CN114100388B - Gas-liquid mixing and pressurizing device for gas turbine - Google Patents
Gas-liquid mixing and pressurizing device for gas turbine Download PDFInfo
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- CN114100388B CN114100388B CN202111150007.8A CN202111150007A CN114100388B CN 114100388 B CN114100388 B CN 114100388B CN 202111150007 A CN202111150007 A CN 202111150007A CN 114100388 B CN114100388 B CN 114100388B
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
- F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
- F02C7/08—Heating air supply before combustion, e.g. by exhaust gases
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
- F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
- F02C7/22—Fuel supply systems
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02C—GAS-TURBINE PLANTS; AIR INTAKES FOR JET-PROPULSION PLANTS; CONTROLLING FUEL SUPPLY IN AIR-BREATHING JET-PROPULSION PLANTS
- F02C7/00—Features, components parts, details or accessories, not provided for in, or of interest apart form groups F02C1/00 - F02C6/00; Air intakes for jet-propulsion plants
- F02C7/22—Fuel supply systems
- F02C7/224—Heating fuel before feeding to the burner
Abstract
The invention discloses a gas-liquid mixing and pressurizing device for a gas turbine. The gas-liquid mixing and pressurizing device for the gas turbine comprises a pair of mixing boxes, a gas turbine, a liquid raw material box and a production support, wherein the pair of mixing boxes, the gas turbine and the liquid raw material box are arranged on the production support, a transfer structure is arranged on the production support and connected to the pair of mixing boxes and the gas turbine, a pressurizing mixing structure is arranged in the pair of mixing boxes, a heat circulation structure is arranged on the gas turbine, and the heat circulation structure is connected to the transfer structure.
Description
Technical Field
The invention relates to the technical field of heat mixing of gas turbines, in particular to a gas-liquid mixing and pressurizing device for a gas turbine.
Background
The Gas Turbine (Gas Turbine) is an internal combustion type power machine which takes continuously flowing Gas as working medium to drive an impeller to rotate at high speed and convert the energy of fuel into useful work, and is a rotary impeller type heat engine, and the working process of the Gas Turbine is that a Gas compressor (i.e. a compressor) continuously sucks air from the atmosphere and compresses the air; the compressed air enters a combustion chamber, is mixed with injected fuel and combusted to become high-temperature fuel gas, and then flows into a gas turbine to expand and do work so as to push a turbine impeller to rotate together with a compressor impeller; the working capacity of the heated high-temperature gas is obviously improved, so that the gas turbine drives the gas compressor and simultaneously has residual work as output mechanical work of the gas turbine. When gas and liquid are mixed, because the gas and liquid are mixed and extruded into the gas turbine after atomization spraying is needed, the phenomenon of uneven liquid drainage is easy to occur in the extrusion process, and the phenomenon of incomplete supporting combustion or insufficient fuel occurs.
Disclosure of Invention
The technical scheme of the invention for achieving the purpose is as follows: the gas-liquid mixing and pressurizing device for the gas turbine comprises a pair of mixing boxes, a gas turbine, a liquid raw material box and a production bracket, wherein the pair of mixing boxes, the gas turbine and the liquid raw material box are arranged on the production bracket, a transfer structure is arranged on the production bracket and connected to the pair of mixing boxes and the gas turbine, a pressurizing mixing structure is arranged in the pair of mixing boxes, a heat circulation structure is arranged on the gas turbine, and the heat circulation structure is connected to the transfer structure;
the pressurized mixing structure comprises: the device comprises a pair of pressurizing driving machines, a pair of pressurizing transmission bevel gears, a pair of pressurizing driving bevel gears, a pair of pressurizing threaded pipes, a pair of pressurizing threaded rods, a pair of pressurizing extrusion plates, a pair of concave driving annular blocks, a plurality of concave transmission annular blocks, a pair of driving circular disks, a plurality of transmission circular disks, a plurality of driving magnet blocks, a pair of stirring driving machines, a pair of stirring driving bevel gears, a pair of stirring transmission circular bevel gears and a plurality of stirring sheets;
the pair of pressurizing driving machines are respectively arranged at the top ends of the pair of mixing boxes, the pair of pressurizing threaded pipes are respectively inserted on the pair of mixing boxes through bearings, the pair of pressurizing threaded rods are respectively movably inserted on the inner sides of the pair of pressurizing threaded pipes, the pair of pressurizing driving bevel gears are respectively arranged at the driving ends of the pair of pressurizing driving machines, the pair of pressurizing driving bevel gears are respectively meshed with the pair of pressurizing driving bevel gears, the pair of pressurizing extrusion plates are respectively arranged at the pair of pressurizing threaded rods, the pair of concave driving circular blocks are respectively arranged at the top ends of the pair of pressurizing extrusion plates, the pair of driving circular blocks are respectively movably inserted on the inner sides of the pair of concave driving circular blocks, the plurality of concave driving circular blocks are respectively circularly arranged on the pair of pressurizing extrusion plates, the plurality of driving circular blocks are respectively movably inserted on the inner sides of the pair of concave driving circular blocks, the pair of bevel gears are respectively meshed with the pair of bevel gears, the pair of driving circular blocks are respectively arranged on the pair of driving circular blocks, the pair of driving circular blocks are respectively meshed with the pair of driving circular blocks, the pair of driving circular blocks are respectively arranged on the pair of circular blocks, the pair of driving circular blocks are respectively meshed with the pair of driving circular blocks, and the pair of driving circular blocks are respectively.
