CN118167575B

CN118167575B - High-efficiency energy-storage low-temperature refrigeration integrated machine for wind power

Info

Publication number: CN118167575B
Application number: CN202410592124.7A
Authority: CN
Inventors: 秦伯进; 卜慧; 印美娟; 齐杰
Original assignee: Jiangsu Josun Air Conditioner Co Ltd
Current assignee: Jiangsu Josun Air Conditioner Co Ltd
Priority date: 2024-05-14
Filing date: 2024-05-14
Publication date: 2024-10-01
Anticipated expiration: 2044-05-14
Also published as: CN118167575A

Abstract

The invention discloses a high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power, which relates to the technical field of low-temperature refrigeration of fans and comprises a cabin body, wherein an engine body is arranged at the top of the cabin body, an air supply engine body is arranged in the cabin body, absorption heat pumps are arranged at the side ends of the air supply engine body, four surface cooling pipes are communicated with the left side end and the right side end of each absorption heat pump, and exhaust and condensation fiber fabric air pipes are communicated with the side ends of the four surface cooling pipes.

Description

High-efficiency energy-storage low-temperature refrigeration integrated machine for wind power

Technical Field

The invention relates to the technical field of low-temperature refrigeration of fans, in particular to a high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power.

Background

The prior small and medium-sized wind driven generators mostly adopt a direct-drive structure, and are characterized in that a flange plate of a fan blade is directly connected with a shaft of an engine, the rotating speed of the fan blade is consistent with that of a motor, and the wind driven generator is generally composed of a wind wheel, a generator, a direction regulator, a tower, a speed limiting safety mechanism, an energy storage device and other components, so that the requirements on low-temperature environment are continuously increased, wherein a traditional refrigerating system mainly comprises a compressor, a condenser, a throttling device and an evaporator which are sequentially communicated and form a circulating pipeline, and the traditional refrigerating system is used for forming a low-temperature refrigerating integrated machine and performing operation.

However, in the prior art, in the use process of the wind driven generator, the wind driven generator continuously generates high-strength wind power, so that the generator and the energy storage device inside the tower are easy to overheat, the internal generator is overloaded, the service life of the internal generator cannot be guaranteed, and the low-temperature refrigeration effect is poor due to the fact that the contact area between a condensed water pipeline and hot and humid air is small in the wind driven generator, so that the condensation efficiency is low, and therefore the high-efficiency energy storage low-temperature refrigeration integrated machine for wind power needs to be provided.

Disclosure of Invention

The invention aims to provide a high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power, which aims to solve the problems that in the use process of a wind power generator, the continuous high-strength wind power generation of the wind power generator is easy to overheat a generator and an energy storage device in a tower, and the low-temperature refrigeration effect is poor and the condensation efficiency is low because of small contact area between a condensed water pipeline and hot and humid air in the wind power generator.

In order to achieve the above purpose, the present invention provides the following technical solutions: the high-efficiency energy storage low-temperature refrigeration all-in-one machine for wind power comprises a cabin body, wherein an engine body is arranged at the top of the cabin body, an air supply engine body is arranged in the cabin body, an absorption heat pump is arranged at the side end of the air supply engine body, four surface cooling pipes are respectively communicated with the left side end and the right side end of the absorption heat pump, a plurality of groups of hall sensors are arranged on the surface of the bottom wall of the absorption heat pump in a communicating manner, a light transmission pipeline is arranged at the top end of the air exhaust condensation fiber fabric air pipe in a butt joint manner, a pipeline connecting assembly is hermetically connected to the top of the light transmission pipeline, an air inlet low-temperature assembly is arranged at the top of the pipeline connecting assembly in a communicating manner, the air exhaust condensation fiber fabric air pipe is arranged to be connected with a plurality of groups of split type, the installation height of the air exhaust condensation fiber fabric air pipe is attached to the tower, a DAC device is arranged in the air exhaust condensation fiber fabric air pipe, a fixed angle iron installation frame is fixedly sleeved outside the air exhaust condensation fiber fabric air pipe in an equal division manner, a plurality of groups of hall sensors are arranged on the bottom wall surface of the absorption heat pump, the absorption heat pump is connected with a frequency converter through a circuit, the frequency converter is connected to the bottom of the absorption heat pump, and the frequency converter is connected to the energy converter through the circuit converter, and the energy converter is connected to the bottom of the energy converter through the frequency converter;

The air inlet low temperature assembly comprises an air inlet low pressure pipe, a low pressure air inlet end is formed by intersecting two wall surfaces at the top end of the air inlet low pressure pipe, vortex generators are arranged in the low pressure air inlet end, an installation fixing angle frame is fixedly arranged outside the low pressure air inlet end, an air compressor is fixedly arranged at the side end of the installation fixing angle frame, a condenser is communicated with the bottom of the air compressor, an evaporator is communicated with the side end of the condenser, a condensing air pipe is communicated with the bottom of the evaporator, a gas liquefier is communicated with the bottom of the condensing air pipe, and a gas transmission circulating pipe is communicated with the bottom of the condenser.

