CN210097294U - Gas cooling water filtering device - Google Patents

Gas cooling water filtering device Download PDF

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Publication number
CN210097294U
CN210097294U CN201920552833.7U CN201920552833U CN210097294U CN 210097294 U CN210097294 U CN 210097294U CN 201920552833 U CN201920552833 U CN 201920552833U CN 210097294 U CN210097294 U CN 210097294U
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CN
China
Prior art keywords
cooling water
filtering device
gas
water filtering
gas cooling
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Expired - Fee Related
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CN201920552833.7U
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Chinese (zh)
Inventor
陈坤兴
张建民
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Jiangsu Boruntong Technology Co Ltd
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Jiangsu Boruntong Technology Co Ltd
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Priority to CN201920552833.7U priority Critical patent/CN210097294U/en
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    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02EREDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
    • Y02E60/00Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
    • Y02E60/30Hydrogen technology
    • Y02E60/36Hydrogen production from non-carbon containing sources, e.g. by water electrolysis
    • YGENERAL 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
    • Y02TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
    • Y02TCLIMATE CHANGE MITIGATION TECHNOLOGIES RELATED TO TRANSPORTATION
    • Y02T10/00Road transport of goods or passengers
    • Y02T10/10Internal combustion engine [ICE] based vehicles
    • Y02T10/12Improving ICE efficiencies

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  • Electrolytic Production Of Non-Metals, Compounds, Apparatuses Therefor (AREA)

Abstract

The utility model relates to a gas cooling water filtering device, including the gas cooling water filtering device jar body of transversal arrangement, a side of the gas cooling water filtering device jar body is provided with gas cooling water filtering device air inlet, and the another side of the gas cooling water filtering device jar body is provided with gas cooling water filtering device gas outlet, the bottom of the gas cooling water filtering device jar body is provided with gas cooling water filtering device liquid return port, the gas cooling water filtering device fin that has a plurality of rectangles of outside extension of the jar body outer wall of the gas cooling water filtering device jar body along its circumferencial direction, interval arrangement such as a plurality of gas cooling water filtering device fins, be provided with multi-disc interval arrangement gas cooling water filtering device silk screen along its length direction in the inner chamber of the gas cooling water filtering device jar body. The utility model relates to a gas cooling water filtering device has the advantage that sexual valence relative altitude, occupation space are little, use cost is low.

Description

Gas cooling water filtering device
Technical Field
The utility model relates to a gas cooling water filtering device belongs to on-vehicle water electrolysis hydrogen manufacturing technical field.
Background
In the process of preparing hydrogen by water electrolysis, the temperature of electrolyte in the electrolytic cell can be continuously raised due to factors such as the occurrence of electrolytic reaction, the pressure-resistant closed structure of the electrolytic cell and the like, and the contents of water vapor in oxyhydrogen gas generated by electrolysis and alkaline particles in the electrolyte are raised along with the temperature rise, thereby having negative influence on the service performance of the oxyhydrogen gas. Therefore, the oxyhydrogen gas is cooled by two modes of forced air cooling heat dissipation and oxyhydrogen gas leading-out cooling of the gas outlet pipeline. The air outlet pipeline forced air cooling heat dissipation mode has higher requirement on the structural design of the pipeline, complex structure and higher cost; forced air cooling heat dissipation can bring the rise of power consumption. Oxyhydrogen derives refrigerated mode, and is comparatively complicated to circulation pipe-line system design, and the security requirement is higher in the process, and the unable automatic electrolyte circulation system that returns of liquid that the while condensation came out needs additionally to design storage device on the one hand, and on the other hand electrolyte concentration can reduce rapidly, influences electrolysis efficiency, shortens the replacement cycle.
SUMMERY OF THE UTILITY MODEL
An object of the utility model is to overcome the aforesaid not enough, provide a gas cooling water filtering device that sexual valence relative altitude, occupation space are little, use cost is low.
The purpose of the utility model is realized like this: the gas cooling water filtering device comprises a transversely arranged gas cooling water filtering device tank body, wherein a gas cooling water filtering device liquid return opening is formed in the bottom of the gas cooling water filtering device tank body, a plurality of rectangular gas cooling water filtering device radiating fins outwards extend from the outer wall of the tank body of the gas cooling water filtering device tank body along the circumferential direction of the tank body, the plurality of gas cooling water filtering device radiating fins are arranged at equal intervals, and a plurality of gas cooling water filtering device wire nets are arranged at intervals in the inner cavity of the gas cooling water filtering device tank body along the length direction of the inner cavity of the gas cooling water filtering device tank body.
Furthermore, a gas cooling water filtering device gas inlet is arranged on one side surface of the gas cooling water filtering device tank body, and a gas cooling water filtering device gas outlet is arranged on the other side surface of the gas cooling water filtering device tank body.
Furthermore, the tank body of the gas cooling water filtering device is arranged into a cylindrical structure.
Furthermore, the wire mesh of the gas cooling water filtering device adopts a stainless steel woven mesh structure.
Furthermore, the radiating fins of the gas cooling water filtering device are made of aluminum materials.
An energy-saving and emission-reducing device for a vehicle internal combustion engine comprises a water electrolysis tank, a circulating liquid storage tank, a gas cooling and water filtering device, a gas drying device and a liquid supplementing tank,
the water electrolyzer is used for preparing oxyhydrogen gas by water electrolysis;
the circulating liquid storage tank is used for collecting gas-liquid mixed high-temperature electrolyte generated in electrochemical reaction in the water electrolysis tank, wherein one part of oxyhydrogen gas containing water vapor is sent into the gas cooling water filtering device, and the other part of high-temperature electrolyte is sent into the liquid supplementing tank;
the gas cooling water filtering device is used for cooling oxyhydrogen gas containing water vapor and performing primary water filtering on the oxyhydrogen gas;
the gas drying device is used for drying the oxyhydrogen gas filtered by the gas cooling water filtering device and outputting the dried oxyhydrogen gas to the engine;
the liquid supplementing tank is used for cooling the high-temperature electrolyte, supplementing raw material water required by electrolysis to the circulating liquid storage tank, and sending the supplemented raw material water into the water electrolysis tank through the circulating liquid storage tank.
Compared with the prior art, the beneficial effects of the utility model are that:
the utility model relates to a gas cooling water filtering device, prepare oxyhydrogen's device to small-size water electrolysis, both need not to carry out forced heat dissipation to the gas outlet pipeline, need not derive the postcooling with oxyhydrogen again, utilize self subsidiary jar body heat radiation structure and inside structure of catching can realize cooling and filtration to the oxyhydrogen gas, reduce the content of vapor and alkaline composition, the liquid drop that the condensation came out simultaneously can automatic flow back to in the electrolyte circulation system, the performance of electrolyte and oxyhydrogen gas has both been guaranteed like this, extra design storage device has been avoided again.