Preferably, the transfer structure comprises: the device comprises a pair of liquid transfer boxes, a pair of air transfer boxes, a hydraulic box, a liquid pump, a hydraulic shunt pipe, two pairs of extrusion hydraulic cylinders, two pairs of centering extrusion plates, two pairs of transfer valves and a pair of feeding sealing valves;
the device comprises a production support, a pair of liquid transfer boxes and a pair of air transfer boxes, wherein the production support is provided with a pair of liquid transfer boxes and a pair of air transfer boxes, the pair of liquid transfer boxes and the pair of air transfer boxes are respectively provided with transfer valves, the other ends of the pair of transfer valves are respectively connected to the pair of mixing boxes, the pair of feeding sealing valves are respectively provided with the pair of mixing boxes, the pair of feeding sealing valves are respectively connected to a gas turbine, the pair of extrusion hydraulic cylinders are respectively provided with the pair of liquid transfer boxes and the pair of air transfer boxes, the pair of transfer extrusion plates are respectively provided with the two pairs of extrusion hydraulic cylinders at the pushing ends, the hydraulic boxes are provided with the production support, the liquid pumping pump is provided with the hydraulic pump, and the hydraulic shunt pipes are respectively connected to the pushing ends of the two pairs of extrusion hydraulic cylinders.
Preferably, the heat circulation structure comprises: the heat dissipation device comprises an exhaust pipe, an air extracting pump, an exhaust valve, four pairs of exhaust shunt pipes, a plurality of heat dissipation pipes, two pairs of square limiting blocks and a plurality of heat dissipation circular ring sheets;
the exhaust pipe is installed on the gas turbine, the air pump is installed on the exhaust pipe, the exhaust valve is installed on the air pump, four pairs of exhaust shunt pipes are respectively inserted on two sides of the liquid transfer box and the air transfer box, and four pairs of exhaust shunt pipes are respectively connected to the exhaust valve, a plurality of radiating pipes are respectively connected to four pairs of exhaust shunt pipes, a plurality of radiating circular ring sheets are respectively installed on a plurality of radiating pipes, and two pairs of return-shaped limiting blocks are respectively installed on a pair of liquid transfer box and a pair of air transfer box.
Preferably, pressure sensors are respectively arranged on the inner sides of the pair of mixing boxes, the pair of liquid transfer boxes and the pair of air transfer boxes.
Preferably, the outer sides of the exhaust pipe and the four pairs of exhaust shunt pipes are provided with heat insulation layers.
Preferably, a pair of coiled pipes are respectively arranged on the inner sides of the pair of mixing boxes, and the two pairs of coiled pipes are respectively connected to the two pairs of transfer valves.
Preferably, plastic layers are arranged on the outer sides of the concave transmission circular blocks.
Preferably, the inner sides of the concave transmission circular blocks and the pair of concave driving circular blocks are respectively provided with an auxiliary ball groove, the auxiliary ball grooves are respectively provided with a plastic ball groove pad, and the inner sides of the plastic ball groove pads are respectively provided with a plastic ball.
Preferably, the inner sides of the pair of mixing boxes, the pair of liquid transfer boxes and the pair of air transfer boxes are respectively provided with temperature sensors.