Preferably, the bottom intercommunication of gas-transmission circulating pipe has oxygen condensation pipeline, the bottom intercommunication of oxygen condensation pipeline has the air pump, the left and right sides end intercommunication of air pump has the gas collecting tube, the bottom intercommunication of gas collecting tube has the gas receiver, the side intercommunication of gas receiver has two sets of trachea, two sets of the side intercommunication of trachea has the hydrogen delivery end.

Preferably, the side end of the hydrogen conveying end is communicated with a booster pump, the bottom of the booster pump is communicated with a gas refrigerant conveying pipeline, a gas-liquid separator is arranged at the bottom end of the gas refrigerant conveying pipeline, the bottom ends of the gas-liquid separator are communicated with a plurality of groups of liquid refrigerant conveying pipelines, and the side ends of the liquid refrigerant conveying pipelines are connected with condensing fin heat exchange structures.

Preferably, the side end of the condensing fin heat exchange structure is communicated with a hydrogen storage tank, the bottom end of the hydrogen storage tank is communicated with a plurality of groups of hydrogen energy conveying pipelines, a plurality of groups of hydrogen energy conveying pipelines are connected with a proton exchange fuel cell, an energy storage connector is arranged at the side end of the proton exchange fuel cell, an energy storage group is connected with the side end of the energy storage connector, and an energy exchange pipe is connected to the top of the energy storage group.

Preferably, the side end of the hydrogen conveying end is connected with an oxyhydrogen separator, the side end of the oxyhydrogen separator is communicated with a gas distribution and delivery pipe, the bottom end of the gas distribution and delivery pipe is communicated with a gas collection chamber, the side edge of the gas collection chamber is provided with a high-efficiency storage battery, the side end of the high-efficiency storage battery is electrically connected with an electrolysis chamber, and the two ends of the electrolysis chamber are communicated with the gas pipe and the gas collection chamber with the height difference.

Preferably, an axle vane group is arranged in the air supply machine body, and the side end of the axle vane group is connected with a power supply structure.

Preferably, a static pressure end is arranged at the side end of the air supply machine body, a low-temperature static pressure air outlet end is connected with the side end of the static pressure end, and an air outlet is communicated with the side end of the low-temperature static pressure air outlet end.

Preferably, the top of the cabin body is provided with a circulating air pump, the side ends of the circulating air pump are respectively communicated with a first air pipe and a second air pipe, and the side ends of the second air pipe and the first air pipe are communicated with a condensing fin heat exchange structure.

Preferably, the axial flow heat dissipation fans are symmetrically arranged on the surface of the back side of the cabin body, and the surface of the machine body is provided with the PLC.

Preferably, the pipeline connecting assembly comprises a flange part, the bottom end of the flange part is connected with a sealing disc through bolt fastening, the side end of the sealing disc is fixedly connected with a fixing seat, and the fixing seat is fixedly installed by forming an equal number of groups of sleeves outside the exhaust condensing fiber fabric air pipe.

Compared with the prior art, the invention has the beneficial effects that:

1. In the invention, the air inlet low-temperature component, the absorption heat pump and the Hall sensor are matched, so that the air inlet low-pressure pipe and the low-pressure air inlet end are conveniently utilized to conduct guiding and conveying operation on high low-pressure air flow, and the vortex generator is matched to ensure the strength of the guided and conveyed air flow, so that the high air flow is converted into liquid under the matching of the air compressor, the condenser, the evaporator, the condensation air pipe and the gas liquefier, the generated liquid is dropped into the DAC device in the air exhaust condensation fiber fabric air pipe, the collected and recovered carbon dioxide is conveyed into the air compressor through the air exhaust condensation fiber fabric air pipe by the DAC device to conduct compressing operation, thereby forming solid dry ice particles, and the condensed water are gathered and dropped along the air exhaust condensation fiber fabric air pipe under the matching of the absorption heat pump, the kinetic potential energy generated when falling is matched with a plurality of groups of Hall sensors, the kinetic potential energy is converted into electric energy by utilizing a frequency converter, an exchanger and an energy storage converter, so that the electric energy is conveyed to an energy storage pump, then the heat can be conveniently conveyed from a low-temperature heat source to a high-temperature heat source pump by utilizing an absorption heat pump, the gas evaporated by falling water and dry ice particles is conveyed to the inside of an air compressor again along an air exhaust condensation fiber fabric air pipe, the evaporated gas is conveyed in a compression mode by utilizing the air compressor again, then the mixture is evaporated and the heat in the flowing gas is absorbed by utilizing a condenser and a gas transmission circulating pipe under the matching of the air compressor, an expansion valve and the evaporator, the gas flowing through the evaporator is condensed and cooled, and the condensed gas is conveyed to the inside of an air supply machine body through the air exhaust condensation fiber fabric air pipe, under the cooperation of the low-temperature static air outlet end and the air outlet, the low-temperature condensing gas conveying operation is convenient, and the whole device is efficient and energy-saving in use.

