CN105588342B - A kind of solar thermal collector and include the seawater desalination system of heat collector - Google Patents
A kind of solar thermal collector and include the seawater desalination system of heat collector Download PDFInfo
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- CN105588342B CN105588342B CN201610106689.5A CN201610106689A CN105588342B CN 105588342 B CN105588342 B CN 105588342B CN 201610106689 A CN201610106689 A CN 201610106689A CN 105588342 B CN105588342 B CN 105588342B
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/50—Solar heat collectors using working fluids the working fluids being conveyed between plates
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F1/00—Treatment of water, waste water, or sewage
- C02F1/02—Treatment of water, waste water, or sewage by heating
- C02F1/04—Treatment of water, waste water, or sewage by heating by distillation or evaporation
- C02F1/14—Treatment of water, waste water, or sewage by heating by distillation or evaporation using solar energy
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/70—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits
- F24S10/75—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits with enlarged surfaces, e.g. with protrusions or corrugations
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/70—Arrangements for concentrating solar-rays for solar heat collectors with reflectors
- F24S23/77—Arrangements for concentrating solar-rays for solar heat collectors with reflectors with flat reflective plates
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S80/00—Details, accessories or component parts of solar heat collectors not provided for in groups F24S10/00-F24S70/00
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- C—CHEMISTRY; METALLURGY
- C02—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F—TREATMENT OF WATER, WASTE WATER, SEWAGE, OR SLUDGE
- C02F2103/00—Nature of the water, waste water, sewage or sludge to be treated
- C02F2103/08—Seawater, e.g. for desalination
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/70—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits
- F24S2010/71—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits the conduits having a non-circular cross-section
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S10/00—Solar heat collectors using working fluids
- F24S10/70—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits
- F24S10/75—Solar heat collectors using working fluids the working fluids being conveyed through tubular absorbing conduits with enlarged surfaces, e.g. with protrusions or corrugations
- F24S2010/751—Special fins
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F24—HEATING; RANGES; VENTILATING
- F24S—SOLAR HEAT COLLECTORS; SOLAR HEAT SYSTEMS
- F24S23/00—Arrangements for concentrating solar-rays for solar heat collectors
- F24S23/70—Arrangements for concentrating solar-rays for solar heat collectors with reflectors
- F24S2023/87—Reflectors layout
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/124—Water desalination
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/124—Water desalination
- Y02A20/138—Water desalination using renewable energy
- Y02A20/142—Solar thermal; Photovoltaics
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02A—TECHNOLOGIES FOR ADAPTATION TO CLIMATE CHANGE
- Y02A20/00—Water conservation; Efficient water supply; Efficient water use
- Y02A20/20—Controlling water pollution; Waste water treatment
- Y02A20/208—Off-grid powered water treatment
- Y02A20/212—Solar-powered wastewater sewage treatment, e.g. spray evaporation
-
- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/40—Solar thermal energy, e.g. solar towers
- Y02E10/44—Heat exchange systems
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- Engineering & Computer Science (AREA)
- Chemical & Material Sciences (AREA)
- Life Sciences & Earth Sciences (AREA)
- Sustainable Development (AREA)
- Sustainable Energy (AREA)
- Mechanical Engineering (AREA)
- Thermal Sciences (AREA)
- Combustion & Propulsion (AREA)
- Physics & Mathematics (AREA)
- General Engineering & Computer Science (AREA)
- Dispersion Chemistry (AREA)
- Hydrology & Water Resources (AREA)
- Environmental & Geological Engineering (AREA)
- Water Supply & Treatment (AREA)
- Organic Chemistry (AREA)
- Heat Treatment Of Water, Waste Water Or Sewage (AREA)
Abstract
The invention provides a kind of solar thermal collector and include the seawater desalination system of heat collector, described in include being connected by collecting plate between thermal-collecting tube, adjacent two thermal-collecting tubes so that between multiple thermal-collecting tube and adjacent collecting plate formed tube plate structure;Described solar energy collector system includes two pieces of tube plate structures, and between described two pieces of tube plate structures, shape is at a certain angle, and the cross section of described thermal-collecting tube is rectangle, and described collecting plate connects rectangular angle.The present invention provides a kind of new heat collector and seawater desalination system, can improve the thermal absorptivity of solar energy, thus improve the desalination efficiency of seawater desalination system.
Description
Technical field
The invention belongs to field of solar energy, particularly relate to a kind of solar energy collector system.
Background technology
Along with the high speed development of modern social economy, the mankind are increasing to the demand of the energy.But coal, oil, sky
So the traditional energy storage level such as gas constantly reduce, the most in short supply, cause rising steadily of price, conventional fossil fuel causes simultaneously
Problem of environmental pollution the most serious, these development that the most significantly limit society and the raising of human life quality.The sun
Can the thermal transition solar energy profit that is that a kind of energy conversion efficiency and utilization rate are high and with low cost, can be widely popularized in the whole society
Use mode.In solar energy heat utilization device, it is important to solar radiant energy will be converted into heat energy, it is achieved the device of this conversion
It is referred to as solar thermal collector.But current solar thermal collector is all circular tube structure, solar heat can be caused in some cases
Amount cannot fully absorb.
Summary of the invention
It is desirable to provide the solar thermal collector of a kind of energy-conserving and environment-protective and include the desalinization of solar thermal collector
System, improves the ability to work of solar seawater desalination.
To achieve these goals, technical scheme is as follows: a kind of solar thermal collector, including thermal-collecting tube, instead
Penetrate mirror and collecting plate, connected by collecting plate between two adjacent thermal-collecting tubes, so that multiple thermal-collecting tube and adjacent thermal-arrest
Tube plate structure is formed between plate;Described solar energy collector system includes two pieces of tube plate structures, between described two pieces of tube plate structures
Shape is at a certain angle, and described angle direction is relative with the direction of the circular arc line structural bending of reflecting mirror, the focus position of reflecting mirror
Between the angle that tube plate structure is formed, the cross section of described thermal-collecting tube is rectangle, and described collecting plate connects rectangle
Angle.
As preferably, the cross section of described thermal-collecting tube is square.
As preferably, arranging inner fin inside described thermal-collecting tube, described inner fin connects rectangular diagonal angle, described interior wing
Sheet will be divided into multiple passage aisle inside thermal-collecting tube, arranges intercommunicating pore on inner fin, so that adjacent passage aisle communicates with each other.
As preferably, the described a length of L of foursquare inner edge, the radius r of described intercommunicating pore are adjacent on described same fin
Distance between the intercommunicating pore center of circle is l, meets following relation:
l/L*10=a*ln(r/L*10)+b;
Wherein ln is logarithmic function, and a, b are parameters, 1.5 < a < 1.6,2.9 <b < 3.0;
0.34<l/L<0.38;
0.14<r/L<0.17;
30mm<L<120mm;
5mm<r<17mm。
As preferably, 15mm < l < 45mm.
