CN113669309B

CN113669309B - Condensation separation type air wave supercharging device and method

Info

Publication number: CN113669309B
Application number: CN202110918261.1A
Authority: CN
Inventors: 胡大鹏; 赵一鸣; 刘凤霞; 李浩然; 于洋; 武锦涛
Original assignee: Dalian University of Technology
Current assignee: Dalian University of Technology
Priority date: 2021-08-11
Filing date: 2021-08-11
Publication date: 2022-12-20
Anticipated expiration: 2041-08-11
Also published as: CN113669309A

Abstract

The invention discloses a condensation separation type air wave supercharging device and method, and belongs to the technical field of injection supercharging of gas jet. Under the working condition of large expansion ratio, the device can utilize high-pressure incident gas after expansion and temperature reduction as a cold source to carry out condensation and dehumidification on final gas generated by the device; the device can directly recover compression work generated by expansion of high-pressure incident gas to boost the gas in the tube, and utilizes the boosted gas to inject and boost low-pressure gas, so that the problems of low efficiency and the like when high-pressure gas is directly used for injecting and boosting are effectively solved, and the high-efficiency utilization of high-pressure gas energy is realized; the single rotor is utilized to complete the cold source production and injection pressurization process, so that the manufacturing cost of the device can be saved, and the structural size of the equipment is optimized; the external adjustment of the deflection angle between the nozzles of the device can be realized by the nozzle adjusting plate and other parts, and the installation and debugging of the equipment are facilitated. The invention can be widely applied to the fields of exploitation and purification of natural gas resources such as coal bed gas and the like.

Description

Condensation separation type air wave supercharging device and method

Technical Field

The invention relates to a condensation separation type air wave supercharging device and method, and belongs to the technical field of gas jet supercharging.

Background

The gas wave technology for realizing energy transfer between gases by utilizing pressure waves is a novel comprehensive utilization technology of pressure energy, and is mainly applied to the fields of dehumidification and purification of natural gas, production and manufacture of low-temperature gas sources, exploitation of low-pressure coal-bed gas wells, pressurization and gathering and transportation of low-pressure gas and the like. The traditional equipment which can realize injection pressurization by utilizing the pressure of high-pressure gas comprises an expander-compressor unit, a turbocharger, a static injector and the like. The expansion machine-compressor unit, the turbocharger and other equipment have complex structures, high processing and maintenance cost and poor liquid carrying operation capacity, and the static ejector is static equipment with a simple structure, but has low efficiency and is easy to cause a large amount of pressure energy waste.

The gas ripples booster compressor through gas ripples technique development then possesses that equipment mechanism is simple, can take advantages such as liquid operation to compare in the energy transfer mode of the direct mixing of static ejector high-low pressure gas, the gas ripples booster compressor carries out energy exchange through the pressure wave, and its isentropic efficiency is also higher relatively. However, the existing air wave superchargers such as the patent axial flow jet air wave supercharger CN201220115597.0 and the radial flow jet air wave supercharger CN201210081102.1 have the problems of low refractive index and low efficiency under the working condition of large expansion ratio.

Disclosure of Invention

In order to solve the above problems, the present invention provides a condensation separation type gas wave supercharging device and a working method thereof. Aiming at the problems in the prior art, under the working condition of large expansion ratio, firstly, the cold source is manufactured by utilizing high-pressure gas expansion, part of compression work generated by the expansion is recovered to obtain high-pressure return gas for injection, after injection pressurization is completed on the injected low-pressure gas, the cold source generated by the high-pressure gas expansion is utilized to condense and dehumidify the medium-pressure produced gas, the final medium-pressure dry gas is obtained, and the high-efficiency utilization of the energy of the high-pressure gas is realized.