Drawings
Fig. 1 is a schematic structural diagram of an automatic control system of an energy-saving device of an internal combustion engine for a vehicle.
FIG. 2 is a schematic structural diagram of an oil-saving and emission-reducing device of an internal combustion engine for a vehicle.
FIG. 3 is a schematic view of the structure of a water electrolyzer.
Fig. 4 is a partially enlarged view of fig. 3.
Fig. 5 is a schematic view of the structure of the water electrolysis electrode plate.
Fig. 6 is a cross-sectional view a-a of fig. 5.
Fig. 7 is a schematic view of the structure of the gasket of the water electrolyzer.
Fig. 8 is a sectional view of B-B in fig. 7.
Fig. 9 is an enlarged view of a portion I in fig. 8.
FIG. 10 is a schematic view of the circulating reservoir.
Fig. 11 is an external view of the gas cooling water filtering device.
Fig. 12 is a schematic structural diagram of the gas cooling water filtering device.
Fig. 13 is a schematic view of the structure of the wire of the gas cooling water filtering device in fig. 12.
Fig. 14 is a schematic structural view of the gas drying device.
Fig. 15 is a schematic structural view of the lid of the drying device of fig. 14 with the gas removed.
FIG. 16 is a top view of the body of the gas dryer of FIG. 14.
FIG. 17 is a bottom view of the body of the gas drying appliance of FIG. 14.
Wherein:
vehicle system 100, vehicle battery 101, and engine 102
Control unit 200
Intelligent controllable electrolysis power supply 300
Energy-saving and emission-reducing device 400 for vehicle internal combustion engine
Water electrolyser 401, first electrolyser end plate 401.1, second electrolyser end plate 401.2, water electrolyser pole plate 401.3, water electrolyser pole plate body 401.3.1, foolproof inclined section 401.3.2, foolproof bump 401.3.3, water electrolyser pole plate electrode 401.3.4, electrolysis zone 401.3.5, electrolysis bump 401.3.6, conical section 401.3.61, semi-circular section 401.3.62, water electrolyser pole plate mounting zone 401.3.7, water electrolyser pole plate mounting hole 401.3.8, water electrolyser gasket 401.4, water electrolyser gasket body 401.4.1, water electrolyser gasket inclined section 401.4.2, first rib frame 401.4.3, second rib frame 401.4.4, third rib frame 401.4.5, water electrolyser gasket mounting zone 401.4.6, water electrolyser gasket mounting hole 401.4.7, convex ring 401.4.8, first water electrolyser gasket 401.5, second water electrolyser gasket 401.6, water electrolyser bolt 401.7, water electrolyser locking component 401.8, water electrolyser return liquid outlet 401.9, water electrolyser liquid outlet 401.10, water electrolyser gas outlet 401.11
A circulating liquid storage tank 402, a circulating liquid storage tank body 402.1, a circulating liquid storage tank cabin separation baffle 402.2, a circulating liquid storage tank cabin 402.3, a circulating liquid storage tank communication port 402.4, a first swing-inhibiting wing-separating fin 402.5 of the circulating liquid storage tank, a second swing-inhibiting wing-separating fin 402.6 of the circulating liquid storage tank, a mesh baffle 402.7 of the circulating liquid storage tank, an air inlet 402.8 of the circulating liquid storage tank, an air outlet 402.9 of the circulating liquid storage tank, a liquid outlet 402.10 of the circulating liquid storage tank, a pressure relief cover 402.11 of the circulating liquid storage tank, a liquid level sensor 402.12 of the circulating liquid storage tank, a liquid
The gas cooling water filtering device 403, a gas cooling water filtering device tank body 403.1, a gas cooling water filtering device air inlet 403.2, a gas cooling water filtering device air outlet 403.3, a gas cooling water filtering device liquid return port 403.4, a gas cooling water filtering device radiating fin 403.5, a gas cooling water filtering device wire mesh 403.6 gas drying device 404, a gas drying device kettle body 404.1, a gas drying device upper kettle cover 404.2, a gas drying device lower kettle cover 404.3, a gas drying device central air chamber 404.4, a gas drying device air inlet 404.5, a gas drying device air outlet 404.6, a gas drying device first vertical plate 404.7, a gas drying device second vertical plate 404.8, a gas drying device third vertical plate 404.9, a gas drying device first notch 404.10, a gas drying device second notch 404.11, a gas drying device air inlet chamber 404.12, a gas drying device air outlet chamber 404.13, a gas drying device air chamber 404.14, a gas drying device third notch 404.15, a gas drying device air outlet, A fourth gap 404.16 for the gas drying means, a liquid level sensor 404.17 for the gas drying means, a first baffle 404.18 for the gas drying means, a second baffle 404.19 for the gas drying means, a third baffle 404.20 for the gas drying means, a desiccant 404.21, a gasket 404.22 for the gas drying means, and a gasket 404.23 for the gas drying means
Fluid infusion pot 405, fluid infusion pot body 405.1, fluid infusion pot water injection port 405.2, fluid infusion pot water outlet 405.3, cooling spiral pipe 405.4, cooling spiral pipe liquid inlet 405.5, cooling spiral pipe liquid outlet 405.6, fluid infusion pot liquid level sensor 405.7 and fluid infusion pot temperature sensor 405.8
Drain valve 406
Water adding pump 407
An electric shutoff valve 408.
Detailed Description
The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.
Referring to fig. 1-2, the utility model relates to an automatic control system for an energy-saving device of a vehicle internal combustion engine, which comprises a control unit 200 composed of a central processing unit and a plurality of co-processing chips, an intelligent controllable electrolytic power source 300, a plurality of sensors and an energy-saving and emission-reducing device 400 of the vehicle internal combustion engine, the control unit 200 collects, calculates, analyzes, outputs and records information such as the working condition, driving environment, road and traffic condition of the vehicle through a plurality of sensors, and simultaneously collects the voltage and current value of the intelligent controllable electrolytic power supply 300 in real time, according to a strategy set by a program, the current values calibrated under different states such as the working condition of the vehicle, the driving environment, the road and the traffic condition are output to the energy-saving and emission-reducing device 400 of the internal combustion engine for the vehicle, and the energy-saving and emission-reducing device 400 of the internal combustion engine for the vehicle is used for carrying out real-time fine control and correction on the air supply quantity of the engine 102 in the vehicle system 100.