A kind of solar seawater desalination system, described system includes heat collector and sea water desalinating unit thereof, described heat collector
Being connected by pipeline with between heat utilization device, described heat collector is heat collector noted earlier.
As preferably, described sea water desalinating unit includes vaporization chamber, arranges liquid distributor, wherein, solar energy collection in vaporization chamber
Hot device heating hot water enter vaporization chamber, in vaporization chamber after the seawater spraying heat exchange of liquid distributor, enter back into plate-type heat-exchange
Sea water in device, with plate type heat exchanger carries out heat exchange, is then recycled back into heating in heat collector, described plate type heat exchanger
Sea water after middle heat exchange enters the liquid distributor in vaporization chamber.
As preferably, heat collector recirculated water is stored in cyclic water tank, described cyclic water tank be arranged on plate type heat exchanger and
Between heat collector.
Compared with prior art, solar water appliance of the present invention has a following advantage:
1) provide the square tube thermal-collecting tube solar thermal collector of a kind of Novel structure, the thermal-arrest of pipe heat collector can be avoided
Blind spot, improves body sun energy heat absorption efficiency.
2) by offering intercommunicating pore inside thermal-collecting tube, while ensureing to improve heat exchange efficiency, decrease in thermal-collecting tube
Flow resistance.
3) changed by the rule of the area of the through hole in thermal-collecting tube, reach optimum Heat-collecting effect and flow resistance.
4) present invention passes through test of many times, in the case of ensureing that heat exchange amount maximum and flow resistance meet requirement,
To an optimum solar thermal collector optimum results, and verified by test, thus demonstrated the accurate of result
Property.
5) present invention proposes a kind of new-type solar seawater desalination system and device, improves desalinization rate.
Accompanying drawing explanation
Fig. 1 is the schematic diagram of Solar Energy Heat Utilization System of the present invention;
Fig. 2 is the structural representation of solar thermal collector of the present invention;
Fig. 3 is thermal-collecting tube cross-sectional structure schematic diagram of the present invention;
Fig. 4 is inner fin intercommunicating pore distribution schematic diagram of the present invention;
Fig. 5 is inner fin intercommunicating pore stagger arrangement distribution schematic diagram of the present invention;
Fig. 6 is square dimensions schematic diagram in thermal-collecting tube of the present invention;
Fig. 7 is solar heat-preservation and desalinization parallel system schematic flow sheet;
Fig. 8 is the schematic diagram of solar seawater desalination control system;
Fig. 9 is sea water desalinating unit system schematic;
Figure 10 is rectangular tube and pipe contrast schematic diagram.
Reference is as follows:
1, solar thermal collector 2, external auxiliary heating 3, water circulating pump 4, cyclic water tank 5, circulating cooling make-up water pump 6,
Plate type heat exchanger 7, shower tray 8, one-level vaporization chamber 9,10, three grades, dual evaporation room vaporization chamber 11, fresh-water tank 12, fresh water
Draining pump 13, concentrated seawater case 14, concentrated seawater draining pump 15, seawater preheating heat exchanger 16, sea water intake pump 17 reflecting mirror,
18 thermal-collecting tubes, 19 collecting plates, 20 headers, 21 headers, 22 heat collector oral siphons, 23 heat collector outlets, heat utilization device 24, interior
Fin 25, intercommunicating pore 26, passage aisle 27, thermophore 28, sea water desalinating unit 29, valve 30, valve 31, temperature sensor 32,
Accumulator inlet pipe 33, outlet pipeline 34, water return pipeline 36, valve 37, temperature sensor 38, water tank 39, outlet 40, entrance
Pipe 41, temperature sensor 42, outlet valve 43, inlet tube valve 44, central controller 45 valve 46.
Detailed description of the invention
Below in conjunction with the accompanying drawings the detailed description of the invention of the present invention is described in detail.
Fig. 1 illustrates a kind of solar energy collector system, and described system includes heat collector 1 and heat utilization device 24 thereof, institute
State and be connected by pipeline between heat collector 1 with heat utilization device 24.
Described collector structure as in figure 2 it is shown, include thermal-collecting tube 18, reflecting mirror 17 and collecting plate 19, two adjacent collection
Connected by collecting plate 19 between heat pipe 18, so that forming tube sheet knot between multiple thermal-collecting tube 18 and adjacent collecting plate 19
Structure;Described solar energy collector system includes two pieces of tube plate structures, and between described two pieces of tube plate structures, shape is at a certain angle, institute
Stating angle direction relative with the direction of the circular arc line structural bending of reflecting mirror, focus D of reflecting mirror 17 is positioned at tube plate structure and is formed
Angle between.
As an improvement, the cross section of described thermal-collecting tube 18 is rectangle, and described collecting plate 19 connects rectangle
Angle.
Prior art the most all uses circular tube structure, but finds in practice to use circular tube structure, for two pipes
Spacing closer time because the distance between two close circular arcs is the least so that the part that two pipes are adjacent cannot
Absorbing solar energy fully, as described in Figure 10, if irradiated or reflection from bottom or top, dash area therein may
Illumination cannot be obtained, thus cause thermal-collecting tube local to absorb heat uneven, easily cause the damage of thermal-collecting tube.And the present invention is by setting
Putting thermal-collecting tube cross section is rhs-structure, the shortcoming overcoming circular tube structure so that have between adjacent thermal-collecting tube 18 relatively
Space more for pipe, irradiates from top and bottom is reflected so that solar energy can reflect into, thus reaches heat absorption
Uniformly, from other angle reflections, for pipe, it is also possible to reach to absorb the purpose of more heat.
As preferably, the cross section of described thermal-collecting tube 18 is square.
Traditional heat collector is all to be set directly in focus by thermal-collecting tube, and once position offsets, then heat is the most not
Can thermal-arrest in thermal-collecting tube, by said structure, sunlight, at reflecting mirror 17, reflexes to tube sheet by reflecting mirror 17 and ties
Structure, by the thermal-collecting tube 18 in heat thermal-arrest to tube plate structure.By this structure, even if because installation or operation problem are led
Cause tube plate structure position to change, then solar energy still can thermal-arrest in thermal-collecting tube 18, thus avoid thermal loss;Simultaneously because of
It is all that thermal-collecting tube is set directly in focus for traditional heat collector, causes thermal-collecting tube hot-spot, cause thermal-collecting tube local
Losing excessive, the life-span is too short, even causes thermal-collecting tube over-heat inside, produces superheated steam, is full of whole thermal-collecting tube, causes thermal-arrest
Pipe internal pressure is excessive, damages thermal-collecting tube, and takes the structure of the application, both can sufficiently have been absorbed by heat, again can be by
The dispersion that heat is relative, it is to avoid heat is excessively concentrated so that overall thermal-collecting tube heat absorption uniformly, extends the service life of thermal-collecting tube.