The technical scheme adopted by the invention is as follows:

under the drive of the transmission shaft, the wave rotor rotates between the base and the medium-pressure supporting plate, the lower end of each oscillating tube is sequentially communicated with the high-pressure nozzle, and high-pressure gas is injected into the oscillating tubes to heat and boost the original gas in the tubes into high-temperature gas; when the upper end of the oscillating pipe is screwed to be communicated with the high-temperature gas outlet nozzle, high-temperature gas is sprayed into the high-temperature gas outlet cavity through the opening at the upper end of the oscillating pipe, the high-temperature nozzle adjusting plate and the high-temperature gas outlet nozzle in sequence; after the high-temperature gas flows out of the high-temperature gas outlet cavity, the pressure of the high-temperature gas can be adjusted through the high-temperature gas outlet adjusting valve; the high-temperature outlet air flows through the regulating valve, enters the heat recoverer to release heat energy, and then enters the high-pressure air return cavity to become high-pressure air return; when the wave rotor continues to rotate and the lower end of the oscillation tube is communicated with the low-temperature gas outlet nozzle, low-temperature gas which is formed by expanding and working conversion of high-pressure gas is discharged into the low-temperature gas outlet cavity through the low-temperature gas outlet nozzle; the low-temperature outlet gas enters the gas heat exchanger under the driving of the driving fan, enters the low-pressure gas return cavity after releasing cold quantity, and then enters the oscillating pipe to be used as low-pressure return gas to push the low-temperature gas to be discharged; the wave rotor continues to rotate, the lower end of the oscillating tube is communicated with the high-pressure air return nozzle, and at the moment, high-pressure return air in the high-pressure air return cavity is injected into the oscillating tube to compress gas in the tube, so that the gas in the tube is boosted to be medium-pressure gas production; when the oscillating pipe rotates to be communicated with the low-pressure air inlet nozzle, low-pressure air inlet in the low-pressure air inlet cavity is sucked into the oscillating pipe by a low-pressure area formed after high-pressure gas in the oscillating pipe expands, so that the low-pressure air inlet is injected; when the oscillating pipe continues to rotate to be communicated with the medium-pressure gas generating nozzle, the medium-pressure gas enters the medium-pressure gas generating cavity through the medium-pressure gas generating nozzle and the flow guide channel; the medium-pressure gas flows out of the medium-pressure gas-generating cavity and then enters the gas heat exchanger, the energy released by the low-temperature gas outlet is utilized to realize condensation, and when the medium-pressure gas flows through the gas-liquid separator, the medium-pressure gas is dehumidified, so that the whole condensation separation type gas wave pressurization process is completed.

When the pressure of a high-pressure gas source for injecting pressurized low-pressure gas is far greater than that of low-pressure injected gas, the pressure of the high-pressure gas source for injecting pressurized low-pressure gas can be reduced by the condensing gas wave pressurization method, and the specific pressure value can be controlled by a high-temperature gas outlet regulating valve, so that the injection pressurization process can be carried out at an expansion ratio with high efficiency. The condensing type gas wave supercharging method provided by the invention can overcome the defect that the performance of the traditional gas wave supercharger is limited under a large expansion ratio, ensures that the equipment has a better injection supercharging effect under a large expansion ratio, and improves the application range and the isentropic working efficiency of the equipment. The condensation gas wave pressurization method provided by the invention can also avoid the waste of high-pressure gas energy, the energy output in the high-pressure gas expansion process is effectively recycled for injecting low-pressure gas, and the cold energy generated in the expansion process is also utilized for condensation and dehumidification of the final product of equipment.

The device comprises a core component wave rotor driven by a transmission shaft, wherein the rotor consists of oscillating pipes with two open ends which are uniformly distributed along the circumferential direction, the oscillating pipes are completely different and are not communicated with each other, and the axial direction of each oscillating pipe is parallel to the axial direction of the rotor. The medium-pressure gas generating cavity, the medium-pressure and high-temperature exhaust cavities and the high-temperature exhaust nozzle are positioned at one end of the oscillating pipe; the high-pressure air inlet cavity and the high-pressure air inlet nozzle, the low-temperature air outlet cavity and the low-temperature air outlet nozzle, the high-pressure air return cavity and the high-pressure air return nozzle, and the low-pressure air inlet cavity and the low-pressure air inlet nozzle are all positioned at the other end of the oscillating pipe; the cavity between the outer wall surface of the rotor and the shell is the low-pressure air return cavity. The transmission shaft drives the rotor to rotate, so that the oscillating pipe is sequentially communicated with the nozzles, and the pressure and temperature gases are discharged into corresponding air cavities.