2. According to the invention, through the cooperation of the gas distribution pipe, the gas storage chamber, the gas collection pipe, the gas pump, the electrolysis chamber, the gas collection chamber and the gas distribution pipe, the electrolysis chamber can be subjected to electrolytic reaction operation through the high-efficiency storage battery, then the hydrogen and the oxygen can be conveniently separated and collected under the cooperation of the hydrogen-oxygen separator, the gas collection pipes with the height difference at the two ends of the electrolysis chamber are communicated, the gas distribution pipe is used for carrying out separation and transportation operation on the generated hydrogen and the oxygen, then when the electrolysis chamber is used for carrying out electrolysis to generate oxygen, the oxygen is enabled to be upwards transported into the gas storage chamber, then the gas pump, the gas storage chamber, the oxygen condensation pipeline and the gas transmission circulation pipe are matched, the subsequent low-temperature condensation operation is facilitated, then the descending collected hydrogen is transported through the gas refrigerant transportation pipeline under the action of the pump, then the gas-liquid separator is matched, the generated redundant refrigerant liquid is stored and utilized, the generated hydrogen liquid is transported into the condensation fin heat exchange structure by the utilization pipelines, the generated hydrogen energy utilization efficiency is ensured, and then the generated hydrogen energy is converted into the energy storage tank and the energy storage tank with the high-efficient energy storage device, and the energy storage device is conveniently exchanged under the cooperation of the high-efficient energy storage device.

3. According to the invention, the axial flow heat radiation fan, the circulating air pump, the first air pipe and the second air pipe are matched, so that the axial flow heat radiation fan conducts air drainage on the condensed gas in the second air pipe in the whole device, the condensed gas in the second air pipe is convenient to cool the inside of the whole device, and the service life of the whole device is ensured.

Drawings

FIG. 1 is a schematic diagram of a structure of a front view of a high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power;

FIG. 2 is a schematic diagram of a side view structure of the wind power high-efficiency energy storage low-temperature refrigeration integrated machine;

FIG. 3 is a schematic diagram of a separation structure of a main body in the high-efficiency energy storage low-temperature refrigeration integrated machine for wind power;

FIG. 4 is a schematic diagram of the internal cross-sectional structure of a main body in the wind power high-efficiency energy storage low-temperature refrigeration integrated machine;

FIG. 5 is a schematic structural diagram of an air intake low-temperature component in the wind power high-efficiency energy storage low-temperature refrigeration integrated machine;

FIG. 6 is a schematic diagram of the internal structure of a cabin and a body in the high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power;

FIG. 7 is a schematic diagram of the installation position structure of a Hall sensor in the high-efficiency energy storage low-temperature refrigeration integrated machine for wind power;

FIG. 8 is a schematic diagram of the installation structure of a proton exchange fuel cell and an energy storage connector in the high-efficiency energy storage low-temperature refrigeration integrated machine for wind power;

FIG. 9 is a schematic diagram of the installation structure of a gas-liquid separator in the wind power high-efficiency energy storage low-temperature refrigeration integrated machine.