The energy-saving and emission-reducing device 400 for the vehicle internal combustion engine comprises a water electrolysis tank 401, a circulating liquid storage tank 402 (an oscillation-inhibiting circulating liquid storage tank of a vehicle-mounted hydrogen-oxygen generator), a gas cooling water filtering device 403, a gas drying device 404 (a gas drying device with an automatic alarm function) and a liquid supplementing tank 405,
the water electrolysis cell 401 is used for electrolyzing water to prepare oxyhydrogen gas;
the circulating liquid storage tank 402 is used for collecting gas-liquid mixed high-temperature electrolyte generated in the electrochemical reaction in the water electrolysis tank 401, wherein one part of oxyhydrogen gas containing water vapor is sent to the gas cooling water filtering device 403, and the other part of high-temperature electrolyte is sent to the liquid supplementing tank 405;
the gas cooling water filtering device 403 is used for cooling the oxyhydrogen gas containing water vapor and performing primary water filtering on the oxyhydrogen gas;
the gas drying device 404 is configured to dry the oxyhydrogen gas filtered by the gas cooling water filtering device 403, and output the dried oxyhydrogen gas to the engine 102;
the liquid replenishing tank 405 is used for cooling the high-temperature electrolyte, replenishing raw material water required for electrolysis to the circulating liquid storage tank 402, and sending the replenished raw material water into the water electrolysis tank 401 through the circulating liquid storage tank 402.
The intelligent controllable electrolytic power supply 300 is used for providing a constant-voltage direct-current power supply with adjustable real-time current for the water electrolyzer 401, so that the continuous power utilization requirement of the water electrolyzer 401 is ensured, the input end of the intelligent controllable electrolytic power supply 300 is connected with the positive electrode and the negative electrode of the vehicle storage battery 101 in the vehicle system 100 through a conductive cable, the output end of the intelligent controllable electrolytic power supply 300 is connected with the positive electrode plate and the negative electrode plate of the water electrolyzer 401 through a conductive cable, and the signal port of the intelligent controllable electrolytic power supply 300 is connected with the control unit 200 through a signal cable.
The plurality of sensors comprise four vehicle sensors and eight external sensors, the vehicle sensors are installed in the vehicle system 100, the vehicle sensors comprise an engine speed sensor, an intake pressure and temperature sensor, a coolant temperature sensor and an accelerator pedal position sensor, and the engine speed sensor is located on an output shaft of a vehicle engine and used for acquiring the real-time rotating speed of the vehicle engine; the air inlet pressure and temperature sensor is positioned at the rear end of an intercooler of an air inlet pipeline of the vehicle and is used for acquiring the air inlet pressure and the air inlet temperature of air sucked by the engine; the cooling liquid temperature sensor is positioned on a vehicle cooling pipeline and used for collecting the real-time temperature of the engine cooling liquid; the accelerator position sensor is positioned below an accelerator pedal of a vehicle cockpit and used for acquiring the opening degree of the accelerator pedal of the vehicle;
the external sensor comprises a speed sensor, an angle sensor, an acceleration sensor, a position track sensor, a temperature sensor, an atmospheric pressure sensor, a wind speed sensor and a fuel flow sensor, wherein the speed sensor is arranged in an automatic control system of the energy-saving and emission-reducing device of the internal combustion engine for the vehicle and is used for acquiring the real-time moving speed of the vehicle; the angle sensor is arranged at a reasonable position on a crossbeam of the vehicle underframe and is used for acquiring the integral real-time angle of the vehicle; the acceleration sensor is arranged in an automatic control system of the energy-saving and emission-reducing device of the internal combustion engine for the vehicle and is used for acquiring the real-time acceleration and the real-time change rate of the speed of the vehicle; the position track sensor (GPS positioning sensor) is arranged in an automatic control system of the energy-saving and emission-reducing device of the internal combustion engine for the vehicle and is used for acquiring the real-time position, the moving track and the moving speed of the vehicle; the temperature sensor is arranged in the oil-saving emission-reducing device of the internal combustion engine for the vehicle and is used for collecting the environmental temperature of the vehicle under the environment; the atmospheric pressure sensor is arranged in the oil-saving emission-reducing device of the vehicle internal combustion engine and is used for collecting atmospheric pressure under the environment where the vehicle is located; the wind speed sensor is arranged at a reasonable position outside a vehicle body and is used for collecting the wind speed of the vehicle in the environment; the fuel flow sensor is arranged on a vehicle fuel pipeline and used for collecting fuel consumption of a vehicle, including instantaneous fuel consumption, interval fuel consumption and the like.
Referring to fig. 3-9, the water electrolyzer 401 comprises a first water electrolyzer end plate 401.1 and a second water electrolyzer end plate 401.2 which are arranged in bilateral symmetry, a plurality of water electrolyzer end plates 401.3 are arranged between the first water electrolyzer end plate 401.1 and the second water electrolyzer end plate 401.2 in parallel, a water electrolyzer sealing gasket 401.4 is arranged between every two adjacent water electrolyzer end plates 401.3, a first water electrolyzer spacer 401.5 is arranged between the inner wall of the first water electrolyzer end plate 401.1 and the water electrolyzer end plate 401.3 positioned at the leftmost side, a second water electrolyzer spacer 401.6 is arranged between the inner wall of the second water electrolyzer end plate 401.2 and the water electrolyzer end plate 401.3 positioned at the rightmost side, the water electrolyzer 401 further comprises a water electrolyzer bolt 401.7 and a water electrolyzer locking assembly 401.8, and the water electrolyzer bolt 401.7 sequentially penetrates through the first water electrolyzer end plate 401.1, the first water electrolyzer spacer 401.5, the plurality of water electrolyzer end plates 401.3 and a plurality of water electrolyzer sealing gaskets 401.4, The water electrolyzer second spacer 401.6 and the water electrolyzer second end plate 401.2, the tail end of the water electrolyzer bolt 401.7 extends out of the water electrolyzer second end plate 401.2 and is locked and fixed by the water electrolyzer locking assembly 401.8;
the water electrolyzer 401 is provided with a water electrolyzer liquid return port 401.9, a water electrolyzer liquid discharge port 401.10 and a water electrolyzer gas outlet 401.11.