In order to ensure that two ends of the oscillating tube are communicated with different nozzles in sequence at a certain time interval, certain deflection angles among the nozzles are required to be ensured; in the invention, the deflection angle adjusting plate, the middle-pressure side bearing cover and the middle-pressure support plate are connected into a whole through the bolt, so that deflection angles between three nozzles such as a high-temperature gas outlet nozzle on the middle-pressure support plate and four fixed-position nozzles such as a high-pressure gas inlet nozzle arranged on the base can be adjusted by rotating the deflection angle adjusting plate to a proper angle; after the deflection angle is adjusted, a locking screw penetrating through the angle fixing plate is inserted between two teeth of the tooth type indexing disc which are right opposite to the through hole of the angle fixing plate, and then the fixation of the deflection angle can be realized.

The invention has the beneficial effects that: under the working condition of large expansion ratio, the injection rate and the isentropic efficiency of the traditional gas wave supercharger are lower, if the high-pressure inlet pressure is reduced by means of throttling, pressure reduction and the like, the injection pressurization process is carried out after the expansion ratio is reduced, although the injection effect can be improved, the high-pressure gas energy utilization rate is low, the pressure energy of the high-pressure gas is wasted, and the refrigeration efficiency is low; the invention utilizes the high-pressure gas expansion to produce the cold source, has high refrigeration efficiency, simultaneously recovers the output compression function to obtain the high-pressure return gas with moderate pressure to inject and pressurize the low-pressure gas, and utilizes the obtained low-temperature cold source to condense and dehumidify the medium-pressure gas, thereby realizing the full utilization of the excess high-pressure gas pressure under the working condition of large expansion ratio, ensuring higher index and obtaining the dehumidified and purified dry and medium-pressure gas; the invention realizes expansion refrigeration and injection pressurization by using one wave rotor, reduces equipment processing investment and is convenient to transport and assemble.

Drawings

FIG. 1 is a flow chart showing the connection relationship between the components of a condensing and separating type gas wave supercharging device.

Fig. 2 is a schematic diagram of a multi-cavity wave pressure booster of a condensation separation type wave pressure device.

Fig. 3 is a structural view of a base of a multi-chamber type gas wave supercharger.

Fig. 4 is anbase:Sub>A-base:Sub>A end view of fig. 2.

Fig. 5 is a cross-sectional view of the wave rotor of the multi-chamber gas wave booster.

Fig. 6 is a schematic structural view of an angling plate.

In the figure: 1. the high-pressure gas inlet valve, 2, a high-pressure gas inlet cavity, 3, a low-temperature gas outlet cavity, 4, a high-pressure gas return cavity, 5, a low-pressure gas inlet cavity, 6, a driving fan, 7, a gas-liquid separator, 8, a gas heat exchanger, 9, a medium-pressure gas generating regulating valve, 10, a medium-pressure gas generating cavity, 11, a multi-cavity gas wave supercharger, 12, a low-pressure gas return cavity, 13, a high-temperature gas outlet cavity, 14, a high-temperature gas outlet regulating valve, 15, a heat recoverer, 16, a high-pressure gas inlet nozzle, 17, a wave rotor, 18, an oscillating pipe, 19, a high-temperature nozzle regulating plate, 20, a high-temperature gas outlet nozzle, 21, a medium-pressure supporting plate, 22, a flat cover sealing head, 23, an offset angle regulating plate, 24, a transmission shaft, 25, a medium-pressure side bearing cover, 26, an angle fixing plate, 27, a first bearing set, 28, a flow guide channel, 29, a medium-pressure gas generating nozzle, 30, a medium-pressure nozzle regulating plate, a medium-pressure screw regulating plate, 31, a shell, 32, a high-pressure gas return nozzle, 33, a second bearing set, 34, a base, 35, a low-temperature gas outlet nozzle, 36, a low-pressure gas inlet nozzle, a low-pressure indexing plate, 37, 38, and a locking indexing plate.

Detailed Description

The following further describes a specific embodiment of the present invention with reference to the drawings and technical solutions.