In the figure: 1. a cabin body; 2. an air outlet; 3. a body; 4. a first air tube; 5. a circulation air pump; 6. a PLC controller; 7. an energy storage tube; 8. an energy storage converter; 9. an energy storage pump; 10. a gas distribution pipe; 11. an air storage chamber; 12. a gas collecting tube; 13. an air pump; 14. an oxygen condensing pipeline; 15. a pipeline connecting assembly; 151. a flange member; 152. a fixing seat; 153. a sealing plate; 16. a light transmission pipeline; 17. air exhausting and condensing fiber fabric air pipes; 18. an air inlet low-temperature assembly; 181. an air inlet low-pressure pipe; 182. a low pressure air inlet end; 183. a vortex generator; 184. installing and fixing the corner frame; 185. an air compressor; 186. a condenser; 187. an evaporator; 188. a condensing gas pipe; 189. a gas liquefier; 1890. a gas circulation pipe; 19. a second air pipe; 20. fixing an angle iron mounting frame; 21. a surface cooling tube; 22. an absorption heat pump; 23. an air supply body; 24. an axial flow heat radiation fan; 25. a hall sensor; 26. a frequency converter; 28. an oxyhydrogen separator; 29. a hydrogen delivery end; 30. a pressurizing pump; 31. a gaseous refrigerant delivery conduit; 32. a gas-liquid separator; 33. a liquid refrigerant delivery conduit; 34. an efficient storage battery; 35. an electrolysis chamber; 36. a plenum chamber; 37. a gas distribution pipe; 38. a power supply structure; 39. a set of shaft vanes; 40. an energy exchange tube; 41. an energy storage group; 42. a static pressure end; 43. a low-temperature static air outlet end; 44. a DAC device; 45. a condensing fin heat exchange structure; 46. a hydrogen energy delivery line; 47. proton exchange fuel cells; 48. an energy storage connector; 49. an exchanger.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and fully with reference to the accompanying drawings, in which it is evident that the embodiments described are only some, but not all embodiments of the invention. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-9: the wind power high-efficiency energy storage low-temperature refrigeration all-in-one machine comprises a cabin body 1, wherein an engine body 3 is arranged at the top of the cabin body 1, an air supply engine body 23 is arranged in the cabin body 1, an absorption heat pump 22 is arranged at the side end of the air supply engine body 23, four surface cooling pipes 21 are respectively communicated with the left side end and the right side end of the absorption heat pump 22, an exhaust condensation fiber fabric air pipe 17 is communicated with the side ends of the four surface cooling pipes 21, a light transmission pipeline 16 is arranged at the top end of the exhaust condensation fiber fabric air pipe 17 in a butt joint mode, a pipeline connecting assembly 15 is connected with the top of the light transmission pipeline 16 in a sealing mode, an air inlet low-temperature assembly 18 is communicated with the top of the pipeline connecting assembly 15, the exhaust condensation fiber fabric air pipe 17 is connected with a plurality of groups of split type, the installation height of the exhaust condensation fiber fabric air pipe 17 is attached to the tower height, a DAC device 44 is arranged in the exhaust condensation fiber fabric air pipe 17, a fixed angle iron installation frame 20 is sleeved and fastened at the outer part of the exhaust condensation fiber fabric air pipe 17 in an equal part, a plurality of groups of Hall sensors 25 are arranged on the surface of the bottom wall of the absorption heat pump 22, the bottom of the absorption heat pump 22 is connected with a frequency converter 26 through a pipeline, the frequency converter 26 is connected with the bottom of the frequency converter 49, the frequency converter 26 is connected with the energy storage 8 through the side of the frequency converter 49, and the energy converter 8 is connected with the bottom of the energy storage 8 through the energy storage 8, and the energy storage 8 is connected with the energy storage 8; the air inlet low temperature assembly 18 comprises an air inlet low pressure pipe 181, a low pressure air inlet end 182 is arranged on the surface of two walls of the top end of the air inlet low pressure pipe 181 in a crossing mode, vortex generators 183 are arranged in the low pressure air inlet end 182, an installation fixing angle frame 184 is fixedly arranged on the outer portion of the low pressure air inlet end 182, an air compressor 185 is fixedly arranged on the side end of the installation fixing angle frame 184, a condenser 186 is communicated with the bottom of the air compressor 185, an evaporator 187 is communicated with the side end of the condenser 186, a condensation air pipe 188 is communicated with the bottom of the evaporator 187, a gas liquefier 189 is communicated with the bottom of the condensation air pipe 188, and a gas transmission circulating pipe 1890 is communicated with the bottom of the condenser 186.

According to the embodiments shown in fig. 1,2 and 4, the bottom end of the gas transmission circulation pipe 1890 is connected with the oxygen condensation pipe 14, the bottom end of the oxygen condensation pipe 14 is connected with the air pump 13, the left and right side ends of the air pump 13 are connected with the gas collecting pipe 12, the bottom end of the gas collecting pipe 12 is connected with the gas storage chamber 11, the side ends of the gas storage chamber 11 are connected with the two component gas pipes 10, the side ends of the two component gas pipes 10 are connected with the hydrogen delivery end 29, under the cooperation of the two component gas pipes 10, when the electrolysis chamber 35 is used for generating oxygen through electrolysis, the oxygen is conveniently lifted and delivered into the gas storage chamber 11, then under the action of the air pump 13, the oxygen inside the gas storage chamber 11 is extracted by the gas collecting pipe 12, and then delivered into the gas transmission circulation pipe 1890 through the oxygen condensation pipe 14, so that the subsequent low-temperature condensation operation is convenient.

According to the embodiments shown in fig. 3, fig. 4, fig. 6, fig. 8 and fig. 9, the side end of the hydrogen delivery end 29 is provided with a pressurizing pump 30 in a communicating manner, the bottom of the pressurizing pump 30 is provided with a gas refrigerant delivery pipe 31 in a communicating manner, the bottom end of the gas refrigerant delivery pipe 31 is provided with a gas-liquid separator 32 in a mounting manner, the bottom end of the gas-liquid separator 32 is provided with a plurality of groups of liquid refrigerant delivery pipes 33 in a communicating manner, the side ends of the plurality of groups of liquid refrigerant delivery pipes 33 are connected with a condensing fin heat exchange structure 45, the descending and collecting hydrogen is delivered through the gas refrigerant delivery pipe 31 under the action of the pressurizing pump 30, then the generated redundant refrigerant liquid is stored and utilized under the cooperation of the gas-liquid separator 32, and then the generated hydrogen liquid is delivered into the condensing fin heat exchange structure 45 by the plurality of groups of liquid refrigerant delivery pipes 33 for heat exchange operation, so that the hydrogen energy utilization efficiency generated by electrolysis is ensured.