As one preferably, focus D of reflecting mirror 17 is positioned on the midpoint of two pieces of tube plate structure least significant end lines.By upper
State setting, it is ensured that absorb solar energy to the full extent, it is to avoid solar energy loses because of focal shift, also ensure that simultaneously
Platy structure is likely to reduced the irradiation blocked sunlight on reflecting mirror 17 as far as possible.It is experimentally confirmed, uses said structure, too
The absorbent effect of sun is best.
As preferably, the cross-sectional area of thermal-collecting tube differs.Along the middle part (i.e. extreme higher position) of tube plate structure to both sides
On extreme lower position (i.e. Fig. 2 thermal-collecting tube A is to B, C direction) bearing of trend, the cross-sectional area of thermal-collecting tube is increasing.Send out in an experiment
Existing, extend from middle part to both sides, caloric receptivity gradually rises, and is because the stop of tube plate structure by analyzing main cause, leads
It is heated in the middle part of cause minimum, and extends to both sides from middle part, absorb heat and gradually rise.By the continuous change of thermal-collecting tube cross-sectional area
Greatly, the discharge of bottom can be increased, so that being heated evenly of water in whole thermal-collecting tube, it is to avoid both sides temperature too high and in
Between temperature too low.The material that so can also avoid the thermal-collecting tube of centre is at high temperature easily damaged, and can keep whole
The homogeneous temperature of thermal-collecting tube, increases the service life.
As preferably, along tube plate structure middle part (i.e. extreme higher position) to both sides extreme lower position (i.e. Fig. 2 thermal-collecting tube A to
B, C direction) on bearing of trend, the amplitude that thermal-collecting tube cross-sectional area increases tapers into.Find in an experiment, for heat absorption
Amount, along the middle part (i.e. extreme higher position) of tube plate structure to both sides extreme lower position (i.e. Fig. 2 thermal-collecting tube A is to B, C direction) extension side
Amplification upwards is gradually successively decreased, and therefore caliber has done such change, to meet corresponding requirement.
As preferably, maximum cross-sectional area is less than 1.22 with the ratio of minimum cross-sectional area.
As preferably, the lower wall surface (face relative with reflecting mirror 17) of tube plate structure is provided for the convex of augmentation of heat transfer
Rise, to strengthen the absorption to solar energy.Along tube plate structure middle part (i.e. extreme higher position) to both sides extreme lower position (i.e. Fig. 2 collect
Heat pipe A is to B, C direction) on bearing of trend, the height of projection of the lower wall surface of thermal-collecting tube 18 is more and more higher.Find in an experiment, from
Middle part extends to both sides, and caloric receptivity gradually rises, and is because the stop of tube plate structure by analyzing main cause, causes middle part
It is heated minimum, and extends to both sides from middle part, absorb heat and gradually rise.By the continuous rising of height of projection, can make
Being heated evenly of water in whole thermal-collecting tube 18, it is to avoid both sides temperature is too high and medium temperature is too low.In so can also avoiding
Between the material of thermal-collecting tube be at high temperature easily damaged, the homogeneous temperature of whole thermal-collecting tube can be kept, extend and use the longevity
Life.
As preferably, along the link position (i.e. the middle part of tube plate structure) of two pieces of tube plate structures to both sides (i.e. Fig. 2 thermal-arrest
Pipe A is to B, C direction) extend, the density of protrusions of the lower wall surface of thermal-collecting tube 18 is more and more higher.Main cause be middle part be heated minimum,
And extend to both sides from middle part, absorb heat and gradually rise.By the continuous rising of density of protrusions, so that whole thermal-arrest
In pipe 18, water is heated evenly, it is to avoid medium temperature is too low and both sides temperature is too high.So can also avoid the thermal-collecting tube of centre
The material of 18 is at high temperature easily damaged, and can keep the homogeneous temperature of whole thermal-collecting tube, increase the service life.
As preferably, the outer wall of thermal-collecting tube 18 can arrange outer fin, such as, can arrange straight fins or helical fin,
The outer fin height of different thermal-collecting tubes is different, along the link position (i.e. the middle part of tube plate structure) of two pieces of tube plate structures to both sides
(i.e. Fig. 2 thermal-collecting tube A is to B, C direction) extends, and the height of outer fin gradually decreases.Main cause is and above arranges the former of projection
Because of identical.
As preferably, arranging inner fin 25 inside described thermal-collecting tube, described inner fin 25 connects rectangular diagonal angle, such as figure
Shown in 3.Described inner fin 25 is divided into multiple passage aisle 27 by internal for thermal-collecting tube 18, arranges intercommunicating pore 26 on inner fin, thus
Adjacent passage aisle 27 is made to communicate with each other.
By arranging inner fin 25, it is divided into multiple passage aisle 27, further augmentation of heat transfer, but phase by internal for thermal-collecting tube 18
The pressure of the fluid flowing answered increases.By arranging intercommunicating pore 26, it is ensured that the adjacent connection between passage aisle 27, so that
Fluid in the passage aisle that pressure is big can flow in the passage aisle that neighbouring pressure is little, and solving the inside of condensation end, each is little
The problem that runner 27 pressure is uneven and local pressure is excessive, thus promote the fluid abundant flowing in heat exchanger channels,
Simultaneously by the setting of intercommunicating pore 27, also reduce the pressure within thermal-collecting tube, improve heat exchange efficiency, also improve collection simultaneously
The service life of heat pipe.
Preferably, the flow direction of fluid in thermal-collecting tube 18, the area of described intercommunicating pore 27 constantly increases.
Described intercommunicating pore 26 is circular configuration, the flow direction of fluid in thermal-collecting tube 18, described circular configuration
Radius constantly increases.
Because the flow direction of fluid in thermal-collecting tube 18, the fluid in thermal-collecting tube 18 constantly absorbs heat and even evaporates,
Hence in so that the pressure of thermal-collecting tube constantly increases, and because the existence of intercommunicating pore 26 so that the pressure within thermal-collecting tube 18
Distribution is more and more uniform, and therefore the area of intercommunicating pore needs very big, constantly becomes big by arranging, so that ensureing heat pipe
In the case of the most even pressure of internal pressure, increase heat exchange area by the change of intercommunicating pore area, thus improve heat exchange effect
Rate.
