CN203559134U - Integrated heat-dissipating oxyhydrogen decarbonization system based on embedded air flue - Google Patents
Integrated heat-dissipating oxyhydrogen decarbonization system based on embedded air flue Download PDFInfo
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- CN203559134U CN203559134U CN201320700927.7U CN201320700927U CN203559134U CN 203559134 U CN203559134 U CN 203559134U CN 201320700927 U CN201320700927 U CN 201320700927U CN 203559134 U CN203559134 U CN 203559134U
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- electrolytic solution
- vessel
- embedded
- air channel
- oxyhydrogen
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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
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/30—Hydrogen technology
- Y02E60/36—Hydrogen production from non-carbon containing sources, e.g. by water electrolysis
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Abstract
The utility model discloses an integrated heat-dissipating oxyhydrogen decarbonization system based on an embedded air flue. The integrated heat-dissipating oxyhydrogen decarbonization system based on the embedded air flue comprises an electrolyte storage tank, an auxiliary water tank storage tank (12) and an anti-backfire device cylinder (14), wherein an electrolysis chamber (5) is mounted inside the electrolyte storage tank; the electrolysis chamber is provided with a positive terminal (26) and a negative terminal (25), and the positive terminal and the negative terminal extend out of the electrolyte storage tank and are connected with the positive electrode and the negative electrode of an external power source, respectively; an embedded heat-dissipating pipeline (4) is arranged to surround the electrolysis chamber; an air flue (31) with an air inlet and an air outlet is arranged at the outer side of the electrolyte storage tank; one end of the embedded heat-dissipating pipeline is communicated with the air outlet of the air flue, while the other end of the embedded heat-dissipating pipeline is communicated with external air, and an axial-flow fan (9) capable of drafting air into the air flue is mounted on the top of the air flue; a water adding system is arranged on the electrolyte storage tank; an air outlet is formed on the electrolyte storage tank and communicated with the anti-backfire device cylinder through a gas pipeline (8), and an exhaust port (17) is formed on the anti-backfire device cylinder.
Description
Technical field
The utility model relates to a kind of integrated capable of removing carbon through oxyhydrogen generation systems based on embedded air channel.
Background technology
Along with industrial production ground is fast-developing, a large amount of fuel that industry cutting and heating are used are all hydrocarbon polymers, as coal, oil, Sweet natural gas etc., in their refinement and combustion processes, all can produce great amount of carbon dioxide, carbon monoxide, hydrogen sulfide, smokeshade etc., the mankind and environment are caused to very big harm.Along with the signature of each major country of the whole world to greenhouse gas emission agreement, each state is all greatly developing clean energy in recent years, and China is also in a planned way implementing energy-saving and emission-reduction, and strengthens the scientific research investment to clean energy field.
Hydrogen Energy is environmental protection, the clean energy of 21st century; hydrogen and oxygen reaction only produce heat and water; during knallgas burning, temperature reaches 2800 ~ 3200 degrees Celsius; can be widely used in cutting and alternative industrial fuel; and water electrolysis hydrogen production oxygen, in the development of the existing recent two decades of China, has started to step into the mass-producing application stage at present.
Because water electrolysis hydrogen production oxygen gas mixture equipment is the conglomerate of the multiple systems such as a kind of machinery, electronics, chemistry, physics, so manufacture difficulty is large, equipment volume is large, cost is too high, causes application enterprise investment excessive, and application difficulty is large.
Summary of the invention
Technical problem to be solved in the utility model is, the problem large for current electrolysis water hydrogen manufacturing breathing equipment manufacture difficulty, equipment volume is large, cost is too high, provide a kind of manufacture simple, equipment volume is little, the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel that cost is low.
In order to solve the problems of the technologies described above, the technical solution adopted in the utility model is: a kind of integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel, and it comprises electrolytic solution hold-up vessel, secondary water tank hold-up vessel and backfire controller cylinder;
Tank room is equipped with in the inside of this electrolytic solution hold-up vessel, and this tank room is provided with positive terminal and negative terminal, and this positive terminal and negative terminal extend electrolytic solution hold-up vessel, and is connected with the positive and negative electrode of external power source respectively;
One embedded-type heat-dissipating pipeline is located at the inside of this electrolytic solution hold-up vessel and is located on all sides of tank room, and the outside of this electrolytic solution hold-up vessel is provided with the air channel with blast inlet and exhaust outlet, one end of this embedded-type heat-dissipating pipeline is communicated with the exhaust outlet in air channel, the other end communicates with extraneous air, and the top in air channel is equipped with and wind can be drawn into the aerofoil fan of air inlet of air duct;
On this electrolytic solution hold-up vessel, be also provided with a convenient water-adding system that adds water to system; And above this electrolytic solution hold-up vessel, be provided with air outlet, this air outlet is communicated with backfire controller cylinder through gas pipeline, and backfire controller cylinder is provided with venting port.