The water electrolysis pole plate 401.3 comprises a rectangular water electrolysis pole plate body 401.3.1, a foolproof structure is arranged at one corner of the water electrolysis pole plate body 401.3.1, the foolproof structure comprises a foolproof inclined section 401.3.2, a foolproof bump 401.3.3 is arranged on the upper section or the lower section of the foolproof inclined section 401.3.2, and in the production process, a worker can quickly identify the installation direction through the foolproof structure, so that the recognition degree is high, mistakes are not easy to occur, and the production efficiency is improved; in addition, under the condition of ensuring the whole water-proof performance of the water electrolysis cell 401, liquid is not easy to deposit at the foolproof inclined section 401.3.2, the risk of circuit short circuit is avoided, and meanwhile, the voltage among the water electrolysis polar plates 401.3 is convenient to detect, and the diagnosis and analysis are convenient;
a water electrolysis pole plate electrode 401.3.3 extends outwards from the middle section of the foolproof inclined section 401.3.2, the water electrolysis pole plate electrode 401.3.4 sequentially comprises a first isosceles trapezoid section, a rectangular section and a second isosceles trapezoid section from inside to outside, one long side of the rectangular section is connected with the upper bottom of the first isosceles trapezoid section and is equal in length, the other long side of the rectangular section is connected with the lower bottom of the second isosceles trapezoid section and is equal in length, and the water electrolysis pole plate electrode 401.3.4 has the advantages of saving materials, being convenient to connect with an external power line and improving installation efficiency due to the structural design and the position design;
the middle part of the surface of the water electrolysis pole plate body 401.3.1 is provided with a rectangular electrolysis region 401.3.5, four sides of an electrolysis region 401.3.5 are respectively parallel to four sides of the water electrolysis pole plate body 401.3.1, one end corner of the electrolysis region 401.3.5, which is close to the foolproof inclined section 401.3.2, is provided with an electrolysis region inclined section, the electrolysis region inclined section is parallel to the foolproof inclined section 401.3.2, a plurality of electrolysis lugs 401.3.6 are uniformly arranged in the electrolysis region 401.3.5, each electrolysis lug 401.3.6 sequentially comprises a conical section 401.3.61 and a semicircular section 401.3.62 from inside to outside, the electrolysis lug 401.3.6 is processed by stamping, sand blasting or shot blasting and other process means, the surface roughness of the water electrolysis pole plate 401.3 is increased, the contact surface area of the water electrolysis pole plate 401.3 and electrolyte is increased, the gas production efficiency is improved, and the overall size of the water electrolysis pole plate 401.3 is reduced so as to meet the requirement of product;
the outer ring of the electrolysis region 401.3.5 is provided with a water electrolysis pole plate mounting region 401.3.7, and a plurality of water electrolysis pole plate mounting holes 401.3.8 are uniformly formed in the water electrolysis pole plate mounting region 401.3.7 along the circumferential direction of the water electrolysis pole plate body 401.3.1.
The water electrolyzer gasket 401.4 comprises a rectangular water electrolyzer gasket body 401.4.1, one corner of the water electrolyzer gasket body 401.4.1 is provided with a water electrolyzer gasket inclined section 401.4.2, the water electrolyzer gasket inclined section 401.4.2 is parallel to the foolproof inclined section 401.3.2 on the water electrolysis polar plate 401.3, and the external dimension of the water electrolyzer gasket body 401.4.1 is larger than that of the water electrolysis polar plate body 401.3.1;
the water electrolyzer gasket body 401.4.1 is provided with a first rib frame 401.4.3, a second rib frame 401.4.4 and a third rib frame 401.4.5 which are the same in shape from inside to outside, the first rib frame 401.4.3 corresponds to an electrolysis region 401.3.5 of the water electrolyzer plate 401.3, the third rib frame 401.4.5 surrounds the outer edge of the water electrolyzer gasket body 401.4.1, the distance between the first rib frame 401.4.3 and the second rib frame 401.4.4 is smaller than the distance between the second rib frame 401.4.4 and the third rib frame 401.4.5, the region between the second rib frame 401.4.4 and the third rib frame 401.4.5 is provided with a water electrolyzer gasket mounting region 401.4.6, a plurality of water electrolyzer gasket mounting holes 401.4.7 are uniformly formed in the water electrolyzer gasket mounting region 401.4.6 along the circumferential direction of the water electrolyzer gasket body 401.4.1, the diameter of the water electrolyzer gasket mounting hole 401.4.7 is smaller than that of the water electrolyzer plate mounting hole 401.3.8, one end ring of the water electrolyzer gasket mounting hole 401.4.7 is provided with a convex ring 401.4.8, the water electrolyzer gasket mounting hole 401.4.7 and the convex ring 401.4.8 are internally provided with water electrolyzer bolts 401.7, and the convex ring 401.4.8 penetrates through the water electrolysis pole plate mounting hole 401.3.8.
During installation, the convex ring 401.4.8 on the water electrolyzer gasket 401.4 penetrates through the water electrolysis pole plate mounting hole 401.3.8 and abuts against the outer ring of the water electrolyzer gasket mounting hole 401.4.7 of the adjacent water electrolyzer gasket 401.4, the water electrolysis pole plate 401.3 is sealed through the reaction force generated after the water electrolysis pole plate is extruded, and the water electrolyzer bolt 401.7 is isolated from being in contact with the water electrolysis pole plate 401.3, so that short circuit caused by the fact that electrolyte contacts the water electrolyzer bolt 401.7 and the water electrolysis pole plate 401.3 due to local sealing failure is avoided; meanwhile, the shape of the water electrolysis bath sealing gasket 401.4 is increased by one circle compared with the shape of the water electrolysis polar plate 401.3, so that the water electrolysis polar plate 401.3 can be completely wrapped when being mutually extruded, the phenomenon of circuit short circuit among a plurality of water electrolysis polar plates 401.3 is avoided, the integral waterproof requirement of the water electrolysis bath 401 is met, and the safety and reliability are improved.