Preferably, the flow direction of fluid in thermal-collecting tube 18, the width that the area of described intercommunicating pore 26 constantly increases
Degree is continuously increased.By being arranged such, also it is the Changing Pattern meeting flowing pressure, while reducing flow resistance further,
Improve heat exchange efficiency.By being arranged such, by being to test the heat exchange efficiency finding to improve about 9%, resistance is basic simultaneously
Keep constant.
Preferably, the flow direction of fluid in thermal-collecting tube 18, the distributed quantity of intercommunicating pore 26 gets more and more, further
Preferably, the amplitude that described intercommunicating pore quantity 26 constantly increases is continuously increased.
Reduce principle by the Distribution Principle of above-mentioned quantity and area identical, identical with intercommunicating pore quantity compared with, logical
Cross distributed number to reduce circulation area.
Finding in actual experiment, the area of intercommunicating pore 26 can not be too small, too small if can cause the increase of flow resistance,
Thus causing weakening of heat exchange, the area of intercommunicating pore 26 can not be excessive, and area is excessive, can cause the minimizing of heat exchange area, thus
Reduce heat transfer effect.Equally, the cross-sectional area of thermal-collecting tube 18 can not be excessive, excessive causes in tube plate structure unit length distribution
Heat exchanger tube is very few, again results in heat transfer effect and is deteriorated, and thermal-collecting tube flow area can not be too small, and too small meeting causes flow resistance to increase
Add, thus cause heat transfer effect to be deteriorated.Therefore between intercommunicating pore 26 with thermal-collecting tube cross-sectional area and adjacent intercommunicating pore 26 thereof
Distance must is fulfilled for certain requirement.
Therefore, the present invention is thousands of the numerical simulations by multiple various sizes of heat collectors and test data,
Meet in the case of industrial requirements pressure-bearing (below 10MPa), in the case of realizing maximum heat exchange amount, the optimal thermal-arrest summed up
The dimensionally-optimised relation of device.
The present invention be heat collector 18 cross section be carry out under square dimensionally-optimised.
The described foursquare interior length of side (the most foursquare outer length of side deducts wall thickness) is L, the radius r of described intercommunicating pore, institute
Stating the distance between intercommunicating pore adjacent on same fin is l, meets following relation:
l/L*10=a*ln(r/L*10)+b;
Wherein ln is logarithmic function, and a, b are parameters, 1.5 < a < 1.6,2.9 <b < 3.0;
0.34<l/L<0.38;
0.14<r/L<0.17;
30mm<L<120mm;
5mm<r<17mm。
Wherein, l is equal to the distance between adjacent intercommunicating pore 26 center of circle.Left and right as shown in Figure 4,5 is adjacent and neighbouring
The intercommunicating pore center of circle between distance.
Further preferably, 15mm < l < 45mm.
Preferably, along with the increase of r/L, described a, b increase.
As preferably, a=1.57, b=2.93.
As preferably, as shown in Figure 4,5, each inner fin arranges multiple rows of intercommunicating pore 26, as it is shown in figure 5, the plurality of
Intercommunicating pore 26 is staggered arrangement structure.Connect structure by staggered arrangement, heat exchange can be improved further, reduce pressure.
As preferably, heat utilization device 24 can be thermophore 28, it is also possible to be sea water desalinating unit as shown in Figure 9
29.Of course, it is possible to be thermophore 28 and sea water desalinating unit 29 parallel connection, as shown in Figure 7.Fig. 7 illustrates solar thermal collection system
A new embodiment.As it is shown in fig. 7, solar energy collector system includes that two thermophores being in parallel mutually 28 and sea water are light
Gasifying device 29.
Solar energy collector system as shown in Figure 7, described system includes heat collector 1, thermophore 28, sea water desalinating unit
29, valve 30, valve 31, valve 37, temperature sensor 32, described heat collector 1 connects formation closed circuit, collection with thermophore 28
Hot device 1 connects formation closed circuit with sea water desalinating unit 29, and the pipeline at thermophore 28 and sea water desalinating unit 29 place is in parallel,
Heat collector 1 absorbs solar energy, the water in heating heat collector 1, and the water after heating respectively enters thermophore 28 by outlet pipeline 34
With sea water desalinating unit 29, the water flowed out in thermophore 28 and sea water desalinating unit 29 is entering heat collector through water return pipeline 36
Heat exchange is carried out in 1.
Certainly thermophore and and sea water desalinating unit 29 other heat utilization device can be used to replace.
In said system, in thermophore 28, carry out accumulation of heat simultaneously by solar energy, desalinization can be carried out.Certainly,
Sea water desalinating unit and thermophore can with independent operating, or isolated operation one of them, wherein Fig. 9 is exactly isolated operation sea water
Desalting plant.
As it is shown in fig. 7, valve 30 is arranged on outlet pipe, enter thermophore 28 and sea water desalinating unit 29 for controlling
Total water yield, valve 31 is arranged on the position of the inlet tube of the pipeline at sea water desalinating unit 29 place, is used for controlling to enter sea water
The flow of the water of desalting plant 29, valve 37 is arranged on the position of the inlet tube 33 of the pipeline at thermophore 28 place, is used for controlling
Entering the flow of the water of thermophore 28, temperature sensor 32 is arranged on the position of the entrance of sea water desalinating unit 29, is used for surveying
Amount enters the temperature of the water of sea water desalinating unit 29.Described system also includes central controller, described central controller and valve
30, valve 31, valve 37, temperature sensor 32 carry out data cube computation.
Preferably, when the temperature that temperature sensor 32 is measured is less than certain temperature when, central controller controls valve
Door 31 strengthens aperture, controls valve 37 simultaneously and reduces aperture, carries with the flow of the hot water of increasing entrance sea water desalinating unit 29
The ability to work of high sea water desalinating unit.When the temperature that temperature sensor 32 is measured is higher than certain temperature when, central authorities' control
Device processed controls valve 31 and reduces aperture, controls valve 37 simultaneously and strengthens aperture, to reduce the hot water entering sea water desalinating unit 29
Flow reduce the ability to work of sea water desalinating unit.By above-mentioned control, it is ensured that the sea of sea water desalinating unit 29
Water desalination the fresh water rate that goes out be held essentially constant, it is to avoid too much or very few, and can also heat have unnecessary in the case of, will
More hot water is stored by thermophore 28.
When the temperature that temperature sensor 32 is measured is reduced to a certain degree when, the now external sea water of sea water desalinating unit
The ability of desalination can be deteriorated, it is impossible to meeting normal demand, this shows that the thermal-arrest ability of solar thermal collector also goes wrong, example
It not the most very strong such as sunlight, or the when that not having the sun in the evening, now valve 30 can be automatically switched off, valve 31 and valve 37
Can fully open, the pipeline at thermophore and sea water desalinating unit place forms a circulation line, and water enters thermophore, thermophore
The heat energy of storage heats entering water in thermophore, and the water of heating enters in sea water desalinating unit 29 and carries out desalinization.
