant suspension platform 1, the seawater atomization and vaporization device can be dynamically adjusted to be in a proper water immersion position, the seawater atomization and vaporization device 3 enables seawater to be directly vaporized and atomized, and the platform is in fresh water vapor fog.

The fog swallowing device 4 is arranged on the wave-resistant suspension platform 1 in a landscape form, and the fog swallowing device 4 in the landscape form sucks and snatchs high-concentration water vapor-containing gas in a negative pressure manner; the multi-pipe cyclone/fiber wire mesh water condensation device 5 is arranged in a bin of the wave-resisting suspension platform 1, and an inlet of the multi-pipe cyclone/fiber wire mesh water condensation device 5 is communicated with an air outlet of the mist swallowing device 4 through a pipeline; the fresh water storing and conveying device 6 is arranged in the bin of the wave-resisting suspension platform 1, and a water inlet of the fresh water storing and conveying device 6 is communicated with a fresh water outlet of the multi-tube cyclone/fiber screen condensate device 5 through a pipeline; the multidirectional power moving device 7 is arranged at the lower part of the periphery of the wave-resisting suspension platform 1; the anchoring device 8 is arranged on the periphery of the wave-resistant suspension platform 1. The control device 9 is electrically connected with the group type surge generating device 2, the seawater atomization and vaporization device 3, the mist swallowing device 4, the fresh water storage and delivery device 6 and the multidirectional power moving device 7.

The wave-resistant suspension platform 1 is an assembled offshore wave-resistant platform made of suspension pieces 11 made of inflatable materials and corrosion-resistant rigid metal materials, the lower portion of the wave-resistant suspension platform is circular, and the upper portion of the wave-resistant suspension platform is pavilion-shaped.

The group type surge power generation device 2 is composed of a plurality of groups of surge power generation devices, each group comprises a plurality of surge power generation devices, and the group type surge power generation devices 2 generate power by utilizing surge kinetic energy driven by sea stormy waves, so that the kinetic energy of the stormy waves is reduced, and the stability of the platform is enhanced.

The seawater atomization and vaporization device 3 is an ultrasonic array atomization device, the ultrasonic array atomization device mainly comprises an oscillation phased array plate 31 and a self-lifting support/storage 32, and the oscillation phased array plate 31 is composed of a plurality of ultrasonic sources arranged according to a conventional sound wave resonance/superposition principle; the self-lifting/storage support 32 is arranged below the porous deck of the wave-resisting suspension platform 1, can automatically adjust the oscillation phased array to be in a proper water immersion surface to obtain the best resonance atomization effect, and can be stored to protect the device.

From lifting support/accomodating 32 including suspension 321, support 322, suspension 321 provide buoyancy for sea water atomization gasification device 3, make sea water atomization gasification device 3 suspend in the sea water to dynamic following adjustment sea water atomization gasification device 3 is in suitable water logging position according to the fluctuation of sea water, support 322 in suspension 321 fixed linking to each other for place oscillation phased array board 31.

The fog swallowing device 4 mainly comprises a landscape mechanism 41, a negative pressure distribution system 42 and a fan 43, wherein the landscape mechanism 41 is arranged on a platform, the negative pressure distribution system 42 is fixed in the landscape mechanism 41, and the negative pressure distribution system 42 is communicated with the fan 43 through a pipeline.

The multi-pipe cyclone/fiber screen water condensation device 5 mainly comprises a multi-pipe cyclone water condensation device 51 and a fiber screen water condensation device 52 which are formed by a plurality of cyclone pipes 511, wherein the cyclone pipes 511 utilize guide vanes in the pipes to enable the high-concentration vapor-containing gas in the pipes to rotate, centrifugally and gather to have the effect of separating the moisture from the air, the air flow with most of the moisture removed passes through the fiber screen water condensation device 52, and the moisture is further removed by utilizing the moisture absorption of fibers and the interception and aggregation function of the screen, so that the fresh water is efficiently obtained.