Preferably, a pair of liquid level meters are respectively arranged on the liquid transfer boxes.
The gas-liquid mixing and pressurizing device for the gas turbine, which is manufactured by the technical scheme of the invention, generates high-speed rotating air flow in the mixing box by the pressurizing and mixing structure, avoids the phenomenon that liquid is directly atomized and extruded in the mixing box to generate gas-liquid mixing non-uniformity, water vapor can be liquefied into small water drops when meeting cold and is attached to the inner side of the mixing box, and the phenomenon that the gas turbine burns non-uniformly or is insufficient in fuel is generated in the using process.
Drawings
FIG. 1 is a schematic diagram of a gas-liquid mixing and pressurizing device for a gas turbine according to the present invention.
FIG. 2 is a schematic side view of a gas-liquid mixing and pressurizing device for a gas turbine according to the present invention.
Fig. 3 is a schematic top view of a gas-liquid mixing and pressurizing device for a gas turbine according to the present invention.
Fig. 4 is an enlarged view of the structure of the "a" portion in fig. 1.
Fig. 5 is an enlarged view of the structure of the "B" portion in fig. 3.
In the figure: 1. a mixing box; 2. a gas turbine; 3. a liquid raw material tank; 4. producing a bracket; 5. feeding and sealing the valve; 6. a pressurized drive; 7. a pressurized transmission helical gear; 8. a helical gear is driven in a pressurizing manner; 9. pressurizing the threaded pipe; 10. pressurizing a threaded rod; 11. a pressurizing extrusion plate; 12. a concave driving ring block; 13. concave transmission circular ring blocks; 14. driving the circular disc; 15. a drive disc; 16. driving the magnet block; 17. a transmission magnet block; 18. a stirring driver; 19. stirring and driving a bevel gear; 20. stirring transmission spiral gear; 21. stirring sheets; 22. a liquid transfer box; 23. an air transfer box; 24. a hydraulic tank; 25. a liquid pump; 26. a hydraulic shunt; 27. extruding a hydraulic cylinder; 28. a transfer extrusion plate; 29. and (5) transferring the valve.
Detailed Description
The invention is specifically described below with reference to the accompanying drawings, as shown in fig. 1-5, a gas-liquid mixing and pressurizing device for a gas turbine 2, which comprises a pair of mixing boxes 1, a gas turbine 2, a liquid raw material box 3 and a production bracket 4, wherein the pair of mixing boxes 1, the gas turbine 2 and the liquid raw material box 3 are arranged on the production bracket 4, a transfer structure is arranged on the production bracket 4 and is connected to the pair of mixing boxes 1 and the gas turbine 2, a pressurizing mixing structure is arranged in the pair of mixing boxes 1, a heat circulation structure is arranged on the gas turbine 2, and the heat circulation structure is connected to the transfer structure; the pressurized mixing structure comprises: a pair of pressurizing driving machines 6, a pair of pressurizing driving bevel gears 7, a pair of pressurizing driving bevel gears 8, a pair of pressurizing threaded pipes 9, a pair of pressurizing threaded rods 10, a pair of pressurizing extrusion plates 11, a pair of concave driving annular blocks 12, a plurality of concave driving annular blocks 13, a pair of driving circular disks 14, a plurality of driving circular disks 15, a plurality of driving magnet blocks 16, a plurality of driving magnet blocks 17, a pair of stirring driving machines 18, a pair of stirring driving bevel gears 19, a pair of stirring driving circular bevel gears 20 and a plurality of stirring sheets 21; a pair of pressurizing driving machines 6 are respectively arranged on the top ends of the pair of mixing boxes 1, a pair of pressurizing threaded pipes 9 are respectively inserted on the pair of mixing boxes 1 through bearings, a pair of pressurizing threaded rods 10 are respectively movably inserted on the inner sides of the pair of pressurizing threaded pipes 9, a pair of pressurizing driving bevel gears 8 are respectively arranged on the driving ends of the pair of pressurizing driving machines 6, the pair of pressurizing driving bevel gears 8 are respectively meshed with the pair of pressurizing driving bevel gears 7, a pair of pressurizing extrusion plates 11 are respectively arranged on the pair of pressurizing threaded rods 10, a pair of concave driving circular ring blocks 12 are respectively arranged on the top ends of the pair of pressurizing extrusion plates 11, a pair of driving circular discs 14 are respectively movably inserted on the inner sides of the pair of concave driving