Fig. 1 shows a flow chart of connection relationship of components of a condensation separation type air wave supercharging device according to the present invention. The condensation separation type gas wave supercharging device comprises a high-pressure air inlet valve 1, a driving fan 6, a gas-liquid separator 7, a gas heat exchanger 8, a medium-pressure gas production regulating valve 9, a multi-cavity gas wave supercharger 11, a high-temperature gas outlet regulating valve 14 and a heat recoverer 15; the lower end of the multi-cavity type gas wave supercharger 11 is uniformly provided with four air cavities, namely a high-pressure air inlet cavity 2, a low-temperature air outlet cavity 3, a high-pressure air return cavity 4 and a low-pressure air inlet cavity 5, the upper end of the multi-cavity type gas wave supercharger is provided with three air cavities from bottom to top, namely a low-pressure air return cavity 12, a high-temperature air outlet cavity 13 and a medium-pressure gas production cavity 10, and each air cavity is correspondingly provided with a connector; the high-pressure air inlet valve 1 is connected with the high-pressure air inlet cavity 2, the high-temperature air outlet cavity 13 is connected with the high-pressure air return cavity 4 through the high-temperature air outlet regulating valve 14 and the heat recoverer 15, the low-temperature air outlet cavity 3 is connected with the low-pressure air return cavity 12 through the driving fan 6 and the gas heat exchanger 8, and the medium-pressure gas production cavity 10 is connected with the gas-liquid separator 7 through the medium-pressure gas production regulating valve 9 and the gas heat exchanger 8.

Fig. 2, 3 and 4 show a structure diagram of a multi-cavity wave booster of a condensation separation type wave booster device. The multi-cavity type gas wave supercharger 11 comprises a flat cover end socket 22, a shell 31 and a base 34, a wave rotor 17, a high-temperature nozzle adjusting plate 19, a medium-pressure supporting plate 21, a transmission shaft 24, a medium-pressure side bearing cover 25, a first bearing set 27, a medium-pressure nozzle adjusting plate 30, a second bearing set 33 and an deflection angle adjusting plate 23, wherein the wave rotor 17, the high-temperature nozzle adjusting plate 19, the medium-pressure supporting plate 21, the transmission shaft 24, the medium-pressure side bearing cover 25, the first bearing set 27, the medium-pressure nozzle adjusting plate 30 and the second bearing set 33 are arranged in the shell 31; the flat cover end enclosure 22 and the base 34 are respectively arranged at two ends of the shell 31; the high-temperature nozzle adjusting plate 19 and the medium-pressure nozzle adjusting plate 30 have the same thickness and are fixed on the lower end face of the lower partition plate of the medium-pressure supporting plate 21 through bolts; the wave rotor 17 is positioned below the high-temperature nozzle adjusting plate 19 and the medium-pressure nozzle adjusting plate 30 and above the base 34, and the wave rotor 17 is connected with the transmission shaft 24 through bolts and rotates at a fixed speed under the driving of the transmission shaft 24; the lower end of the transmission shaft 24 is inserted into the base 34, the lower end of the transmission shaft 24 is installed on the base 34, the middle part of the transmission shaft passes through the cylinder of the medium-pressure support plate 21, the upper end of the transmission shaft passes through the flat cover end socket 22 and the medium-pressure side bearing cover 25, the lower end of the transmission shaft 24 is fixed through the second bearing set 33, and the middle part of the transmission shaft is fixed through the first bearing set 27.

The interior of the base 34 is sequentially divided into a high-pressure air inlet cavity 2, a low-temperature air outlet cavity 3, a high-pressure air return cavity 4 and a low-pressure air inlet cavity 5 by clapboards; the upper end panel of the base 34 is provided with a high-pressure air inlet nozzle 16, a low-temperature air outlet nozzle 35, a high-pressure air return nozzle 32 and a low-pressure air inlet nozzle 36 which correspond to the air cavity in sequence.