Further being improved to of such scheme, this water-adding system is automatic watering system, its top that is specially this electrolytic solution hold-up vessel is provided with electrolytic solution level switch, and this electrolytic solution level switch and secondary water tank hold-up vessel, backfire controller level switch, make-up water pump, secondary water tank electromagnetic valve, electrolytic solution hold-up vessel add water solenoid valve, backfire controller adds water solenoid valve and forms a whole set of automatic watering system.
Further being improved to of such scheme, this electrolytic solution level switch is arranged on electrolytic solution hold-up vessel by flange, and the centre of flange arranges this air outlet.
Further being improved to of such scheme, this make-up water pump is surge pump.
Further being improved to of such scheme, the upper end of this electrolytic solution hold-up vessel is provided with electrolysis safety valve and negative pressure switch.
Further being improved to of such scheme, this positive terminal and negative terminal are all used insulation covering and sealing-ring to be fixed and seal through the interior outside of electrolytic solution hold-up vessel.
Further being improved to of such scheme, the air inlet end of this gas pipeline is equipped with the strainer of a filtering moisture.
Further being improved to of such scheme, is equipped with backfire controller cylinder safety valve on this backfire controller cylinder.
Further being improved to of such scheme, electrolytic solution hold-up vessel is vertical is positioned in frame for this.
Compared with prior art, the beneficial effect that the utility model has is: what in relatively previous capable of removing carbon through oxyhydrogen system, electrolytic solution hold-up vessel was two splits with gas-water separation middle connection again of tank radiating pipe composition occurs, simultaneously also need be in surrounding's increase aluminium flake heat radiation of radiating pipe, the utility model is by embedded-type heat-dissipating pipeline, tank room, electrolytic solution hold-up vessel, gas-water separation structure (being located at the strainer of gas pipeline air inlet end) is made an integral body, the common the same pot that uses, and radiator element is stainless steel, pass through actual verification, existing heat radiation can reach requirement, make the utility model equipment more integrated, volume is less, preparation technology is simpler, efficiency is higher, can effectively reduce energy consumption, be conducive to vigorously promote the use.
Accompanying drawing explanation
Fig. 1 is the main TV structure schematic diagram of the utility model one embodiment;
Fig. 2 is the side-looking structural representation of the utility model one embodiment.
Label declaration:
1, electrolytic solution hold-up vessel leg; 2, electrolytic solution tap valve; 3, electrolytic solution hold-up vessel; 4, embedded pipe; 5, tank room; 6, electrolysis safety valve; 7, strainer; 8, gas pipeline; 9, aerofoil fan; 10, electrolytic solution level switch; 11, negative pressure switch; 12, secondary water tank hold-up vessel; 13, secondary water level detector of water tank; 14, backfire controller cylinder; 15, backfire controller safety valve; 16, secondary tank filler opening; 17, venting port; 18, anti-backfire level switch; 19, secondary water tank drain valve; 20, surge pump; 21, secondary water tank electromagnetic valve; 22, electrolytic solution hold-up vessel adds water solenoid valve; 23, backfire controller adds water solenoid valve; 24, condensate water level detector; 25, negative terminal; 26, positive terminal; 27, insulation covering; 28, sealing-ring; 29, check valve; 30, condensate water discharging magnetic valve.
Embodiment
As shown in Figure 1 and Figure 2, the integral heat dissipation capable of removing carbon through oxyhydrogen system of the utility model based on embedded air channel, comprise that one is fixed on the electrolytic solution hold-up vessel 3 in frame by leg 1, and secondary water tank hold-up vessel 12 and backfire controller cylinder 14.
The interior lower end of this electrolytic solution hold-up vessel 3 is equipped with tank room 5, the both sides of this tank room 5 are provided with positive terminal 26 and negative terminal 25, and this positive terminal 26 and negative terminal 25 all extend electrolytic solution hold-up vessel 3, to facilitate positive pole and the negative pole of access external power source.On this positive terminal 26 and negative terminal 25, through the interior outside of electrolytic solution hold-up vessel 3, all use insulation covering 27 and sealing-ring 28 to be fixed and to seal.
Embedded-type heat-dissipating pipeline 4 is also equipped with in the inside of this electrolytic solution hold-up vessel 3, and above this electrolytic solution hold-up vessel 3, be provided with air channel 31, blast inlet and exhaust outlet (not shown) are equipped with in below this air channel 31 or side, this embedded-type heat-dissipating pipeline 4 is installed in all sides of tank room 5, and the entrance of this embedded-type heat-dissipating pipeline 4 communicates with the exhaust outlet in air channel 31, aerofoil fan 9 is also equipped with at the top in air channel 31, and air channel 31, aerofoil fan 9, embedded-type heat-dissipating pipeline 4 form the cooling system of embedded high efficiency and heat radiation.By wind, the blast inlet by air channel 31 is drawn into aerofoil fan 9, and in exhaust outlet is sent into embedded-type heat-dissipating pipeline 4, thereby by taking away by the cold wind of embedded-type heat-dissipating pipeline 4 high temperature that electrolytic solution is passed to embedded-type heat-dissipating pipeline 4, through the wind of embedded-type heat-dissipating pipeline 4 heat absorptions, finally by the air outlet of embedded-type heat-dissipating pipeline 4, hot blast is discharged.