circular ring blocks 12, the concave transmission circular blocks 13 are respectively circularly arranged on the pair of pressurizing extrusion plates 11, the transmission circular disks 15 are respectively movably inserted into the inner sides of the concave transmission circular blocks 13, the stirring transmission circular bevel gears 20 are respectively arranged on the pair of driving circular disks 14, the stirring driver 18 is respectively arranged on the pair of concave driving circular blocks 12, the stirring driver bevel gears 19 are respectively arranged on the driving ends of the pair of stirring driver 18, the stirring driver bevel gears 19 are respectively meshed with the stirring transmission circular bevel gears 20, the driving magnet blocks 16 are respectively arranged on the pair of driving circular disks 14, the transmission magnet blocks 17 are respectively arranged on the transmission circular disks 15, the stirring blades 21 are respectively arranged on the transmission discs 15; the transfer structure comprises: a pair of liquid transfer boxes 22, a pair of air transfer boxes 23, a hydraulic box 24, a liquid pump 25, a hydraulic shunt pipe 26, two pairs of extrusion hydraulic cylinders 27, two pairs of transfer extrusion plates 28, two pairs of transfer valves 29 and a pair of feeding sealing valves 5; the pair of liquid transfer tanks 22 and the pair of air transfer tanks 23 are mounted on the production support 4, the two pairs of transfer valves 29 are respectively mounted on the pair of liquid transfer tanks 22 and the pair of air transfer tanks 23, the other ends of the two pairs of transfer valves 29 are respectively connected to the pair of mixing tanks 1, the pair of feeding sealing valves 5 are respectively mounted on the pair of mixing tanks 1, the pair of feeding sealing valves 5 are respectively connected to the gas turbine 2, the two pairs of extrusion hydraulic cylinders 27 are respectively mounted on the inner sides of the pair of liquid transfer tanks 22 and the pair of air transfer tanks 23, the two pairs of transfer plates 28 are respectively mounted on the pushing ends of the two pairs of extrusion hydraulic cylinders 27, the hydraulic tank 24 is mounted on the production support 4, the liquid pump 25 is mounted on the hydraulic tank 24, the hydraulic shunt pipes 26 are mounted on the liquid pump 25, and the hydraulic shunt pipes 26 are respectively connected to the hydraulic ends of the two pairs of extrusion hydraulic cylinders 27; the heat circulation structure comprises: the heat dissipation device comprises an exhaust pipe, an air extracting pump, an exhaust valve, four pairs of exhaust shunt pipes, a plurality of heat dissipation pipes, two pairs of square limiting blocks and a plurality of heat dissipation circular ring sheets; the exhaust pipe is arranged on the gas turbine 2, the air pump is arranged on the exhaust pipe, the exhaust valve is arranged on the air pump, four pairs of exhaust shunt pipes are respectively inserted on two sides of a pair of liquid transfer boxes 22 and a pair of air transfer boxes 23, the four pairs of exhaust shunt pipes are respectively connected to the exhaust valve, a plurality of radiating pipes are respectively connected to the four pairs of exhaust shunt pipes, a plurality of radiating circular ring sheets are respectively arranged on the plurality of radiating pipes, and two pairs of return limiting blocks are respectively arranged on the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23; the inner sides of the pair of mixing boxes 1, the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 are respectively provided with pressure sensors; the outer sides of the exhaust pipe and the four pairs of exhaust shunt pipes are provided with heat insulation layers; a pair of coiled pipes are respectively arranged on the inner sides of the pair of mixing boxes 1, and the two pairs of coiled pipes are respectively connected to the two pairs of transit valves 29; the outer sides of the concave transmission circular blocks 13 are provided with plastic layers; auxiliary ball grooves are respectively formed in the inner sides of the concave transmission ring blocks 13 and the pair of concave driving ring blocks 12, plastic ball groove pads are respectively arranged in the auxiliary ball grooves, and plastic balls are respectively arranged in the inner sides of the plastic ball groove pads; temperature sensors are respectively arranged on the inner sides of the pair of mixing boxes 1, the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23; a pair of liquid level gauges are respectively provided on the liquid transfer boxes 22.