By above-mentioned operation, the heat-sinking capability of sea water desalinating unit 29 can met sunray is strong when,
After i.e. meeting user's radiating requirements, unnecessary heat is carried out accumulation of heat by thermophore 28, at solar thermal collector 1 for heat energy
In the case of hypodynamic, utilize the energy heats recirculated water that thermophore stores, to meet the demand of sea water desalinating unit 29.So
Solar energy can be made full use of, it is to avoid the waste of too much heat.
As preferably, the pipeline of sea water desalinating unit 29 also sets up ancillary heating equipment 2, as it is shown in figure 9, desalinization
Water in device 29 pipeline flows through assisted heating device advancing into of sea water desalinating unit 29.Described ancillary heating equipment 2
Automatically heating is started according to the temperature of the water flowed through in assisted heating device 2.
Preferably, assisted heating device 2 can be electric heater, hot-water boiler or other heat exchangers, wherein Fig. 9 exhibition
Show a heat-exchanger rig.The Main Function of electric heater or hot-water boiler is the effect playing auxiliary heating, such as, work as utilization
The water of solar energy heating is not reaching to predetermined temperature, and this is to start electric heater or hot-water boiler.
Described electric heater and/or hot-water boiler and/or heat exchanger also include that control system, described control system include surveying
The temperature sensor of amount temperature and central controller, electric heater and/or hot-water boiler and/or heat exchanger are according to entering electrical heating
The temperature of the water of device and hot-water boiler and/or heat exchanger starts automatically, heats hot water.Carry out below for electric heater
Explanation.
Temperature sensor is for measuring the temperature of the water entering electric heater, and central controller is for controlling electric heater
Heating power.When the inflow temperature measured is less than temperature a, electric heater starts heating, and heats with power A;Work as heat
When the inflow temperature measured is less than temperature b lower than temperature a, electric heater heats with the power B higher than power A;Work as survey
When the inflow temperature of amount is less than temperature c lower than temperature b, electric heater heats with the power C higher than power B;Work as measurement
Inflow temperature less than lower than temperature c temperature d time, electric heater heats with the power D higher than power C;When measure
When inflow temperature is less than temperature e lower than temperature d, electric heater heats with the power E higher than power D.
Of course, it is possible to select, in order to increase the accuracy measuring temperature, can set at the water outlet of electric heater
Put another temperature sensor, calculated the startup of electric heater by the meansigma methods of the temperature of the measurement of two temperature sensors
Power.
For boiler, automatic ignition device is set.When the temperature of the water entering boiler measured is less than certain temperature
The when of spending, boiler heats with regard to starting ignition device.When the temperature of the water measured reaches certain temperature when, the most just
Stop heating.
Of course, it is possible to select, in order to increase the accuracy measuring temperature, can arrange separately at the water outlet of boiler
One temperature sensor, calculates the startup merit of electric heater by the meansigma methods of the temperature of the measurement of two temperature sensors
Rate.
Certainly as preferably, a heat exchanger can be set as ancillary heating equipment, as shown in Figure 9.Heat exchanger provides
Thermal source and the water entering sea water desalinating unit 29 carry out heat exchange, and described heat exchanger automatically provides heat according to the water temperature entering heat exchanger
Source carries out heat exchange.If the temperature measuring the water entering heat exchanger is less than certain temperature, central controller controls is changed
Hot device provides thermal source heat hot water.When the temperature of the water measured reaches certain temperature when, then just stop providing thermal source.
Fig. 8 illustrates the detailed description of the invention of a further improvement of solar thermal collector device.For not mentioning
Feature identical with embodiment above.Preferably, also include that water tank 39, described thermal-collecting tube are loop circuit heat pipes, loop circuit heat pipe
Condensation end be arranged in solar water container 39.Heat collector absorbs the heat of solar energy, the evaporation ends of reheat loop heat pipe, evaporation
The working fluid of end, through being recycled into the condensation end of loop circuit heat pipe, carries out heat release at condensation end, the water in heating water tank.Cold
The heat release of solidifying end is re-circulated into the evaporation ends of heat pipe and heats after completing.As preferably, wherein the evaporation ends of loop circuit heat pipe is
Heat collector.
As shown in Figure 8, electric heater unit can be set in water tank, when the leaving water temperature of water tank is less than certain numerical value
Time, electric heater unit can be started.The present invention realizes the Based Intelligent Control to seawater desalination system in several ways.
As improving one, in described water tank 39, temperature sensor is set, for measuring the temperature of the water in water tank 39.Water
Inlet tube valve 44 and outlet valve 43 it is respectively provided with on the inlet tube 41 of case 39 and outlet 40, described temperature sensor,
Inlet tube valve 44 and outlet valve 43 and central controller 45 data cube computation.Central controller 45 is surveyed according to temperature sensor
The temperature of amount controls inlet tube valve 44 and the opening and closing of outlet valve 43 and the size of aperture.
If the temperature of the water in temperature sensor measurement water tank 39 is less than the numerical value of lower limit, then central controller 45 controls
Valve 43,44 is automatically switched off, thus ensures that the water in water tank 39 continues heat temperature raising;If the temperature of the water in the water tank 39 measured
Degree exceedes the numerical value of the upper limit, then central controller 45 controls valve 43,44 and automatically opens up.By above-mentioned measure, it is possible to and ensure
The temperature of the water of water tank 39 output keeps uniform temperature such that it is able to reach utilizable temperature.
As preferably, in described water tank 39, multiple temperature sensor is set, measures water by multiple temperature sensors
Temperature.
As preferably, central controller 45 carrys out control valve by the meansigma methods of the temperature of the water of multiple temperature sensor measurements
The opening and closing of door 43,22.
As preferably, central controller 45 carrys out control valve by the minimum of the temperature of the water of multiple temperature sensor measurements
The opening and closing of door 43,22.By taking minimum, it is possible to ensure that the temperature of the water of all positions in water tank 39 can reach sea
The utilizable temperature of water desalination apparatus.
As preferably, at least one described temperature sensor is the position of close tank entry pipe 41 in being arranged on water tank 39
Put.
As preferably, at least one described temperature sensor is the position of close vessel outlet 40 in being arranged on water tank 39
Put.
Improving two as one, described central controller 45 is ensured by the size controlling the aperture of valve 43,44
Leaving water temperature in water tank reaches steady state value.I.e. enter water tank 39 by regulation and the flow said leaving water tank 39 adjusts water
The temperature of the water outlet of case 39.