The middle-pressure support plate 21 is of a circular tube structure, the upper end surface and the lower end surface of the circular tube are provided with baffle plates extending outwards, and the edges of the baffle plates are hermetically connected with the inner wall of the shell 31; the middle pressure support plate 21 is located at an upper portion inside the housing 31; the middle part and the upper part of the equipment are divided into a low-pressure air return cavity 12, a high-temperature air outlet cavity 13 and a medium-pressure air generating cavity 10 from bottom to top by the two layers of clapboards and the shell 31 of the flat cover end enclosure 22 and the medium-pressure support plate 21; a high-temperature gas outlet nozzle 20 and a medium-pressure gas outlet nozzle 29 corresponding to the gas cavity are respectively arranged on the lower partition plate of the medium-pressure support plate 21; a flow guide channel 28 is arranged between the two layers of the partition boards, one end of the flow guide channel is connected with a medium-pressure gas production nozzle 29, and the other end of the flow guide channel is connected with a medium-pressure gas production cavity 10 for guiding medium-pressure gas into the medium-pressure gas production cavity 10. The medium-pressure gas generating cavity 10 is positioned above the medium-pressure support plate 21; the upper surface of the upper partition plate of the medium-pressure support plate 21 and the lower surface of the deflection angle adjusting plate 23 are connected through a medium-pressure side bearing cover 25, the flat cap seal head 22 is positioned on the outer side of the upper end of the medium-pressure side bearing cover 25, the deflection angle adjusting plate 23 is positioned above the flat cap seal head 22, and the deflection angle adjusting plate 23 is connected with the upper surface of the flat cap seal head 22.

In order to ensure the rotation of the wave rotor 17, the lower end face of the wave rotor is required to keep a 0.05mm-5mm gap with the high-pressure air inlet nozzle 16, the low-temperature air outlet nozzle 35, the high-pressure air return nozzle 32 and the low-pressure air inlet nozzle 36, and the upper end face of the wave rotor is required to keep a 0.05mm-5mm gap with the high-temperature nozzle adjusting plate 19 and the medium-pressure nozzle adjusting plate 30.

Fig. 5 shows a cross-sectional view of the wave rotor of the multi-chamber gas wave booster. The wave rotor 17 is provided with 10-200 oscillating tubes 18 with equal sections, the length of which is 50mm-1000mm, and the two ends of which are opened along the circumferential direction, and the sections of the oscillating tubes are square, fan-shaped or round.

The ratio of the arc length of the central line of the high-temperature nozzle adjusting plate 19 and the medium-pressure nozzle adjusting plate 30 to the circumference of the middle diameter of the wave rotor 17 is 0.1-0.4; the two adjusting plates are fan-shaped rings with through holes, the shapes and the sizes of the holes are the same as those of the corresponding high-temperature gas outlet nozzle 20 and the medium-pressure gas outlet nozzle 29, when the adjusting plates are connected with the medium-pressure supporting plate, the through holes of the adjusting plates are completely overlapped with the nozzles, and the ratio of the arc length of the central line on the two sides to the circumference length of the central diameter of the wave rotor is 0.01-0.2.

Fig. 6 shows a schematic structural view of the multi-chamber gas wave booster angle adjustment plate 23. The deflection angle adjusting plate 23 is provided with a tooth type dividing plate 37, the included angle of the central lines of two adjacent teeth is 0.5-5 degrees, and the total number of teeth is 2-100 degrees. The flat cap end enclosure 22 seals the top end of the medium-pressure side bearing cover 25 and the shell 31 into a whole, and an angle fixing plate 26 is arranged on the flat cap end enclosure 22; the deflection angle adjusting plate 23 is of an annular structure, and a tooth type dividing plate 37 is arranged on the outer side edge of the deflection angle adjusting plate; the deflection angle adjusting plate 23 is connected with the top end of the medium-pressure side bearing gland 25 through a bolt and is fixed on the flat cap end enclosure 22; the lower end of the bearing cover 25 on the medium-pressure side is connected with the medium-pressure support plate 21 through a bolt; the angle fixing plate 26 is provided with threaded through holes corresponding to the indexing teeth of the tooth-type indexing disc 37, the number of the angle fixing plates 26 is equal to that of the tooth-type indexing disc 37, the number of the threaded through holes in the angle fixing plate 26 is equal to the number of layers of the indexing teeth, and the locking screw 38 is inserted into the space between two adjacent indexing teeth through the threaded through holes to lock the angle; the rotation of the deflection angle adjusting plate 23 can drive the middle pressure side bearing cover 25 connected with the deflection angle adjusting plate and the middle pressure support plate 21 connected with the middle pressure side bearing cover 25 to rotate by the same angle, thereby realizing the deflection angle adjustment between the middle pressure gas generating nozzle 29 and the high pressure gas inlet nozzle 16.