The embodiment is characterized by comprising a pair of mixing boxes, a gas turbine, a liquid raw material box and a production bracket, wherein the pair of mixing boxes, the gas turbine and the liquid raw material box are arranged on the production bracket, a transfer structure is arranged on the production bracket and connected to the pair of mixing boxes and the gas turbine, a pressurizing mixing structure is arranged in the pair of mixing boxes, a heat circulation structure is arranged on the gas turbine, and the heat circulation structure is connected to the transfer structure; the pressurized mixing structure comprises: the device comprises a pair of pressurizing driving machines, a pair of pressurizing transmission bevel gears, a pair of pressurizing driving bevel gears, a pair of pressurizing threaded pipes, a pair of pressurizing threaded rods, a pair of pressurizing extrusion plates, a pair of concave driving annular blocks, a plurality of concave transmission annular blocks, a pair of driving circular disks, a plurality of transmission circular disks, a plurality of driving magnet blocks, a pair of stirring driving machines, a pair of stirring driving bevel gears, a pair of stirring transmission circular bevel gears and a plurality of stirring sheets; the pair of pressurizing driving machines are respectively arranged at the top ends of the pair of mixing boxes, the pair of pressurizing threaded pipes are respectively inserted on the pair of mixing boxes through bearings, the pair of pressurizing threaded rods are respectively movably inserted on the inner sides of the pair of pressurizing threaded pipes, the pair of pressurizing driving bevel gears are respectively arranged at the driving ends of the pair of pressurizing driving machines, the pair of pressurizing driving bevel gears are respectively meshed with the pair of pressurizing transmission bevel gears, the pair of pressurizing extrusion plates are respectively arranged on the pair of pressurizing threaded rods, the pair of concave driving circular blocks are respectively arranged at the top ends of the pair of pressurizing extrusion plates, the pair of driving circular blocks are respectively movably inserted on the inner sides of the pair of concave driving circular blocks, the plurality of concave driving circular blocks are respectively circularly arranged on the pair of pressurizing plates, the plurality of driving circular blocks are respectively movably inserted on the inner sides of the plurality of concave driving circular blocks, the pair of stirring driving circular bevel gears are respectively arranged on the pair of driving circular blocks, the pair of stirring driving circular bevel gears are respectively meshed with the pair of driving circular bevel gears of the pair of stirring driving circular blocks, the pair of stirring driving circular blocks are respectively arranged on the pair of stirring circular bevel gears, the pair of stirring circular driving circular blocks are respectively meshed with the pair of stirring circular blocks, the pair of stirring circular driving circular blocks are respectively meshed with the plurality of stirring circular blocks, and the stirring circular blocks are respectively arranged on the stirring circular blocks; the gas-liquid raw materials generate high-speed rotating air flow in the mixing box through the pressurizing mixing structure, the phenomenon that liquid is directly atomized in the mixing box, extruded to generate gas-liquid mixing unevenly, water vapor is liquefied into small water drops when meeting cold and is attached to the inner side of the mixing box is avoided, the phenomenon that a gas turbine burns unevenly or fuel is insufficient is generated in the using process, meanwhile, air and fuel liquid need to be preheated firstly when being combusted, the phenomenon that liquefaction and combustion absorb excessive heat can be avoided, and heat in smoke after combustion is converted into a preheating heat source of the air and the fuel liquid.
All electric parts and the adaptive power supply are connected through wires by the person skilled in the art, and a proper controller is selected according to actual conditions so as to meet control requirements, specific connection and control sequence, and the electric connection is completed by referring to the following working principles in the working sequence among the electric parts, wherein the detailed connection means are known in the art, and the following main description of the working principles and processes is omitted.