Outlet pipe temp sensor 42, described outlet temperature sensor 42 and central authorities are set on described tank outlet pipeline 17
Controller 45 data cube computation, central controller 45 controls inlet tube valve 44 according to the temperature that temperature sensor 42 is measured and goes out
The opening and closing of mouth tube valve 43 and the size of aperture.
If the temperature of the water of the outlet 19 that temperature sensor 42 is measured is less than the numerical value of lower limit, then central controller 45
The aperture controlling valve 43 increases, and reduces the aperture of valve 44, so that the water entered in water tank 39 reduces so that leave water
Water in case 39 increases, so that the discharge reduction in water tank 39.The temperature of water in water tank 39 is improved by the minimizing of the water yield
Degree, thus improve the outlet temperature of water tank 39.On the contrary, the temperature of the water of the outlet 19 that temperature sensor 42 is measured is higher than the upper limit
Numerical value, then central controller 45 control valve 43 aperture reduce, increase valve 44 aperture so that enter water tank 39
Interior water increases so that leaves the water in water tank 39 and reduces, so that the water yield in water tank 39 increases.By the increase of the water yield
Reduce the temperature of water in water tank 39, thus reduce the outlet temperature of water tank 39.By above-mentioned measure, it is possible to and ensure water tank 39
The temperature of the water of output keeps within the specific limits such that it is able to reach the utilizable temperature of sea water desalinating unit 29.
As preferably, described outlet 40 arranges multiple temperature sensor 42, is surveyed by multiple temperature sensors 42
The temperature of the water of water-masuring box outlet pipe.
As preferably, the meansigma methods of the temperature of the water that central controller 45 is measured by multiple temperature sensors 42 controls
The size of the aperture of valve 43,44.
As preferably, the minimum of the temperature of the water that central controller 45 is measured by multiple temperature sensors 42 controls
The aperture of valve 43,44.By taking minimum, it is possible to the further accuracy of data.
As preferably, at least one described temperature sensor is arranged on the outlet 40 position near water tank 39.
As preferably, limit value deducts lower numerical limit and is 5-10 degree Celsius, preferably 6-8 degree Celsius.
As the further improvement of improvement two, lower referred to as improvement three, carry out control valve by the temperature of water in measurement water tank 39
The opening and closing of door 43,44.
If the temperature of the water of the water tank 39 that temperature sensor 42 is measured is less than the numerical value of lower limit, then central controller 45 is controlled
The aperture of valve 43 processed increases, and reduces the aperture of valve 44, so that the water entered in water tank 39 reduces so that leave water tank
Water in 39 increases, so that the discharge reduction in water tank 39.The temperature of water in water tank 39 is improved by the minimizing of the water yield,
Thus improve the outlet temperature of water tank 39.On the contrary, the temperature of the water in the water tank 39 that temperature sensor 42 is measured is higher than the upper limit
Numerical value, then central controller 45 controls the aperture minimizing of valve 43, increases the aperture of valve 44, so that enter in water tank 39
Water increase so that leave water in water tank 39 and reduce, so that the water yield in water tank 39 increases.Come by the increase of the water yield
The temperature of water in reduction water tank 39, thus reduce the outlet temperature of water tank 39.By above-mentioned measure, it is possible to and ensure that water tank 39 is defeated
The temperature of the water gone out keeps within the specific limits such that it is able to reach the utilizable temperature of sea water desalinating unit.
As preferably, in described water tank 39, multiple temperature sensor is set, measures water by multiple temperature sensors
Temperature.
As preferably, central controller 45 carrys out control valve by the meansigma methods of the temperature of the water of multiple temperature sensor measurements
The aperture of door 43,22.
As preferably, central controller 45 carrys out control valve by the minimum of the temperature of the water of multiple temperature sensor measurements
The aperture of door 43,22.By taking minimum, it is possible to the temperature of the water of all positions in guarantee water tank 39 can reach can
With the temperature utilized.
As preferably, at least one described temperature sensor is the position of close tank entry pipe 41 in being arranged on water tank 39
Put.
As preferably, at least one described temperature sensor is the position of close vessel outlet 40 in being arranged on water tank 39
Put.
As preferably, limit value deducts lower numerical limit and is 8-13 degree Celsius, preferably 9-11 degree Celsius.
As improving four, water-level gauge, described water-level gauge and central controller 45 data cube computation are set in described water tank 39.
The height of central controller level monitoring thus control the size of the aperture of valve 43,44.
By the height of level monitoring, it is to avoid the water level in water tank is too low, thus thermal-collecting tube release end of heat is caused to dispel the heat,
Cause thermal-collecting tube to damage, avoid the water level in water tank 39 too high simultaneously, thus in causing water tank, pressure is excessive, especially in heating
In the case of boiling.
If the water level of the water tank 39 that water-level gauge is measured is higher than the numerical value of the upper limit, then central controller 45 controls valve 43
Aperture increases, and reduces the aperture of valve 44, so that the water entered in water tank 39 reduces so that leaves the water in water tank 39 and increases
Add, so that the discharge reduction in water tank 39.The water level of water in water tank 39 is reduced by the minimizing of the water yield.On the contrary, water level
Water level in the water tank 39 of measurement amount is less than the numerical value of lower limit, then central controller 45 controls the aperture minimizing of valve 43, increases
The aperture of valve 44, so that the water entered in water tank 39 increases so that leaves the water in water tank 39 and reduces, so that water
The water yield in case 39 increases.
As preferably, the limit value of water level is the height at the 90%-95% place of water tank capacity, preferably 93%.
As preferably, the lower numerical limit of water level is the height that thermal-collecting tube release end of heat stretches in water tank.Thus ensure in water tank
Water cover release end of heat comprehensively.
Improving five is to improving one, improving four improvement combined.
If the temperature of the water in temperature sensor measurement water tank 39 is less than the numerical value of lower limit, now central controller 45
The water level measured according to the water-level gauge of monitoring carrys out the opening and closing of autocontrol valve 43,44, and concrete measure is as follows:
The water level that the water-level gauge of central controller 45 monitoring is measured is higher than lower limit and less than higher limit, then central authorities control
Device 45 controls valve 44,44 and is automatically switched off, thus ensures that the water in water tank 39 continues heat temperature raising;
The water level that the water-level gauge of central controller 45 monitoring is measured is less than lower limit, then central controller 45 controls valve 43
Being automatically switched off, valve 44 continues to open, thus ensures that water continues to flow in water tank 39, when the water-level gauge of central controller 45 monitoring
The water level measured is at or above lower limit, then central controller 45 controls valve 44 and is automatically switched off;
The water level that the water-level gauge of central controller 45 monitoring is measured is higher than higher limit, then central controller 45 controls valve 43
Continuing to open, valve 44 is automatically switched off, thus ensures that water continues to flow out water tank 39, when the water level measurement of central controller 45 monitoring
The water level of amount is equal to or less than higher limit, then central controller 45 controls valve 43 and is automatically switched off.