According to the embodiments shown in fig. 3, 6 and 8, the side end of the condensation fin heat exchange structure 45 is connected with a hydrogen storage tank, the bottom end of the hydrogen storage tank is connected with a plurality of groups of hydrogen energy transmission pipelines 46, the side end of the plurality of groups of hydrogen energy transmission pipelines 46 is connected with a proton exchange fuel cell 47, the side end of the proton exchange fuel cell 47 is provided with an energy storage connector 48, the side end of the energy storage connector 48 is connected with an energy storage group 41, the top of the energy storage group 41 is connected with an energy exchange tube 40, after the generated hydrogen energy heat exchange operation, the hydrogen energy can be transmitted to the hydrogen storage tank for hydrogen energy storage, then the stored hydrogen energy can be transmitted and utilized under the action of the plurality of groups of hydrogen energy transmission pipelines 46, the hydrogen energy is utilized as fuel under the action of the proton exchange fuel cell 47, and then the energy is converted into the required electric energy, and under the cooperation of the energy storage connector 48 and the energy exchange tube 40, the surplus load electric energy can be converted into the hydrogen energy for storage in the energy storage group 41, and the subsequent utilization is convenient.

According to the embodiments shown in fig. 4, 6 and 9, the side end of the hydrogen gas delivering end 29 is connected with the oxyhydrogen separator 28, the side end of the oxyhydrogen separator 28 is connected with the gas delivering tube 37, the bottom end of the gas delivering tube 37 is connected with the gas collecting chamber 36, the side edge of the gas collecting chamber 36 is provided with the high-efficiency storage battery 34, the side end of the high-efficiency storage battery 34 is electrically connected with the electrolysis chamber 35, and the gas collecting chamber 36 with the two ends of the electrolysis chamber 35 being in the height difference is connected, under the cooperation of the high-efficiency storage battery 34, the electrolysis reaction of the anode and the cathode in the electrolysis chamber 35 is facilitated, the generated oxygen is adsorbed on the anode surface, the hydrogen is attached to the cathode surface, then under the cooperation of the oxyhydrogen separator 28, the characteristics of oxygen rising and hydrogen falling are utilized in the electrolysis reaction process, the hydrogen and the oxygen are separated and collected, and the gas collecting chamber 36 with the two ends of the electrolysis chamber 35 being in the height difference is connected, so that the gas delivering tube 37 separates and delivers the generated hydrogen and the oxygen.

According to the illustration in fig. 6, the air supply body 23 is internally provided with the shaft vane group 39, the side end of the shaft vane group 39 is connected with the power supply structure 38, the power supply structure 38 operates by utilizing the kinetic potential energy generated by the condensation and accumulation liquid falling from the high place by exhausting the air and condensation fiber fabric air pipe 17 attached to the tower height, and the shaft vane group 39 drives the power supply structure 38 to operate by utilizing the generated high-efficiency exhaust, so that the whole device has high energy supply efficiency, reduces energy consumption and is convenient for high-efficiency energy storage operation.

As shown in fig. 1,3, 4, 6 and 8, a static pressure end 42 is mounted at a side end of the air blower body 23, a low-temperature static air outlet end 43 is connected to a side end of the static pressure end 42, an air outlet 2 is connected to a side end of the low-temperature static air outlet end 43, and the air blower body 23, the low-temperature static air outlet end 43 and the air outlet 2 cooperate to facilitate low-temperature condensation operation.

According to the arrangement of fig. 1, fig. 2, fig. 6, fig. 7 and fig. 8, the top of the cabin body 1 is provided with a circulating air pump 5, the side ends of the circulating air pump 5 are respectively communicated with a first air pipe 4 and a second air pipe 19, the side ends of the second air pipe 19 and the first air pipe 4 are communicated with a condensing fin heat exchange structure 45, under the cooperation of the circulating air pump 5, the gas generated by the heat exchange of the condensing fin heat exchange structure 45 is conveniently converted into condensed gas under the action of the first air pipe 4 and then is conveyed into the second air pipe 19, and the condensed gas in the second air pipe 19 is convenient for cooling the whole device, so that the service life of the whole device operation is ensured.

According to the embodiments shown in fig. 1,2 and 7, the axial-flow heat dissipation fans 24 are symmetrically installed on the back side surface of the cabin body 1, and the PLC controller 6 is arranged on the surface of the machine body 3, and the axial-flow heat dissipation fans 24 are matched with the second air pipe 19, so that the condensed gas conveyed by the interior of the second air pipe 19 is subjected to gas drainage in the whole device by the axial-flow heat dissipation fans 24, and the condensed gas in the interior of the second air pipe 19 is convenient to cool the interior of the whole device.