Examples: the smoke in the gas turbine 2 is led to the exhaust pipe through the air exhaust valve, the smoke is led to the four pairs of exhaust shunt pipes through the air exhaust valve, the smoke is led to the plurality of radiating pipes through the four pairs of exhaust shunt pipes, the heat is respectively radiated to the inner sides of the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 through the radiating circular ring sheets on the plurality of radiating pipes, simultaneously, the transfer extrusion plates 28 on the pushing ends of the two pairs of extrusion hydraulic cylinders 27 are respectively driven through the expansion and contraction of the two pairs of extrusion hydraulic cylinders 27, the pair of liquid transfer boxes 22 and the lifting in the pair of air transfer boxes 23 are respectively arranged through the two pairs of transfer extrusion plates 28, the air and the liquid in the liquid feed boxes 3 are respectively pumped to the inner sides of the air transfer boxes 23 and the liquid transfer boxes 22, and then the air and the gas are extruded to the inner sides of the mixing boxes 1, simultaneously, the pressurizing driver 6 on the mixing box 1 is operated to drive the pressurizing driving bevel gear 8 on the driving end of the pressurizing driver 6 to rotate, the pressurizing driving bevel gear 7 meshed with the pressurizing driving bevel gear 8 is driven to rotate by the pressurizing driving bevel gear 8, the pressurizing threaded pipe 9 on the pressurizing driving bevel gear 7 is driven to rotate by the pressurizing driving bevel gear 7, the pressurizing threaded rod 10 in the pressurizing threaded pipe 9 is driven to rotate by the rotation of the pressurizing threaded pipe 9, the pressurizing threaded rod 10 is lifted along the inner side of the pressurizing threaded pipe 9, simultaneously, the pressurizing extrusion plate 11 on the pressurizing threaded rod 10 is driven by the pressurizing threaded rod 10, the liquid and the air in the air transfer box 23 and the liquid transfer box 22 are pumped to the inner side of the mixing box 1 by the lifting of the pressurizing extrusion plate 11, the stirring driving bevel gear 19 on the driving circular block 12 on the pressurizing extrusion plate 11 is driven to rotate by the stirring driving bevel gear 19 on the driving end of the stirring driving machine 18, the stirring driving helical gear 19 drives the stirring driving spiral gear 20 meshed with the stirring driving helical gear 19 to rotate, the stirring driving spiral gear 20 drives the upper driving spiral disk 14 to rotate, the driving spiral disk 14 drives the upper driving magnet blocks 16 to magnetically drive the lower driving magnet blocks 17 on the lower driving disk 15 to rotate, the lower driving magnet blocks 17 drive the upper driving disk 15 to rotate, the lower driving magnet blocks 15 drive the upper stirring plate 21, and the stirring plates 21 drive the upper stirring plate 21, so that mixed rotating air flow is generated in the pair of mixing boxes 1, gas-liquid and air are mixed to generate mixed air flow, the mixed air flow is extruded into the gas turbine through the lifting of the pressurizing extrusion plate 11, the mixed air flow generates centrifugal rotating air flow through the pressurizing mixing structure, the mixed air flow is prevented from directly transferring, the phenomenon of non-uniform rotation is avoided, and meanwhile, the heat on a plurality of cooling circular plates is absorbed by liquid and air, and the heat in the air is recovered when the required by the heat is recovered, and the required combustion temperature is avoided.
As a preferred scheme, still further, the transfer structure includes: a pair of liquid transfer boxes 22, a pair of air transfer boxes 23, a hydraulic box 24, a liquid pump 25, a hydraulic shunt pipe 26, two pairs of extrusion hydraulic cylinders 27, two pairs of transfer extrusion plates 28, two pairs of transfer valves 29 and a pair of feeding sealing valves 5;
the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 are mounted on the production support 4, the two pairs of transfer valves 29 are mounted on the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 respectively, the other ends of the two pairs of transfer valves 29 are connected to the pair of mixing boxes 1 respectively, the pair of feeding sealing valves 5 are mounted on the pair of mixing boxes 1 respectively, the pair of feeding sealing valves 5 are connected to the gas turbine 2 respectively, the two pairs of extrusion hydraulic cylinders 27 are mounted on the inner sides of the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 respectively, the two pairs of transfer extrusion plates 28 are mounted on the pushing ends of the two pairs of extrusion hydraulic cylinders 27 respectively, the hydraulic boxes 24 are mounted on the production support 4, the liquid pump 25 is mounted on the hydraulic boxes 24, the hydraulic shunt pipes 26 are mounted on the liquid pump 25 respectively, and the hydraulic shunt pipes 26 are connected to the pushing ends of the two pairs of extrusion hydraulic cylinders 27 respectively.