Referring to fig. 10, the circulating liquid storage tank 402 comprises a circulating liquid storage tank body 402.1, a plurality of vertical circulating liquid storage tank warehouse separating plates 402.2 are arranged in an inner cavity of the circulating liquid storage tank body 402.1 from left to right, the circulating liquid storage tank warehouse separating plates 402.2 divide the inner cavity of the circulating liquid storage tank body 402.1 into a plurality of circulating liquid storage tank liquid storage bin chambers 402.3, so that the liquid level fluctuation caused by mutual conversion of potential energy and kinetic energy generated by liquid level fluctuation can be inhibited or reduced, a circulating liquid storage tank communicating port 402.4 is formed in the lower section of the circulating liquid storage tank warehouse separating plate 402.2, the circulating liquid storage tank communicating port 402.4 enables the circulating liquid storage tank bin chambers 402.3 to be communicated with each other, the liquid level height in the circulating liquid storage tank bin chambers 402.3 is ensured to be consistent, a plurality of layers of first oscillation inhibiting fins 402.5 are arranged on the inner wall of the circulating liquid storage tank bin chamber 402.3 on the left, the lower sections of the inner walls of the rest circulating liquid storage tank liquid storage bin 402.3 are respectively provided with a layer of circulating liquid storage tank second swing inhibiting and isolating fins 402.6, a plurality of circulating liquid storage tank mesh partition plates 402.7 which are arranged at intervals are arranged above the circulating liquid storage tank second swing inhibiting and isolating fins 402.6, the peripheries of the circulating liquid storage tank mesh partition plates 402.6 are fixedly connected with the inner wall of the circulating liquid storage tank liquid storage bin 402.3, the circulating liquid storage tank second swing inhibiting and isolating fins 402.6 and the plurality of circulating liquid storage tank mesh partition plates 402.7 are respectively positioned at the same height as a plurality of circulating liquid storage tank first swing inhibiting and isolating fins 402.5 which are arranged from bottom to top, the internal stress of liquid swing can be eliminated by the circulating liquid storage tank first swing inhibiting and isolating fins 402.5, the circulating liquid storage tank second swing inhibiting and isolating fins 402.6 and the circulating liquid storage tank mesh partition plates 402.7, the up-down fluctuation of the liquid is inhibited. The number of the first oscillation suppressing and isolating fin 402.5 of the circulating liquid storage tank, the second oscillation suppressing and isolating fin 402.6 of the circulating liquid storage tank and the mesh partition 402.7 of the circulating liquid storage tank is determined according to the working liquid level of liquid in the body 402.1 of the circulating liquid storage tank, and in order to ensure stable oscillation suppressing effect, one to two layers of the first oscillation suppressing and isolating fin 402.5 of the circulating liquid storage tank and the second oscillation suppressing and isolating fin 402.6 of the circulating liquid storage tank can be additionally arranged above the mesh partition 402.7 or the fluctuation range of the liquid level of the circulating liquid storage tank.
A circulating liquid storage tank air inlet 402.8 is downwards arranged at the bottom of the right section of the circulating liquid storage tank body 402.1, a circulating liquid storage tank air outlet 402.9 is upwards arranged at the top of the right section of the circulating liquid storage tank body 402.1, a circulating liquid storage tank liquid outlet 402.10 is downwards arranged at the bottom of the middle section of the circulating liquid storage tank body 402.1, a circulating liquid storage tank pressure relief cover 402.11 is arranged at the top of the middle section of the circulating liquid storage tank body 402.1, a circulating liquid storage tank liquid level sensor 402.12 and a circulating liquid storage tank liquid adding pipe 402.13 are arranged in a circulating liquid storage tank chamber 402.3 at the left side, the top end of the circulating liquid storage tank liquid level sensor 402.12 is connected with the top of the circulating liquid storage tank body 402.1, the bottom end of the circulating liquid storage tank liquid adding pipe 402.13 extends out of the bottom of the circulating liquid storage tank body 402.1 and, liquid level fluctuation caused by liquid upwelling caused by filling liquid is effectively avoided;
a circulating liquid storage tank pressure sensor 402.14 is also arranged in the circulating liquid storage tank 402.
The working principle of the circulating liquid storage tank 402 is as follows: under the normal working state, the circulating liquid storage tank 402 keeps the electrolyte with the volume 2/3, oxyhydrogen gas generated by water electrolysis carries the electrolyte to enter the circulating liquid storage tank 402 through the air inlet 402.8 of the circulating liquid storage tank, the oxyhydrogen gas permeates the electrolyte in the circulating liquid storage tank 402 and is output through the air outlet 402.9 of the circulating liquid storage tank, and the electrolyte stored in the circulating liquid storage tank 402 outputs liquid to the liquid supplementing tank 405 through the liquid outlet 402.10 of the circulating liquid storage tank under the action of gravity. Under the condition that the vehicle continuously moves, the circulating liquid storage tank 402 can prevent liquid contained in the tank from shaking and fluctuation of the liquid level, avoid the liquid from overflowing into other pipelines, ensure the stability of the pressure and the liquid level in the circulating liquid storage tank and further avoid the signal error of the liquid level sensor 402.12 of the circulating liquid storage tank.
Referring to fig. 11 to 13, the gas cooling water filtering device 403 includes a cylindrical gas cooling water filtering device tank 403.1 arranged transversely, a gas cooling water filtering device gas inlet 403.2 is arranged at a lower section of a right side of the gas cooling water filtering device tank 403.1, a gas cooling water filtering device gas outlet 403.3 is arranged at an upper section of a left side of the gas cooling water filtering device tank 403.1, a gas cooling water filtering device liquid return port 403.4 is arranged at the bottom of the gas cooling water filtering device tank 403.1, a plurality of rectangular gas cooling water filtering device cooling fins 403.5 are extended outwards from an outer wall of a tank body of the gas cooling water filtering device tank 403.1 along a circumferential direction thereof, the plurality of gas cooling water filtering device cooling fins 403.5 are arranged at equal intervals, the gas cooling water filtering device cooling fins 403.5 are made of aluminum material, a plurality of circular gas cooling water filtering device wire meshes 403.6 are arranged in an inner cavity of the gas cooling water filtering device tank 403.1 along a length direction thereof, the wire nets 403.6 of the gas cooling water filtering device are arranged at equal intervals, and the wire net 403.6 of the gas cooling water filtering device is of a stainless steel woven net structure.
The working principle of the gas cooling water filtering device 403 is as follows: oxyhydrogen gas containing water vapor enters a gas cooling water filtering device tank body 403.1 through a gas cooling water filtering device gas inlet 403.2 and is output from a gas cooling water filtering device gas outlet 403.3, rapid heat dissipation of the gas cooling water filtering device tank body 403.1 is promoted through a gas cooling water filtering device heat dissipation sheet 403.5, when the oxyhydrogen gas with higher temperature flows through a gas cooling water filtering device wire mesh 403.6 with lower temperature in the gas cooling water filtering device tank body 403.1, the water vapor in the oxyhydrogen gas is condensed into water drops on the surface of the dense gas cooling water filtering device wire mesh 403.6, and the water drops are gathered together under the action of gravity and output through a gas cooling water filtering device liquid return port 403.4. The gas cooling water filtering device 403 has small volume, simple structure and easy processing, can reduce the content of water vapor and alkaline components in the oxyhydrogen gas, does not need to be additionally provided with a storage device to lead the oxyhydrogen gas out for cooling, and reduces the occupied space.