According to fig. 1 and 4, the pipe connection assembly 15 includes a flange member 151, the bottom end of the flange member 151 is connected with a sealing disc 153 through bolt fastening, the side end of the sealing disc 153 is connected with a fixing seat 152 in a fastening manner, wherein the fixing seat 152 forms an equally-divided plurality of groups of sleeved fastening installation outside the exhaust condensing fiber fabric air pipes 17, under the cooperation of the sealing disc 153 and the flange member 151, the air inlet low-pressure pipe 181, the exhaust condensing fiber fabric air pipes 17 and the light-transmitting pipe 16 are conveniently and sealingly installed and connected, and the air transmission circulating pipe 1890 is conveniently and fixedly installed outside the exhaust condensing fiber fabric air pipes 17 by utilizing the fixing seat 152.

The wiring diagrams of the gas liquefier 189, the absorption heat pump 22, the hall sensor 25, the frequency converter 26, the oxyhydrogen separator 28, the gas-liquid separator 32, the energy exchange tube 40, the DAC device 44, the proton exchange fuel cell 47, the energy storage connector 48 and the exchanger 49 in the present invention are well known in the art, and the working principle thereof is a well known technology, and the model thereof is selected to be suitable according to actual use, so that the control mode and the wiring arrangement will not be explained in detail for the gas liquefier 189, the absorption heat pump 22, the hall sensor 25, the frequency converter 26, the oxyhydrogen separator 28, the gas-liquid separator 32, the energy exchange tube 40, the DAC device 44, the proton exchange fuel cell 47, the energy storage connector 48 and the exchanger 49.