Of course, the condensing and separating type air wave supercharging device can also be arranged into an air wave refrigerating device and an air wave supercharging device during implementation of the invention. At the moment, the air wave refrigerating device is provided with a rotor, a group of air cavities (specifically comprising a high-pressure air inlet cavity, a low-temperature air outlet cavity, a high-temperature air outlet cavity and a low-pressure air return cavity), a group of high-pressure and high-temperature gas pressure regulating valves, a heat recoverer and a driving fan, and is used for providing a cold source in the air wave refrigerating process and providing a high-pressure source required by the injection pressurization process; the gas wave supercharging device is provided with a rotor, a group of gas cavities (specifically comprising a high-pressure gas return cavity, a low-pressure gas inlet cavity and a medium-pressure gas generation cavity), a gas-liquid separator and a gas heat exchanger, and is used for realizing injection supercharging of low-pressure gas and condensation dehumidification of final medium-pressure gas generation. In the embodiment, all the air cavities are integrated in a single multi-cavity type gas wave supercharger, and the whole effect of the invention is realized by using a single rotor, so that the manufacturing cost of equipment can be saved, and the volume of the equipment can be reduced.

Of course, when the invention is implemented, if the final medium-pressure gas production of the device does not need condensation and dehumidification, the cold energy generated by high-pressure gas inlet expansion refrigeration can also be recycled by other modes.

The working steps of the condensation separation type gas wave supercharging device are as follows:

(a) When the wave rotor 17 rotates, the lower end of each oscillating tube 18 is sequentially communicated with the high-pressure air inlet nozzle 16, high-pressure air in the high-pressure air inlet cavity 2 is injected into the oscillating tube 18 through the high-pressure air inlet nozzle 16, and the original air in the tube is compressed, so that the original air in the tube is heated and pressurized into high-temperature air; when the upper end of the oscillating tube 18 is screwed to be communicated with the high-temperature gas outlet nozzle 20, high-temperature gas is sprayed into the high-temperature gas outlet cavity 13 through the opening at the upper end of the oscillating tube, the high-temperature nozzle adjusting plate 19 and the high-temperature gas outlet nozzle 20 in sequence; because the high-temperature air outlet cavity 13 is connected with the high-pressure air return cavity 4 through the heat recoverer 15, high-temperature air flows out of the high-temperature air outlet cavity 13, then enters the heat recoverer 15 to release heat energy, and then enters the high-pressure air return cavity 4 to become high-pressure return air;

(b) The wave rotor 17 continues to rotate, the lower end of the oscillating tube 18 is communicated with the low-temperature gas outlet nozzle 35, the high-pressure gas after expansion work is reduced in temperature and converted into low-temperature gas, the low-temperature gas is discharged from the lower end of the oscillating tube 18 and is discharged into the low-temperature gas outlet cavity 3 through the low-temperature gas outlet nozzle 35; the low-temperature outlet gas enters a gas heat exchanger 8 under the drive of a driving fan 6, enters a low-pressure gas return cavity 12 after cold energy is released, and then enters an oscillating tube 18 to be used as low-pressure return gas to push the low-temperature gas to be discharged;

(c) The wave rotor 17 continues to rotate, the lower end of the oscillating tube 18 is communicated with the high-pressure return air nozzle 32, and at the moment, high-pressure return air in the high-pressure return air cavity 4 is injected into the oscillating tube 18 to compress gas in the tube, so that the gas in the tube is boosted into medium-pressure gas; when the oscillating pipe 18 is rotated to be communicated with the medium-pressure gas generating nozzle 29, the medium-pressure gas enters the medium-pressure gas generating nozzle 29 through the opening at the upper end of the oscillating pipe 18 and then enters the medium-pressure gas generating cavity 10 through the flow guide channel 28; when the oscillating pipe 18 rotates to be communicated with the low-pressure air inlet nozzle 36, low-pressure air in the low-pressure air inlet cavity 5 is sucked into the oscillating pipe 18 by a low-pressure area formed after high-pressure air in the oscillating pipe 18 expands, so that low-pressure air is injected; the medium-pressure gas flows out of the medium-pressure gas-generating cavity 10 and then enters the gas heat exchanger 8, the energy released by the low-temperature gas outlet is utilized to realize condensation, and when the medium-pressure gas flows through the gas-liquid separator 7, the medium-pressure gas is dehumidified, so that the whole condensation separation type gas wave pressurization process is completed.