Referring to fig. 14-17, the gas drying means 404 comprises a vertically arranged cylindrical gas drying means kettle body 404.1, a gas drying means upper kettle lid 404.2 and a gas drying means lower kettle lid 404.3, the upper section and the lower section of the gas drying device kettle body 404.1 are respectively in threaded connection with the inner side edge of the upper kettle cover 404.2 of the gas drying device and the inner side edge of the lower kettle cover 404.3 of the gas drying device, the left side and the right side of the upper section of the gas drying device kettle body 404.1 are respectively provided with a gas drying device gas inlet 404.5 and a gas drying device gas outlet 404.6, the center of the inner cavity of the gas drying device kettle body 404.1 is provided with a vertical polygonal central gas chamber 404.4 of the gas drying device, a gas drying device liquid level sensor 404.17 is arranged in the gas chamber 404.4 in the center of the gas drying device, and the top end of the gas drying device liquid level sensor 404.17 is fixedly connected with the center of the upper pot cover 404.2 of the gas drying device;
a plurality of first risers 404.7 of the gas drying devices, a plurality of second risers 404.8 of the gas drying devices and two third risers 404.9 of the gas drying devices which are centrosymmetric are annularly arranged in an annular chamber between a central air chamber 404.4 of the gas drying device and a kettle body 404.1 of the gas drying device, a first opening 404.10 of the gas drying device is arranged in the middle of the top end of the first riser 404.7 of the gas drying device, a second opening 404.11 of the gas drying device is arranged in the middle of the bottom end of the second riser 404.8 of the gas drying device, the two third risers 404.9 of the gas drying devices are respectively arranged at the front side of an air inlet 404.5 of the gas drying device and the rear side of an air outlet 404.6 of the gas drying device, the first risers 404.7 of the gas drying devices and the second risers 404.8 of the gas drying devices are arranged in a staggered manner and are arranged at equal intervals at the front section and the rear section of an annular chamber between the third risers 404.9 of the gas drying, wherein, the third riser 404.9 of the gas drying device positioned in front of the gas inlet 404.5 of the gas drying device, the outer side surface of the central air chamber 404.4 of the gas drying device, the first riser 404.7 of the gas drying device and the inner side surface of the kettle body 404.1 of the gas drying device form a gas drying device inlet 404.12 communicated with the gas inlet 404.5 of the gas drying device, the third riser 404.9 of the gas drying device positioned behind the gas outlet 404.6 of the gas drying device, the outer side surface of the central air chamber 404.4 of the gas drying device, the second riser 404.8 of the gas drying device and the inner side surface of the kettle body 404.1 of the gas drying device form a gas drying device outlet 404.13 communicated with the gas outlet 404.6 of the gas drying device, and the first riser 404.7 of the gas drying device, the outer side surface of the central air chamber 404.4 of the gas drying device, the second riser 404.8 of the gas drying device and the inner side surface of the kettle body 404.1 of the gas, the gas drying device inlet chamber 404.12, the gas drying device outlet chamber 404.13 and the gas drying device gas chamber 404.14 have the same volume capacity;
the top end and the bottom end of the gas drying device central gas chamber 404.4 are respectively provided with a gas drying device third notch 404.15 and a gas drying device fourth notch 404.16, the gas drying device third notch 404.15 is positioned in the gas drying device gas chamber 404.14 close to the front side of the gas drying device inlet chamber 404.12, and the gas drying device fourth notch 404.16 is positioned in the gas drying device gas chamber 404.14 close to the rear side of the gas drying device outlet chamber 404.13;
a transverse first baffle 404.18 of the gas drying device is arranged at the bottom section of the central gas chamber 404.4 of the gas drying device, a plurality of air holes are formed in the surface of the first baffle 404.18 of the gas drying device, and the first baffle 404.18 of the gas drying device is positioned above a fourth notch 404.16 of the gas drying device; the bottom end of the gas inlet chamber 404.12 of the gas drying device is provided with a second baffle 404.19 of the gas drying device; the top section of the gas chamber 404.14 of the gas drying device, which is arranged next to the rear side of the gas inlet chamber 404.12 of the gas drying device, is provided with a transverse third clapboard 404.20 of the gas drying device, and the third clapboard 404.20 of the gas drying device is positioned below the first notch 404.10 of the gas drying device; the middle section of the inner cavity of the gas drying device outlet chamber 404.13 is provided with a transverse gas drying device fourth partition plate 404.21, and the gas drying device fourth partition plate 404.21 divides the inner cavity of the gas drying device outlet chamber 404.13 into an upper cavity and a lower cavity; a plurality of air holes are formed in the surfaces of the third partition 404.20 and the fourth partition 404.21 of the gas drying device, and desiccants 404.21 are placed in the inner cavity of the gas chamber 404.14 of the gas drying device and the lower cavity of the gas outlet chamber 404.13 of the gas drying device;
when a worker places the desiccant 404.21 into the gas drying device kettle 404.1, the gas drying device kettle 404.1 needs to be placed upside down, the first partition 404.18 of the gas drying device is used for blocking the desiccant 404.21 from entering the central air chamber 404.4 of the gas drying device, the second partition 404.19 of the gas drying device enables the gas drying device inlet chamber 404.12 to form an independent water accumulation space, and blocks the desiccant 404.21 from entering the gas drying device inlet chamber 404.12, the fourth partition 404.21 of the gas drying device is used for blocking the desiccant 404.21 from entering the upper cavity of the gas drying device outlet chamber 404.13, so that the desiccant 404.21 is prevented from blocking the gas drying device outlet 404.6, and the third partition 404.20 of the gas drying device is used for blocking the desiccant 404.21 in the corresponding gas drying device air chamber 404.14 from entering the gas drying device inlet chamber 404.12, so as to prevent the desiccant 404.21 from blocking the gas drying device inlet 404.5;
a gas drying device sealing gasket 404.22 is respectively arranged between the top end and the bottom end of the gas drying device kettle body 404.1 and the upper kettle cover 404.2 of the gas drying device and the lower kettle cover 404.3 of the gas drying device;
the upper end face and the lower end face of the central air chamber 404.4 of the gas drying device, the air inlet chamber 404.12 of the gas drying device, the air outlet chamber 404.13 of the gas drying device and the air chamber 404.14 of the gas drying device are respectively provided with a sealing strip 404.23 of the gas drying device, and the independence among the air chambers is ensured through the sealing match between the sealing strips 404.23 of the gas drying device and the sealing pads 404.22 of the gas drying device.