The application method and the working principle of the device are as follows: firstly, under the cooperation of the sealing disc 153 and the flange 151, the air inlet low-pressure pipe 181, the air exhaust condensing fiber fabric air pipe 17 and the light transmission pipeline 16 are conveniently and fixedly installed outside the air exhaust condensing fiber fabric air pipe 17 by utilizing the fixing seat 152, the integral air exhaust condensing fiber fabric air pipe 17 is installed in a multi-section mode outside the tower body, the light transmission pipeline 16 is installed at the middle ends of the two groups of air exhaust condensing fiber fabric air pipes 17, the air inlet low-pressure pipe 181 is installed at the top end of the air exhaust condensing fiber fabric air pipe 17, Thereby forming high pipeline operation, being matched with the fixed angle iron mounting frame 20, being convenient for installing and stabilizing the bottom end of the air-exhausting and condensing fiber fabric air pipe 17 and the side walls of the cabin body 1 and the machine body 3, then under the matching of the air inlet low-pressure pipe 181, guiding and conveying the high low-pressure air flow through the low-pressure air inlet end 182 which is arranged on the surface of the two walls in a crossing way, under the matching of the vortex generator 183, guaranteeing the strength of the guided and conveyed air flow, when the high-pressure air flow is compressed and conveyed under the action of the air compressor 185, utilizing the condenser 186, being convenient for discharging the air conveyed by the air compressor 185 into the condenser 186 and the evaporator 187, The condensation evaporation operation is performed so that the gas is converted into liquid by the cooperation of the condensation air pipe 188 and the gas liquefier 189, the generated liquid is dropped into the DAC device 44 in the air-exhausting condensation fiber fabric air pipe 17, the DAC system in the DAC device 44 captures carbon dioxide by using the surface of the filter covered with the special chemical agent, and then a compound is formed therein, when the new compound is heated, the captured carbon dioxide is released and separated from the chemical agent, and then can be recycled, thereby the DAC device 44 can more efficiently recycle the carbon dioxide, and then the collected and recycled carbon dioxide, The air compressor 185 is conveyed by the air exhaust condensing fiber fabric air pipe 17 to perform compression operation, thereby forming solid dry ice particles, the solid dry ice particles and condensed water are gathered and fall along the air exhaust condensing fiber fabric air pipe 17 under the cooperation of the absorption heat pump 22, the kinetic potential energy generated when falling is converted into electric energy by the frequency converter 26, the exchanger 49 and the energy storage converter 8 under the cooperation of the plurality of groups of Hall sensors 25, so as to be conveyed into the energy storage pump 9, and then the absorption heat pump 22 can be utilized to facilitate the conveying of heat from a low-temperature heat source to a high-temperature heat source pump, so that the falling water and the gas evaporated by the dry ice particles, The air is conveyed to the inside of the air compressor 185 along the air exhaust condensing fiber fabric air pipe 17 again, the evaporated gas is compressed and conveyed again by the air compressor 185, then the high-temperature and high-pressure gas compressed by the air compressor 185 is condensed by the condenser 186 and the gas conveying circulating pipe 1890, so that the high-temperature and high-pressure gas is converted into liquid, and then is regulated by the expansion valve, so that a low-temperature and low-pressure gas-liquid mixture is changed into the evaporator 187, the mixture is evaporated and absorbs heat in the flowing gas under the cooperation of the evaporator 187, the gas flowing through the evaporator 187 is condensed and cooled, the condensed gas is discharged to the air supply body 23 by the exhaust air condensing fiber fabric air pipe 17, so that the operation of low-temperature condensing and gas conveying is facilitated under the cooperation of the low-temperature static air outlet end 43 and the air outlet 2, and the energy converted in the energy storage pump 9 is conveyed to the high-efficiency storage battery 34 under the cooperation of the energy storage pipe 7, so that the electrolysis reaction of the anode and the cathode existing in the electrolysis chamber 35 is facilitated under the cooperation of the high-efficiency storage battery 34, the generated oxygen is adsorbed on the surface of the anode, the hydrogen is attached to the surface of the cathode, and then under the cooperation of the oxyhydrogen separator 28, the oxygen rises during the electrolysis reaction, The characteristic of hydrogen descending, separating and collecting the hydrogen and the oxygen, communicating the air pipe and the air collecting chamber 36 with the two ends of the electrolysis chamber 35 having the height difference, facilitating the separation and conveying operation of the generated hydrogen and the oxygen by utilizing the gas separating and conveying pipe 37, so that when the electrolysis chamber 35 is electrolyzed to generate the oxygen, the oxygen is ascended and conveyed into the air storage chamber 11, then under the action of the air pump 13, the oxygen in the air storage chamber 11 is extracted by utilizing the air collecting pipe 12 and conveyed into the air conveying circulating pipe 1890 through the oxygen condensing pipeline 14, facilitating the subsequent low-temperature condensing operation, and facilitating the conveying of the descending and collected hydrogen through the gas refrigerant conveying pipe 31 under the action of the pressurizing pump 30, The generated redundant refrigerant liquid is stored and utilized under the cooperation of the gas-liquid separator 32, then the generated hydrogen liquid is conveyed into the condensation fin heat exchange structure 45 by utilizing the plurality of groups of liquid refrigerant conveying pipelines 33 to perform heat exchange operation, the utilization efficiency of hydrogen energy generated by electrolysis is ensured, then the generated hydrogen energy can be conveyed into a hydrogen storage tank to store hydrogen energy after the heat exchange operation, then the stored hydrogen energy can be conveyed and utilized under the action of the plurality of groups of hydrogen energy conveying pipelines 46, when the proton exchange fuel cell 47 is used, the hydrogen energy is used as fuel to be converted into required electric energy, and under the cooperation of the energy storage connector 48 and the energy exchange tube 40, the redundant load electric energy can be converted into hydrogen energy and is conveyed to the energy storage group 41 for storage, subsequent utilization is facilitated, meanwhile, after that, the gas generated by heat exchange of the condensation fin heat exchange structure 45 can be conveniently conveyed to the first gas pipe 4 under the action of the circulating gas pump 5 under the cooperation of the axial flow heat dissipation fan 24, the gas is converted into condensed gas and then conveyed to the second gas pipe 19, and then the axial flow heat dissipation fan 24 is conveniently used for conducting gas drainage on the condensed gas in the second gas pipe 19 in the whole device, so that the condensed gas in the second gas pipe 19 is conveniently cooled in the whole device, and the service life of the whole device is guaranteed.

Although the present invention has been described with reference to the foregoing embodiments, it will be apparent to those skilled in the art that modifications may be made to the embodiments described, or equivalents may be substituted for elements thereof, and any modifications, equivalents, improvements and changes may be made without departing from the spirit and principles of the present invention.

Claims

1. Wind-powered electricity generation is with high-efficient energy storage low temperature refrigeration all-in-one, its characterized in that: including cabin body (1), the top of cabin body (1) is provided with organism (3), the internally mounted of cabin body (1) has air supply organism (23), the side-mounting of air supply organism (23) is provided with absorption heat pump (22), the side-mounting of absorption heat pump (22) all communicates with four surface cooling tubes (21), four the side-mounting of surface cooling tubes (21) communicates there is condensation fiber fabric tuber pipe (17) of airing exhaust, the top butt joint of condensation fiber fabric tuber pipe (17) of airing exhaust is installed light-transmitting pipeline (16), the top sealing connection of light-transmitting pipeline (16) has pipeline coupling assembling (15), the top intercommunication of pipeline coupling assembling (15) has air inlet low temperature component (18), condensation fiber fabric tuber pipe (17) of airing exhaust sets up to multiunit amalgamation and connects, just condensation fiber fabric tuber pipe (17)'s installation height adheres to the pylon height, condensation fiber fabric tuber pipe (17)'s inside is provided with DAC device (44), condensation fiber fabric tuber pipe (17) of airing exhaust's outside fastening cover has heat pump (22) bottom wall (25) fixed by way of hall formula heat pump (22) bottom wall (25), the side end of the frequency converter (26) is connected with an exchanger (49) through a circuit, the side end of the exchanger (49) is connected with an energy storage converter (8), the bottom of the energy storage converter (8) is connected with an energy storage pump (9), and the top of the energy storage converter (8) is communicated with an energy storage pipe (7);