Remaining feature with improve one, improve five identical, describe the most one by one.
Improving six is to improving two, improving four improvement combined.
If the temperature of the water of the outlet that temperature sensor 42 is measured is less than the numerical value of lower limit, central controller 45 basis
The water level that the water-level gauge of monitoring is measured carrys out the aperture of autocontrol valve 43,44, and concrete measure is as follows:
The water level that the water-level gauge of central controller 45 monitoring is measured is less than higher limit, then central controller 45 controls valve 43
Aperture increase, reduce the aperture of valve 44, so that the water entered in water tank 39 reduces so that leave the water in water tank 39
Increase, so that the discharge reduction in water tank 39, if the water level in water tank 39 is reduced to lower limit or close to lower limit,
Then central controller controls valve 43,44 is closed;
The water level that the water-level gauge of central controller 45 monitoring is measured is less than lower limit, then central controller 45 controls valve 43
Close, be simultaneously emitted by alarm;Now show cannot to realize at present the water temperature needed, reason be probably intensity of illumination not or its
His reason, to remind operator to note.
If the temperature of the water of the outlet that temperature sensor 42 is measured is higher than the numerical value of the upper limit, central controller 45 basis
The water level that the water-level gauge of monitoring is measured carrys out the aperture of autocontrol valve 43,22, and concrete measure is as follows:
The water level that the water-level gauge of central controller 45 monitoring is measured is less than higher limit, then central controller 45 controls valve 43
Aperture reduce, increase the aperture of valve 44, so that the water entered in water tank 39 increases so that leave the water in water tank 39
Reduce, so that the water yield in water tank 39 increases;If the water level in water tank 39 increases to higher limit or close to higher limit,
Then central controller controls valve 43,44 is closed;
The water level that the water-level gauge of central controller 45 monitoring is measured is higher than higher limit, then central controller 45 controls valve 44
Close, be simultaneously emitted by alarm;Now show cannot to realize at present the water temperature needed, reason be probably arrange water temperature too low or its
His reason, to remind operator to note.
Remaining feature with improve one, improve five identical, describe the most one by one.
Fig. 9 illustrates an idiographic flow schematic diagram of solar energy sea water desalination apparatus in preceding embodiment.Certainly in Fig. 9
Heat collector 1 water tank 39 can also be used to replace.
Described sea water desalinating unit includes liquid distributor 7, vaporization chamber 8-10, board-like preheating heat exchanger 15, fresh-water tank 11, light
Water excavationg pump 12, concentrated seawater case 13, concentrated seawater excavationg pump 14.Package unit comprises two set circulations, respectively seawater circulation and adds
Heat recirculated water circulates.
Wherein, solar thermal collector 1 or the hot water entrance vaporization chamber of heating in the water tank 39 of heat collector 1 heating,
In vaporization chamber 8 after liquid distributor 7 sprays heat exchange, enter back into plate type heat exchanger 6, carry out with the sea water in plate type heat exchanger 6
Heat exchange, is then recycled back in heater 1 or water tank 39 heating.
As preferably, described ancillary heating equipment 2 is arranged between heat collector or water tank 39 and vaporization chamber.
As preferably, recirculated water is stored in cyclic water tank 4, and described cyclic water tank 4 is arranged on plate type heat exchanger 6 and thermal-arrest
Between device 1 or water tank 39.As preferably, described recirculated water is circulated under the effect of recirculating water pump 3.Additionally can pass through
Circulating cooling make-up water pump 5, adds recirculated water in system.
Sea water passes through sea water intake pump 16, is inputted in board-like preheating heat exchanger 15 by sea water, at board-like preheating heat exchanger
By entering plate type heat exchanger 6 after the preheating of the fresh water steam in vaporization chamber in 15, carry out in board-like preheating heat exchanger 6
After heat exchange, entering vaporization chamber, spray heat exchange through liquid distributor 7 in vaporization chamber, after heat exchange, the steam of evaporation enters board-like
Preheating heat exchanger, preheats, to realize making full use of of heat, subsequently into being finally collected into the sea water of the system of entrance
In fresh-water tank 11, can be discharged by fresh water extraction pump 12, described vaporization chamber connects concentrated seawater case 13, and remaining concentrated seawater also will be collected
In concentrated seawater case 13, discharge via concentrated seawater excavationg pump 14.
As preferably, described vaporization chamber includes that multistage evaporation room, described multistage evaporation room are connected in series, and sea water steams higher level
Sending out in room and entering next stage vaporization chamber after heat exchange, the steam of described upper level vaporization chamber evaporation enters next stage vaporization chamber, makees
Heat exchange is carried out for thermal source and the sea water entering next stage vaporization chamber.
As preferably, described solar thermal collector 1 or the hot water heated in the water tank 39 of heat collector 1 heating enter
Enter first order vaporization chamber 8.
As preferably, described vaporization chamber is 3 grades, respectively room first order vaporization chamber 8, second level vaporization chamber 9, and the third level is evaporated
Room 10, shown board-like preheating heat exchanger 15 is 3, and described first order vaporization chamber 8 steam out enters second level vaporization chamber 9
After, enter back into the first board-like preheating heat exchanger 15, described second steams level sends out room 9 steam entrance third level vaporization chamber 10 out
After, entering back into the second board-like preheating heat exchanger 15, third level vaporization chamber 10 steam out is directly entered three-plate type preheating and changes
Hot device 15.
As preferably, described sea water is successively through the three, the second, first board-like preheating heat exchanger 15.It is found through experiments,
By this order, optimal sea water fresh water rate can be reached.Main cause is the three, the second, first board-like preheating heat exchanger 15
In exchange capability of heat be gradually lowered, sea water first passes through the heat exchanger that exchange capability of heat is low, then progressively rises through exchange capability of heat with this
High heat exchanger so that the temperature of sea water gradually rises and carries out heat exchange, it is to avoid the heat exchanger being directly over exchange capability of heat strong enters
Entering, after row heat exchange, the heat exchanger heat exchange that exchange capability of heat is weak, the heat exchanger that exchange capability of heat is weak is not reaching preferable heat exchange effect
Really.