Preferably, the heat circulation structure further comprises: the heat dissipation device comprises an exhaust pipe, an air extracting pump, an exhaust valve, four pairs of exhaust shunt pipes, a plurality of heat dissipation pipes, two pairs of square limiting blocks and a plurality of heat dissipation circular ring sheets;
the exhaust pipe is installed on the gas turbine 2, the air pump is installed on the exhaust pipe, the exhaust valve is installed on the air pump, four pairs of exhaust shunt pipes are respectively inserted on two sides of a pair of liquid transfer boxes 22 and a pair of air transfer boxes 23, and four pairs of exhaust shunt pipes are respectively connected on the exhaust valve, a plurality of radiating pipes are respectively connected on four pairs of exhaust shunt pipes, a plurality of radiating circular ring sheets are respectively installed on a plurality of radiating pipes, and two pairs of return-shaped limiting blocks are respectively installed on a pair of liquid transfer boxes 22 and a pair of air transfer boxes 23.
Preferably, the inner sides of the pair of mixing tanks 1, the pair of liquid transfer tanks 22 and the pair of air transfer tanks 23 are respectively provided with pressure sensors.
Preferably, the outer sides of the exhaust pipe and the four pairs of exhaust shunt pipes are provided with heat insulation layers.
Preferably, a pair of coiled pipes are respectively arranged on the inner sides of the pair of mixing boxes 1, and the two pairs of coiled pipes are respectively connected to the two pairs of transit valves 29.
Preferably, a plastic layer is further disposed on the outer side of the concave transmission ring blocks 13.
As a preferred solution, the inner sides of the concave driving ring blocks 13 and the pair of concave driving ring blocks 12 are respectively provided with an auxiliary ball groove, the inner sides of the auxiliary ball grooves are respectively provided with a plastic ball groove pad, and the inner sides of the plastic ball groove pads are respectively provided with a plastic ball.
Preferably, the inner sides of the pair of mixing boxes 1, the pair of liquid transfer boxes 22 and the pair of air transfer boxes 23 are respectively provided with temperature sensors.
Preferably, a pair of liquid level meters are respectively arranged on the liquid transfer boxes 22.
The above technical solution only represents the preferred technical solution of the present invention, and some changes that may be made by those skilled in the art to some parts of the technical solution represent the principles of the present invention, and the technical solution falls within the scope of the present invention.
Claims (1)
1. A gas-liquid mixing and pressurizing device for a gas turbine comprises a pair of mixing boxes, a gas turbine, a liquid raw material box and a production bracket; the method is characterized in that: the pair of mixing boxes, the gas turbine and the liquid raw material box are arranged on the production support, a transfer structure is arranged on the production support and connected to the pair of mixing boxes and the gas turbine, a pressurizing mixing structure is arranged in the pair of mixing boxes, a heat circulation structure is arranged on the gas turbine, and the heat circulation structure is connected to the transfer structure;
the pressurized mixing structure comprises: the device comprises a pair of pressurizing driving machines, a pair of pressurizing transmission bevel gears, a pair of pressurizing driving bevel gears, a pair of pressurizing threaded pipes, a pair of pressurizing threaded rods, a pair of pressurizing extrusion plates, a pair of concave driving annular blocks, a plurality of concave transmission annular blocks, a pair of driving circular disks, a plurality of transmission circular disks, a plurality of driving magnet blocks, a pair of stirring driving machines, a pair of stirring driving bevel gears, a pair of stirring transmission circular bevel gears and a plurality of stirring sheets;
the pair of pressurizing driving machines are respectively arranged at the top ends of the pair of mixing boxes, the pair of pressurizing threaded pipes are respectively inserted into the pair of mixing boxes through bearings, the pair of pressurizing threaded rods are respectively movably inserted into the inner sides of the pair of pressurizing threaded pipes, the pair of pressurizing driving bevel gears are respectively arranged at the driving ends of the pair of pressurizing driving machines, the pair of pressurizing driving bevel gears are respectively meshed with the pair of pressurizing driving bevel gears, the pair of pressurizing extrusion plates are respectively arranged on the pair of pressurizing threaded rods, the pair of concave driving circular ring blocks are respectively arranged at the top ends of the pair of pressurizing extrusion plates, the pair of driving circular discs are respectively movably inserted into the inner sides of the pair of concave driving circular ring blocks, the plurality of concave transmission circular blocks are respectively circularly arranged on the pair of pressurizing extrusion plates, the plurality of