The fresh water storing and feeding device 6 mainly comprises a fresh water bin 61 and a fresh water delivery pump 62, wherein the fresh water delivery pump 63 is arranged in the fresh water bin 61 through a submersible pump, and the fresh water delivery pump 62 supplies domestic water on the wave-resistant suspension platform and can deliver fresh water in the bin to land through a pipeline.

The multidirectional power moving device 7 is a multidirectional water spraying moving device 71, the multidirectional water spraying moving device 71 mainly comprises a water pump 711, an electromagnetic valve 712 and a water spraying pipe 713, the water pump 711 is communicated with a water inlet of the electromagnetic valve through a pipeline, a water outlet of the electromagnetic valve 712 is connected with the water spraying pipe 713, and the water spraying pipe 713 is distributed around the lower portion of the anti-wave suspension platform 1, so that the landscape seawater desalination platform can move in any direction.

The control device 9 (not shown in the figure) is used for operating or automatically controlling the movement or the static state of the landscape seawater desalination platform, controlling the working conditions of the seawater vaporization and atomization device 3 and the fresh water delivery pump 52, and the like.

Example 2

Referring to fig. 7 to 8, the present embodiment is different from embodiment 1 in that:

the wave-resistant suspension platform 1 is an integrated marine wave-resistant platform made of high-molecular polymer flexible materials and is rectangular;

the seawater atomization and gasification device 3 is a high-frequency excitation atomization device, the oscillation phased array plate 31 is composed of a plurality of high-frequency excitation sources which are arranged according to the conventional sound wave resonance/superposition principle and are in a linear array, and the self-lifting support/storage 32 is a storable support which is connected with the wave-resisting suspension platform 1 through a hinge;

the landscape mechanism 41 is an animal model (sea horse) and is arranged around the wave-resistant suspension platform 1, the negative pressure distribution system 42 is communicated with the air inlet of the multi-tube cyclone water condensing device 51, the air outlet of the multi-tube cyclone water condensing device 51 is communicated with the air inlet of the fan 43, and the air outlet of the fan 43 is communicated with the air inlet of the fiber mesh water condensing device 52;

the fresh water delivery pump 52 is communicated with the fresh water bin 51 through a pipeline;

the landscape seawater desalination platform for leisure/rescue can also be provided with leisure and entertainment equipment such as tables, chairs, fishing gear and the like, and rescue articles such as first-aid kits and the like.

Example 3

Referring to fig. 9, the present embodiment is different from embodiment 1 in that:

the wave-resistant suspension platform 1 is an assembled marine wave-resistant platform made of suspension pieces 11 made of high-molecular polymer flexible materials and corrosion-resistant rigid metal materials, the whole platform is in a semi-whale shape, a storage bin 12, an equipment bin 13 and a life-saving article bin 14 are arranged below a platform deck, and a hollow rockery and a series of leisure and entertainment facilities for people are arranged on the platform.

The seawater atomization and gasification device 2 is a fixed ultrasonic array atomization device and is arranged in a hollow rockery of the wave-resistant suspension platform 1;

the landscape mechanism 41 is positioned above the seawater atomization and gasification device 2 and in the hollow rockery of the wave-resistant suspension platform 1;

the outer surface of the hollow rockery is provided with a solar power generation device.

Various modifications and variations of the present invention may be made by those skilled in the art, and they are still within the scope of the present invention, provided they are within the scope of the claims and their equivalents.

What is not described in detail in the specification is prior art that is well known to those skilled in the art.

Claims (10)

1. Landscape seawater desalination platform that can supply leisure/rescue usefulness, its characterized in that: the system comprises a wave-resistant suspension platform, a group type surge generating device, a seawater atomization and vaporization device, a mist swallowing device, a multi-pipe cyclone/fiber screen water condensation device, a fresh water storage and delivery device, a multidirectional power moving device and an anchor stopping device; the anti-wave suspension platform is an integrated or assembled low-resistance relief anti-wave suspension platform; the group type surge generating device is arranged around the wave-resistant suspension platform and is integrated with the platform or the platform assembly;

the seawater atomization and vaporization device is arranged on a movable support at the periphery of the wave-resistant suspension platform and/or a support below a porous deck of the wave-resistant suspension platform, and can be dynamically adjusted to be at a proper water immersion position or be lifted up and down and/or be stored;