The top of this electrolytic solution hold-up vessel 3 is also provided with electrolytic solution water level probe 10, this electrolytic solution water level probe 10 adds water solenoid valve 22 with secondary water tank hold-up vessel 12, backfire controller water level probe 18, surge pump 20, secondary water tank electromagnetic valve 21, electrolytic solution hold-up vessel, backfire controller adds water solenoid valve 23 and forms a whole set of automatic watering system (this automatic watering system is this area prior art, thereby omits its annexation).
Above this electrolytic solution hold-up vessel 3, be provided with an air outlet (not shown in the figures, in the illustrated embodiment, electrolytic solution water level probe 10 is arranged on electrolytic solution hold-up vessel 3 by flange, the centre of flange arranges this air outlet), this air outlet connects a gas pipeline 8, this gas pipeline 8 is communicated with backfire controller cylinder 14, and then the venting port 17 by backfire controller cylinder 14 carries out exhaust.For the moisture in filtering gas, the air inlet end of this gas pipeline 8 is equipped with a strainer 7.The gas that electrolysis produces enters gas pipeline 8 by the air outlet of electrolytic solution hold-up vessel 3, and discharges through backfire controller cylinder 14.When igniting, the water level in backfire controller cylinder 14, backfire controller safety valve 15 is carried out the safe handling of anti-backfire and pressure overvoltage exhaust.
Claims (9)
1. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel, is characterized in that comprising electrolytic solution hold-up vessel (3), secondary water tank hold-up vessel (12) and backfire controller cylinder (14);
Tank room (5) is equipped with in the inside of this electrolytic solution hold-up vessel (3), this tank room (5) is provided with positive terminal (26) and negative terminal (25), and this positive terminal (26) extends electrolytic solution hold-up vessel and is connected with the positive and negative electrode of external power source respectively with negative terminal (25);
One embedded-type heat-dissipating pipeline (4) is located at the inside of this electrolytic solution hold-up vessel (3) and is located on all sides of tank room (5), and the outside of this electrolytic solution hold-up vessel is provided with the air channel of blast inlet and exhaust outlet (31), one end of this embedded-type heat-dissipating pipeline (4) is communicated with the exhaust outlet in air channel, the other end communicates with extraneous air, and the aerofoil fan (9) that wind can be drawn into air inlet of air duct is equipped with at the top in air channel;
On this electrolytic solution hold-up vessel (3), be also provided with a convenient water-adding system that adds water to system; And above this electrolytic solution hold-up vessel (3), be provided with air outlet, this air outlet is communicated with backfire controller cylinder (14) through gas pipeline (8), and backfire controller cylinder (14) is provided with venting port (17).
2. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, it is characterized in that, this water-adding system is automatic watering system, its top that is specially this electrolytic solution hold-up vessel is provided with electrolytic solution level switch, and this electrolytic solution level switch and secondary water tank hold-up vessel, backfire controller level switch, make-up water pump, secondary water tank electromagnetic valve, electrolytic solution hold-up vessel add water solenoid valve, backfire controller adds water solenoid valve and forms a whole set of automatic watering system.
3. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 2, is characterized in that, it is upper that this electrolytic solution level switch is arranged at electrolytic solution hold-up vessel (3) by flange, and the centre of flange arranges this air outlet.
4. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 2, is characterized in that, this make-up water pump is surge pump.
5. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, is characterized in that, the upper end of this electrolytic solution hold-up vessel (3) is provided with electrolysis safety valve (6) and negative pressure switch (11).
6. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, it is characterized in that, this positive terminal (26) all uses insulation covering (27) and sealing-ring (28) to be fixed and to seal with negative terminal (25) through the interior outside of electrolytic solution hold-up vessel (3).
7. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, is characterized in that, the air inlet end of this gas pipeline (8) is equipped with the strainer (7) of a filtering moisture.
8. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, is characterized in that, on this backfire controller cylinder (14), backfire controller cylinder safety valve (15) is housed.
9. the integral heat dissipation capable of removing carbon through oxyhydrogen system based on embedded air channel according to claim 1, is characterized in that, vertical being positioned in frame of this electrolytic solution hold-up vessel (3).
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Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104630813A (en) * | 2013-11-08 | 2015-05-20 | 长沙矿山研究院有限责任公司 | Integral heat-dissipation hydrogen-oxygen de-carbon system based on embedded air channel |
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2013
- 2013-11-08 CN CN201320700927.7U patent/CN203559134U/en not_active Expired - Fee Related
Cited By (1)
Publication number | Priority date | Publication date | Assignee | Title |
---|---|---|---|---|
CN104630813A (en) * | 2013-11-08 | 2015-05-20 | 长沙矿山研究院有限责任公司 | Integral heat-dissipation hydrogen-oxygen de-carbon system based on embedded air channel |
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C14 | Grant of patent or utility model | ||
GR01 | Patent grant | ||
CF01 | Termination of patent right due to non-payment of annual fee | ||
CF01 | Termination of patent right due to non-payment of annual fee |
Granted publication date: 20140423 Termination date: 20171108 |