The working principle of the gas drying device 404 is as follows: oxyhydrogen gas with water vapor enters an air inlet chamber 404.12 of the gas drying device through an air inlet 404.5 of the gas drying device, part of the water vapor forms small water drops when being cooled and deposits in an air inlet chamber 404.12 of the gas drying device, the oxyhydrogen gas with the water vapor sequentially flows through an air chamber 404.14 of the gas drying device at the rear section of a kettle body 404.1 of the gas drying device in an S shape through a first notch 404.10 of the gas drying device and a second notch 404.11 of the gas drying device, then flows through a fourth notch 404.16 of the gas drying device into a central air chamber 404.4 of the gas drying device, flows through a third notch 404.15 of the gas drying device into an air chamber 404.14 of the gas drying device at the front side of the air inlet chamber 404.12 of the gas drying device, and sequentially flows through the air chamber 404.14 of the gas drying device at the front section of the kettle body 404.1 of the gas drying device in an S shape through the first notch 404.10 of the gas drying device and the second notch 404.11, finally enters the gas outlet chamber 404.13 of the gas drying device and is output through the gas outlet 404.6 of the gas drying device. When the desiccant 404.21 fails or the drying capacity is insufficient, water vapor in oxyhydrogen gas cannot be sucked out in time, the time is long, the water level of accumulated water in the central air chamber 404.4 of the gas drying device gradually rises, and when a floating ball in the liquid level sensor 404.17 of the gas drying device reaches a high liquid level, the liquid level sensor 404.17 of the gas drying device feeds back a signal to the control unit 100, starts an alarm function and triggers further protection measures. The gas drying device 404 has two functions of gas drying and failure alarm, ensures small volume, increases effective path and area of contact between the drying agent and the gas, prolongs the replacement period of the drying agent, is convenient for replacing the drying agent due to the structural design, and can automatically alarm and trigger further protection measures when the drying agent fails or the drying capacity is insufficient.
The liquid supplementing tank 405 comprises a vertically-arranged liquid supplementing tank body 405.1, a liquid supplementing tank water filling port 405.2 is arranged at the top of the liquid supplementing tank body 405.1, a liquid supplementing tank water outlet 405.3 is arranged at the lower section of the liquid supplementing tank body 405.1, a cooling spiral pipe 405.4 is arranged in an inner cavity of the liquid supplementing tank body 405.1 from top to bottom, the upper end port of the cooling spiral pipe 405.4 is set as a cooling spiral pipe liquid inlet 405.5, the upper end port of the cooling spiral pipe 405.4 extends out of the upper section of the liquid supplementing tank body 405.1, the lower end port of the cooling spiral pipe 405.4 is set as a cooling spiral pipe liquid outlet 405.6, the lower end port of the cooling spiral pipe 405.4 extends out of the lower section of the liquid supplementing tank body 405.1, and a liquid supplementing tank liquid level sensor 405.7 and a liquid supplementing tank temperature sensor 405.8 are further arranged in the inner cavity of;
the liquid replenishing tank body 405.1 is filled with normal-temperature raw material water, and the cooling spiral pipe 405.4 is soaked in the normal-temperature raw material water.
The connection relationship among the water electrolysis tank 401, the circulating liquid storage tank 402, the gas cooling water filtering device 403, the gas drying device 404 and the liquid supplementing tank 405 is as follows:
the water electrolysis bath outlet 401.11 is connected with the circulating liquid storage tank inlet 402.8 through a first pipeline, the circulating liquid storage tank outlet 402.9 is connected with the gas cooling water filtering device inlet 403.2 through a second pipeline, the gas cooling water filtering device outlet 403.3 is connected with the gas drying device inlet 404.5 through a third pipeline, the gas drying device outlet 404.6 introduces the dried oxyhydrogen gas into the gas inlet pipeline of the engine 102, the gas cooling water filtering device liquid return port 403.4, the circulating liquid storage tank outlet 402.10 and the cooling spiral pipe inlet 405.5 are connected through a fourth pipeline, the cooling spiral pipe outlet 405.6 is connected with the water electrolysis bath liquid return port 401.9 through a fifth pipeline, the water electrolysis bath liquid outlet 401.10 is connected with a liquid discharge valve 406 through a sixth pipeline, the liquid supplementing tank outlet 405.3 is connected with the bottom end of the circulating liquid storage tank charging pipe 402.13 through a seventh pipeline, the seventh pipeline is provided with a water adding pump 407 and an electric stop valve 408.
The working principle of the oil-saving emission-reducing device of the internal combustion engine for the vehicle is as follows:
the water electrolysis tank 401 starts to electrolyze water and timely generates oxyhydrogen gas with water vapor, the oxyhydrogen gas with water vapor is gathered to the top, enters the circulating liquid storage tank 402 from a gas outlet 401.11 of the water electrolysis tank through a first pipeline from a gas inlet 402.8 of the circulating liquid storage tank, permeates electrolyte in the circulating liquid storage tank 402, is gathered at the top in the circulating liquid storage tank 402, enters the gas cooling and water filtering device 403 from a gas outlet 402.9 of the circulating liquid storage tank through a second pipeline from a gas inlet 403.2 of the gas cooling and water filtering device, enters the gas drying device 404 from a gas outlet 403.3 of the gas cooling and water filtering device through a third pipeline from a gas inlet 404.5 of the gas drying device, is dried by a drying agent 404.21 in the drying device 404, and is output to a gas inlet pipeline of the engine 102 from a gas outlet 404.6 of the gas drying device, finally enters an engine cylinder along with air;
when oxyhydrogen gas with water vapor enters the gas cooling water filtering device 403, the water vapor condenses into liquid when meeting cold, gathers at the bottom of the gas cooling water filtering device 403, enters the cooling spiral tube 405.4 through the fourth pipeline and the cooling spiral tube inlet 405.5 through the liquid return port 403.4 of the gas cooling water filtering device, and flows back to the water electrolyzer 401 through the water electrolyzer return port 401.9 through the fifth pipeline and the cooling spiral tube outlet 405.6;
during the electrochemical reaction of water electrolysis, a large amount of heat energy can be released to cause the temperature of the electrolyte in the water electrolysis cell 401 to continuously rise, oxyhydrogen gas generated in the water electrolysis cell 401 enters the circulating liquid storage tank 402 from the air outlet 401.11 of the water electrolysis cell through the first pipeline from the air inlet 402.8 of the circulating liquid storage tank, simultaneously, due to the action of the internal pressure and air flow of the water electrolysis cell 401, high-temperature electrolyte at the upper part in the water electrolysis cell 401 is brought into the circulating liquid storage tank 402 in a gas-liquid mixing mode, after the electrolyte in the circulating liquid storage tank 402 is cooled slightly, the cooled electrolyte enters the cooling spiral tube 405.4 from the liquid outlet 402.10 of the circulating liquid storage tank through the fourth pipeline from the liquid inlet 405.5 of the cooling spiral tube under the action of self gravity, as the liquid supplementing tank 405 is filled with normal-temperature raw material water, the high-temperature electrolyte in the cooling spiral tube 405.4 can be fully cooled, and the cooled electrolyte flows back to the water electrolysis cell from the liquid 401, an electrolytic reaction is performed. Thus, the circulation cooling is continued.