transmission circular plates are respectively movably inserted on the inner sides of the plurality of concave transmission circular blocks, the pair of stirring transmission circular helical gears are respectively arranged on the pair of driving circular plates, the pair of stirring driving machines are respectively arranged on the pair of concave driving circular blocks, the pair of stirring driving helical gears are respectively arranged on the driving ends of the pair of stirring driving machines, the pair of stirring driving helical gears are respectively meshed with the pair of stirring transmission circular helical gears, the plurality of driving magnet blocks are respectively arranged on the pair of driving circular plates, the plurality of transmission magnet blocks are respectively arranged on the plurality of transmission circular plates, and the plurality of stirring sheets are respectively arranged on the plurality of transmission circular plates;
the transfer structure comprises: the device comprises a pair of liquid transfer boxes, a pair of air transfer boxes, a hydraulic box, a liquid pump, a hydraulic shunt pipe, two pairs of extrusion hydraulic cylinders, two pairs of centering extrusion plates, two pairs of transfer valves and a pair of feeding sealing valves;
the device comprises a production bracket, a pair of liquid transfer boxes, a pair of air transfer boxes, two pairs of transfer valves, a pair of liquid pump, a pair of liquid distributing pipes, a pair of feeding sealing valves, two pairs of extrusion hydraulic cylinders, two pairs of transfer pressing plates, two pairs of hydraulic distributing pipes and a hydraulic pump, wherein the pair of liquid transfer boxes and the pair of air transfer boxes are arranged on the production bracket, the two pairs of transfer valves are respectively arranged on the pair of liquid transfer boxes and the pair of air transfer boxes, the other ends of the two pairs of transfer valves are respectively connected to the pair of mixing boxes, the pair of feeding sealing valves are respectively arranged on the pair of mixing boxes, the pair of feeding sealing valves are respectively connected to the gas turbine, the two pairs of extrusion hydraulic cylinders are respectively arranged on the inner sides of the pair of liquid transfer boxes and the pair of air transfer boxes, the two pairs of transfer pressing plates are respectively arranged on the pushing ends of the two pairs of extrusion hydraulic cylinders, the hydraulic boxes are arranged on the production bracket, the hydraulic pump is arranged on the hydraulic box, the hydraulic distributing pipes are arranged on the hydraulic pump, and the hydraulic distributing pipes are respectively connected to the pushing ends of the two pairs of extrusion hydraulic cylinders;
the heat circulation structure comprises an exhaust pipe, an air pump, an exhaust valve, four pairs of exhaust shunt pipes, a plurality of radiating pipes, two pairs of square limiting blocks and a plurality of radiating circular ring sheets;
the exhaust pipe is arranged on the gas turbine, the air extracting pump is arranged on the exhaust pipe, the exhaust valve is arranged on the air extracting pump, four pairs of exhaust shunt pipes are respectively inserted on two sides of a pair of liquid transfer boxes and a pair of air transfer boxes, the four pairs of exhaust shunt pipes are respectively connected to the exhaust valve, a plurality of radiating pipes are respectively connected to the four pairs of exhaust shunt pipes, a plurality of radiating circular ring sheets are respectively arranged on the plurality of radiating pipes, and two pairs of return limiting blocks are respectively arranged on the pair of liquid transfer boxes and the pair of air transfer boxes;
the inner sides of the pair of mixing boxes, the pair of liquid transfer boxes and the pair of air transfer boxes are respectively provided with a pressure sensor;
the outer sides of the exhaust pipe and the four pairs of exhaust shunt pipes are provided with heat insulation layers;
a pair of coiled pipes are respectively arranged on the inner sides of the pair of mixing boxes, and the two pairs of coiled pipes are respectively connected to the two pairs of transfer valves;
the outer sides of the concave transmission circular blocks are provided with plastic layers;
auxiliary ball grooves are respectively formed in the inner sides of the concave transmission ring blocks and the pair of concave driving ring blocks, plastic ball groove pads are respectively arranged in the auxiliary ball grooves, and plastic balls are respectively arranged in the inner sides of the plastic ball groove pads;
the inner sides of the pair of mixing boxes, the pair of liquid transfer boxes and the pair of air transfer boxes are respectively provided with a temperature sensor;
and a pair of liquid level meters are respectively arranged on the liquid transfer boxes.
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CN115780010A (en) * | 2022-10-21 | 2023-03-14 | 烟台鑫龙建筑工程有限公司 | Novel high-efficiency energy-saving building cutting block and processing equipment |
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