The utility model provides an air inlet low temperature subassembly (18) is including air inlet low pressure pipe (181), low pressure inlet end (182) have been seted up on the top both walls surface cross of air inlet low pressure pipe (181), vortex generator (183) are all installed to the inside of low pressure inlet end (182), install fixed angle frame (184) are installed to the outside fastening of low pressure inlet end (182), air compressor (185) are installed in the side fastening of installation fixed angle frame (184), the bottom intercommunication of air compressor (185) has condenser (186), the side intercommunication of condenser (186) has evaporimeter (187), the bottom intercommunication of evaporimeter (187) has condenser trachea (188), the bottom intercommunication of condenser trachea (188) has gas liquefier (189), just the bottom intercommunication of condenser (186) has gas transmission circulating pipe (1890).

2. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the bottom intercommunication of gas-supply circulation pipe (1890) has oxygen condensation pipeline (14), the bottom intercommunication of oxygen condensation pipeline (14) has air pump (13), the left and right sides end intercommunication of air pump (13) has gas-collecting tube (12), the bottom intercommunication of gas-collecting tube (12) has gas receiver (11), the side intercommunication of gas receiver (11) has two component air pipes (10), two sets of the side intercommunication of gas-separating pipe (10) has hydrogen delivery end (29).

3. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 2, wherein: the hydrogen gas conveying device is characterized in that a pressurizing pump (30) is arranged at the side end of the hydrogen gas conveying end (29) in a communicating mode, a gas refrigerant conveying pipeline (31) is arranged at the bottom of the pressurizing pump (30) in a communicating mode, a gas-liquid separator (32) is arranged at the bottom end of the gas refrigerant conveying pipeline (31), a plurality of groups of liquid refrigerant conveying pipelines (33) are arranged at the bottom end of the gas-liquid separator (32) in a communicating mode, and condensing fin heat exchange structures (45) are connected at the side ends of the liquid refrigerant conveying pipelines (33).

4. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 3, wherein: the side end of condensing fin heat transfer structure (45) is linked together and is had the hydrogen storage jar, the bottom intercommunication of hydrogen storage jar has multiunit hydrogen energy transfer line (46), multiunit the side end of hydrogen energy transfer line (46) is connected with proton exchange fuel cell (47), the side of proton exchange fuel cell (47) is provided with energy storage connector (48), the side of energy storage connector (48) is connected with energy storage group (41), the top of energy storage group (41) is connected with energy exchange tube (40).

5. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 2, wherein: the hydrogen gas separation device is characterized in that an oxyhydrogen separator (28) is connected to the side end of the hydrogen gas conveying end (29), a gas separation conveying pipe (37) is communicated to the side end of the oxyhydrogen separator (28), a gas collection chamber (36) is communicated to the bottom end of the gas separation conveying pipe (37), a high-efficiency storage battery (34) is arranged on the side edge of the gas collection chamber (36), an electrolysis chamber (35) is electrically connected to the side end of the high-efficiency storage battery (34), and gas pipes and gas collection chambers (36) with the two ends of the electrolysis chamber (35) being in vertical height difference are communicated.

6. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the inside of the air supply machine body (23) is provided with a shaft vane group (39), and the side end of the shaft vane group (39) is connected with a power supply structure (38).

7. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the side end of the air supply machine body (23) is provided with a static pressure end (42), the side end of the static pressure end (42) is connected with a low-temperature static air outlet end (43), and the side end of the low-temperature static air outlet end (43) is communicated with an air outlet (2).

8. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the top of the cabin body (1) is provided with a circulating air pump (5), the side ends of the circulating air pump (5) are respectively communicated with a first air pipe (4) and a second air pipe (19), and the side ends of the second air pipe (19) and the first air pipe (4) are communicated with a condensing fin heat exchange structure (45).

9. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the axial-flow heat dissipation fans (24) are symmetrically arranged on the back side surface of the cabin body (1), and the PLC (programmable logic controller) 6 is arranged on the surface of the machine body (3).

10. The high-efficiency energy-storage low-temperature refrigeration integrated machine for wind power according to claim 1, wherein: the pipeline connecting assembly (15) comprises a flange piece (151), a sealing disc (153) is connected to the bottom end of the flange piece (151) through bolt fastening, a fixing seat (152) is connected to the side end of the sealing disc (153) in a fastening mode, and the fixing seat (152) is fixedly installed in a mode of forming equal division multiple sets of overlapping outside the exhaust condensing fiber fabric air pipe (17).