Along with the continuous continuation of the electrolytic reaction, the electrolyte in the water electrolysis tank 401 is continuously consumed, so that the liquid level of the electrolyte in the circulating liquid storage tank 402 is continuously reduced, when the liquid level of the electrolyte is reduced to a set liquid level low level, an alarm signal is triggered, the control unit 200 controls the water adding pump 407 to start, and simultaneously controls the electric stop valve 408 to open, so that normal-temperature raw water in the liquid supplementing tank 405 is pumped into the circulating liquid storage tank 402 from the bottom end of the liquid adding pipe 402.13 of the circulating liquid storage tank through a seventh pipeline through a liquid supplementing tank water outlet 405.3, and along with the rise of the liquid level in the circulating liquid storage tank 402, when the liquid level reaches a set liquid level high level, the alarm signal is triggered, the control unit 200 controls the water adding pump 407 to close.
In the output process of oxyhydrogen gas, if gas is not smoothly discharged due to pipeline blockage, the gas pressure in the circulating liquid storage tank 402 and the gas cooling water filtering device 403 can be continuously increased, the gas pressure change condition in the circulating liquid storage tank 402 is monitored in real time through the circulating liquid storage tank pressure sensor 402.14, when the gas pressure in the circulating liquid storage tank 402 reaches the alarm upper limit pressure value, a signal is triggered to alarm, the control unit 200 controls the intelligent controllable electrolytic power supply 300 to stop supplying power in time, and the whole vehicle internal combustion engine energy-saving and emission-reducing device 400 is closed to stop generating gas; when the pressure sensor 402.14 of the circulating liquid storage tank fails or the control unit 200 fails and pressure cannot be protected and monitored, because the pressure relief cover 402.11 of the circulating liquid storage tank 402 is arranged at the top of the circulating liquid storage tank 402, when the gas pressure in the circulating liquid storage tank 402 reaches the alarm upper limit pressure value, a protection spring in the pressure relief cover 402.11 of the circulating liquid storage tank is compressed under the action of pressure, so that a pressure relief opening is opened, and the pressure is automatically reset after the pressure is released.
The working principle of an automatic control system of an energy-saving device of an internal combustion engine for a vehicle is as follows:
the control unit firstly detects the starting and stopping states of the vehicle, and performs parameter pre-detection on the vehicle and the hydrogen-oxygen assisted fuel-saving and emission-reducing device of the internal combustion engine for the vehicle after the vehicle is powered on;
when the engine is in a vehicle-mounted starting state, the control unit enters a normal running mode, and judges the working conditions (idling and normal running) of the engine according to the detection information of the vehicle sensor and the external sensor;
when the vehicle starts to run normally, the control unit collects, analyzes and calculates data of each sensor in real time, and judges the working condition, the running environment, the road and the traffic condition of the vehicle in real time (the working condition of the vehicle comprises the running states of starting, accelerating, uniform speed, decelerating and the like of the vehicle;
meanwhile, the control unit collects the voltage and the current value of the intelligent controllable electrolytic power supply in real time, outputs the current value calibrated in different states of the working condition, the driving environment, the road, the traffic state and the like of the vehicle according to the collection and analysis of various parameters and the strategy set by the program, and when the electrolytic current value changes, the gas production of the water electrolysis bath also changes along with the change of the electrolytic current value, thereby realizing the control of the gas supply of the oil-saving and emission-reducing device of the internal combustion engine for the vehicle.
The control unit is used for collecting, analyzing and calculating data of each sensor in the oil-saving and emission-reducing device of the internal combustion engine for the vehicle in real time, judging the running condition of the device in real time, identifying various alarming and fault states, controlling each execution element to carry out corresponding processing action in time and ensuring the normal running and fault alarming of the whole device.
The control unit can be in communication connection with the background data server in real time through a network, records relevant information (such as vehicle speed, position, interval track and the like) of a vehicle, various parameters (such as running start-stop state, internal element execution action record, alarm, fault code and the like) in the oil-saving and emission-reducing device of the internal combustion engine for the vehicle, records data such as device maintenance record and the like in real time, and timely pushes items needing to be processed to network terminals such as sales and after-sales services.
The above is only a specific application example of the present invention, and does not constitute any limitation to the protection scope of the present invention. All the technical solutions formed by equivalent transformation or equivalent replacement fall within the protection scope of the present invention.

Claims (5)

1. A gas cooling water filtering device is characterized in that: the gas cooling water filtering device comprises a transversely arranged gas cooling water filtering device tank body, wherein a gas cooling water filtering device liquid return port is formed in the bottom of the gas cooling water filtering device tank body, a plurality of rectangular gas cooling water filtering device radiating fins outwards extend from the outer wall of the tank body of the gas cooling water filtering device tank body along the circumferential direction of the tank body, the plurality of gas cooling water filtering device radiating fins are arranged at equal intervals, and a plurality of gas cooling water filtering device wire nets are arranged at intervals in the inner cavity of the gas cooling water filtering device tank body along the length direction of the inner cavity of the gas cooling water filtering.
2. A gas cooling water filtering device according to claim 1, wherein: and a gas cooling water filtering device gas inlet is formed in one side surface of the gas cooling water filtering device tank body, and a gas cooling water filtering device gas outlet is formed in the other side surface of the gas cooling water filtering device tank body.
3. A gas cooling water filtering device according to claim 1, wherein: the tank body of the gas cooling water filtering device is of a cylindrical structure.
4. A gas cooling water filtering device according to claim 1, wherein: the wire mesh of the gas cooling water filtering device adopts a stainless steel woven mesh structure.
5. A gas cooling water filtering device according to claim 1, wherein: the radiating fins of the gas cooling water filtering device are made of aluminum materials.
CN201920552833.7U 2019-04-23 2019-04-23 Gas cooling water filtering device Expired - Fee Related CN210097294U (en)

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Cited By (3)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109893959A (en) * 2019-04-23 2019-06-18 江苏博润通科技有限公司 A kind of gas cooling water treatment plant
CN109915286A (en) * 2019-04-23 2019-06-21 江苏博润通科技有限公司 Circulation fluid reservoir is swung in automobile-used oxyhydrogen generator suppression
CN109931172A (en) * 2019-04-23 2019-06-25 江苏博润通科技有限公司 Vehicular internal combustion engine energy saver automatic control system

Cited By (4)

* Cited by examiner, † Cited by third party
Publication number Priority date Publication date Assignee Title
CN109893959A (en) * 2019-04-23 2019-06-18 江苏博润通科技有限公司 A kind of gas cooling water treatment plant
CN109915286A (en) * 2019-04-23 2019-06-21 江苏博润通科技有限公司 Circulation fluid reservoir is swung in automobile-used oxyhydrogen generator suppression
CN109931172A (en) * 2019-04-23 2019-06-25 江苏博润通科技有限公司 Vehicular internal combustion engine energy saver automatic control system
CN109931172B (en) * 2019-04-23 2024-11-01 江苏博润通科技有限公司 Automatic control system for energy-saving device of internal combustion engine for vehicle

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