As preferably, the solar energy pipeline entering first evaporator 8 arranges temperature sensor and flow transducer
(Fig. 9 only identifies temperature sensor), for measuring temperature and the flow of hot water, the institute of the hot water entering first evaporator 8
State to enter and on the seawaterline of first order vaporization chamber 8, valve 46 is set, be used for controlling to enter first order vaporization chamber 8 flow, described
System also includes that controller, described controller are connected with temperature sensor, flow transducer, valve data, described controller root
According to the hot water temperature measured and hot water flow, the aperture of autocontrol valve 46.
Described controller is that the combination according to hot water temperature and hot water flow carries out Valve controlling, concrete control mode
As follows: to control parameter Q=(hot water temperature-fiducial temperature) * hot water flow, if control parameter Q measured increases, the most automatically increase
Add the aperture of valve, if control parameter Q measured reduces, the most automatically reduce the aperture of valve.
By above-mentioned Based Intelligent Control, it is possible to achieve along with hot water temperature and changes in flow rate control to participate in the sea water of heat exchange
Flow, it is to avoid the sea water amount participating in heat exchange is too high or too low, thus avoids sea hypervolia or very few, thus affects light
Change effect.
As preferably, described fiducial temperature is 25-35 DEG C.
As preferably, sea water intake pump 16 and controller carry out data cube computation, and controller is according to entering first order vaporization chamber 8
Seawaterline on valve 46 aperture automatically adjust the power of intake pump 16.If valve 45 aperture increase, automatically increase into
The power of water pump 16, if valve 46 aperture reduces, reduces the power of intake pump 16 automatically.
Described controller can be above-mentioned central controller 45, it is also possible to be new controller.
Although the present invention discloses as above with preferred embodiment, but the present invention is not limited to this.Any art technology
Personnel, without departing from the spirit and scope of the present invention, all can make various changes or modifications, and therefore protection scope of the present invention should
When being as the criterion with claim limited range.
Claims (5)
1. a solar thermal collector, including thermal-collecting tube, reflecting mirror and collecting plate, passes through thermal-arrest between two adjacent thermal-collecting tubes
Plate connects, so that the collecting plate between multiple thermal-collecting tube and Neighbor Set heat pipe forms tube plate structure;Described solar thermal collector
Including two pieces of tube plate structures, between described two pieces of tube plate structures, shape is at a certain angle, described angle direction and the circle of reflecting mirror
The direction of camber line structural bending is relative, the focus of reflecting mirror between the angle that two pieces of tube plate structures are formed, described thermal-arrest
The cross section of pipe is square, and described collecting plate connects foursquare angle, arranges inner fin inside described thermal-collecting tube, described interior
Fin connects foursquare diagonal angle, and described inner fin will be divided into multiple passage aisle, arranges connection on inner fin inside thermal-collecting tube
Hole, so that adjacent passage aisle communicates with each other, the described a length of L of foursquare inner edge, the radius r of described intercommunicating pore, same wing
The distance between the intercommunicating pore center of circle adjacent on sheet is l, meets following relation:
L/L*10=a*ln (r/L*10)+b;
Wherein ln is logarithmic function, and a, b are parameters, 1.5 < a < 1.6,2.9 <b < 3.0;
0.34<l/L<0.38;
0.14<r/L<0.17;
30mm<L<120mm;
5mm<r<17mm。
2. solar thermal collector as claimed in claim 1,15mm < l < 45mm.
3. a solar seawater desalination system, described system includes solar thermal collector and sea water desalinating unit thereof, described too
Sun can be connected by pipeline between heat collector and sea water desalinating unit, and described solar thermal collector is the sun of claim 1 or 2
Can heat collector.
4. solar seawater desalination system as claimed in claim 3, described sea water desalinating unit includes vaporization chamber, in vaporization chamber
Arranging liquid distributor, wherein, the hot water of solar thermal collector heating enters vaporization chamber, and in vaporization chamber, the sea water through liquid distributor sprays
After drenching heat exchange, enter back into plate type heat exchanger, carry out heat exchange with the sea water in plate type heat exchanger, be then recycled back into solar energy collection
Heating in hot device, in described plate type heat exchanger, the sea water after heat exchange enters the liquid distributor in vaporization chamber.
5. solar seawater desalination system as claimed in claim 4, solar thermal collector recirculated water is stored in cyclic water tank,
Described cyclic water tank is arranged between plate type heat exchanger and solar thermal collector.
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CN110081400B (en) * | 2018-07-05 | 2020-12-01 | 苏州创力波科技有限公司 | Solar steam generator with steam flow control function |
CN108870522B (en) * | 2018-07-11 | 2020-11-10 | 集美大学 | Household central hot water system of solar heat pump |
CN111238067B (en) * | 2018-08-03 | 2021-01-08 | 青岛赛博贝斯数据有限公司 | Solar energy system for controlling closed system pump according to thermal fluid communication |
CN109945513B (en) * | 2018-08-05 | 2020-02-21 | 青岛鑫众合贸易有限公司 | Trough type solar heat collection system for heating liquid medicine |
CN110806017B (en) * | 2018-08-05 | 2021-07-16 | 国网山东省电力公司无棣县供电公司 | Pressure monitoring groove type solar heat collector system |
CN109945517B (en) * | 2018-08-05 | 2020-04-07 | 青岛鑫众合贸易有限公司 | Trough type solar heat collection system for heating liquid medicine |
CN109282688A (en) * | 2018-11-27 | 2019-01-29 | 珠海格力电器股份有限公司 | The processing method of air-conditioning condenser heat exchanger tube, condenser, air-conditioning and the heat exchanger tube |
TWI694972B (en) * | 2018-12-25 | 2020-06-01 | 國立屏東科技大學 | Solar desalination device |
CN110065981A (en) * | 2019-06-13 | 2019-07-30 | 东华理工大学 | A kind of single hose solar energy electrostatic atomization sea water desalination vaporising device and method |
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CN102344179A (en) * | 2011-09-29 | 2012-02-08 | 中国科学院广州能源研究所 | Solar absorption type sea water desalination device with regenerative cycle |
CN102583611A (en) * | 2012-03-14 | 2012-07-18 | 绍兴文理学院 | Horizontal tube falling film evaporation solar seawater desalination device |
CN104633960A (en) * | 2015-03-09 | 2015-05-20 | 中国石油大学(华东) | Loop heat pipe solar system with fins of different heights in heat collection pipes |
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CN102344179A (en) * | 2011-09-29 | 2012-02-08 | 中国科学院广州能源研究所 | Solar absorption type sea water desalination device with regenerative cycle |
CN102583611A (en) * | 2012-03-14 | 2012-07-18 | 绍兴文理学院 | Horizontal tube falling film evaporation solar seawater desalination device |
CN104633960A (en) * | 2015-03-09 | 2015-05-20 | 中国石油大学(华东) | Loop heat pipe solar system with fins of different heights in heat collection pipes |
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