the mist swallowing device is arranged on the wave-resistant suspension platform in a landscape form, and the mist swallowing device in the landscape form sucks and snatchs high-concentration water vapor-containing gas in a negative pressure manner; the multi-tube cyclone/fiber wire mesh water condensation device is arranged in a cabin of the wave-resistant suspension platform and/or arranged on the platform in a landscape form, and an inlet of the multi-tube cyclone/fiber wire mesh water condensation device is communicated with an air outlet of the mist swallowing device through a pipeline;

the fresh water storing and conveying device is arranged in a bin of the wave-resisting suspension platform or on the platform, and a water inlet of the fresh water storing and conveying device is communicated with a fresh water outlet of the multi-tube cyclone/fiber screen water condensing device through a pipeline; the multidirectional power moving device is arranged at the lower part of the periphery of the wave-resistant suspension platform and/or in the suspension piece of the platform or on the platform; the anchoring device is arranged on the periphery of the wave-resistant suspension platform.

2. The landscape seawater desalination platform for leisure/rescue according to claim 1, which is characterized in that: the seawater atomization and vaporization device adopts an ultrasonic array atomization device and/or a high-frequency excitation atomization device and/or a spraying device; the ultrasonic array atomization device or the high-frequency excitation atomization device comprises an oscillation phased array plate and a self-lifting/containing support, wherein the oscillation phased array plate is composed of a plurality of ultrasonic sources or high-frequency excitation sources arranged according to the conventional sound wave resonance/superposition principle; the self-lifting/storage support is arranged around the wave-resisting suspension platform and/or under the porous deck of the platform.

3. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the multidirectional power moving device is a multidirectional water spraying moving device and/or a vortex propulsion device and/or a wind power propulsion device; the multidirectional water spraying moving device comprises a water pump, an electromagnetic valve and water spraying pipes, wherein the water pump is communicated with the water inlet of the electromagnetic valve through a pipeline, the water outlet of the electromagnetic valve is connected with the water spraying pipes, and the water spraying pipes are distributed around the landscape seawater desalination platform, so that the landscape seawater desalination platform can move in any direction.

4. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the wave-resistant suspension platform is an integrated or assembled marine wave-resistant suspension platform made of corrosion-resistant high-molecular polymer flexible materials and/or rigid metal materials and/or inflatable materials.

5. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the multi-pipe cyclone/fiber screen water condensation device comprises a multi-pipe cyclone water condensation device and a fiber screen water condensation device, wherein the multi-pipe cyclone water condensation device and the fiber screen water condensation device are composed of a plurality of cyclone pipes.

6. The landscape seawater desalination platform for leisure/rescue according to claim 5, characterized in that: the fiber screen of the fiber screen water condensing device carries limestone, dolomite or medical stone.

7. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the fresh water storage and delivery device comprises a fresh water bin and a fresh water delivery pump, wherein the fresh water delivery pump is communicated with the fresh water bin through a pipeline or is arranged in the fresh water bin by a submersible pump, and the fresh water delivery pump supplies domestic water on the wave-resistant suspension platform and delivers the fresh water in the bin to the land by the pipeline.

8. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the fog swallowing device comprises a landscape mechanism, a negative pressure distribution system and a fan, wherein the landscape mechanism is arranged on the platform, the negative pressure distribution system is fixed in the landscape mechanism, and the negative pressure distribution system is communicated with the fan through a pipeline.

9. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: the device also comprises an operation and control device, wherein the operation and control device is used for operating or automatically controlling the movement or the static state of the landscape seawater desalination platform and controlling the working conditions of the seawater vaporization and atomization device and the fresh water pump; the solar water heater is also provided with a wind power generation device and/or a solar power generation device so as to realize self-sufficiency of power utilization to the maximum extent; the landscape seawater desalination platform for leisure/rescue can be provided with a fuel kinetic energy device in the cabin or on the platform.

10. The landscape seawater desalination platform for leisure/rescue according to claim 1 or 2, which is characterized in that: and is also provided with leisure and recreation facilities, rescue devices and articles.

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