Claims

1. The condensation separation type gas wave supercharging device is characterized by comprising a high-pressure air inlet valve (1), a driving fan (6), a gas-liquid separator (7), a gas heat exchanger (8), a medium-pressure gas production regulating valve (9), a multi-cavity gas wave supercharger (11), a high-temperature gas outlet regulating valve (14) and a heat recoverer (15);

the multi-cavity type gas wave supercharger (11) comprises a flat cover seal head (22), a shell (31), a base (34), a wave rotor (17), a high-temperature nozzle adjusting plate (19), a medium-pressure support plate (21), a transmission shaft (24), a medium-pressure side bearing cover (25), a first bearing set (27), a medium-pressure nozzle adjusting plate (30) and a second bearing set (33) which are arranged in the shell (31), and an offset angle adjusting plate (23) which is arranged outside the shell (31); the flat cover end enclosure (22) and the base (34) are respectively arranged at two ends of the shell (31);

the interior of the base (34) is uniformly divided into a high-pressure air inlet cavity (2), a low-temperature air outlet cavity (3), a high-pressure air return cavity (4) and a low-pressure air inlet cavity (5) by a partition plate, and each air cavity is correspondingly provided with an interface; a high-pressure air inlet nozzle (16), a low-temperature air outlet nozzle (35), a high-pressure air return nozzle (32) and a low-pressure air inlet nozzle (36) which correspond to the air cavity are sequentially arranged on the upper end panel of the base (34);

the middle-pressure supporting plate (21) is of a circular tube structure, the upper end face and the lower end face of the circular tube are provided with partition plates extending outwards, and the edges of the partition plates are hermetically connected with the inner wall of the shell (31); a medium pressure support plate (21) is located at the upper part in the shell (31); the middle part and the upper part of the equipment are divided into a low-pressure air return cavity (12), a high-temperature air outlet cavity (13) and a medium-pressure air generating cavity (10) from bottom to top by two layers of clapboards and a shell (31) of a flat cover end enclosure (22) and a medium-pressure support plate (21), and each air cavity is correspondingly provided with an interface; a high-temperature gas outlet nozzle (20) and a medium-pressure gas generating nozzle (29) which correspond to the gas cavity are respectively arranged on the lower partition plate of the medium-pressure support plate (21); a flow guide channel (28) is arranged between the two layers of partition plates, one end of the flow guide channel is connected with a medium-pressure gas production nozzle (29), and the other end of the flow guide channel is connected with a medium-pressure gas production cavity (10) and is used for guiding medium-pressure gas production into the medium-pressure gas production cavity (10); the medium-pressure gas generating cavity (10) is positioned above the medium-pressure support plate (21); the upper surface of an upper clapboard of a middle-pressure support plate (21) is connected with the lower surface of a deflection angle adjusting plate (23) through a middle-pressure side bearing cover (25), a flat cover seal head (22) is positioned at the outer side of the upper end of the middle-pressure side bearing cover (25), the deflection angle adjusting plate (23) is positioned above the flat cover seal head (22), and the deflection angle adjusting plate (23) is connected with the upper surface of the flat cover seal head (22);

the high-pressure air inlet valve (1) is connected with the high-pressure air inlet cavity (2), the high-temperature air outlet cavity (13) is connected with the high-pressure air return cavity (4) through a high-temperature air outlet adjusting valve (14) and a heat recoverer (15), the low-temperature air outlet cavity (3) is connected with the low-pressure air return cavity (12) through a driving fan (6) and a gas heat exchanger (8), and the medium-pressure air generating cavity (10) is connected with the gas-liquid separator (7) through a medium-pressure air generating adjusting valve (9) and the gas heat exchanger (8);

the high-temperature nozzle adjusting plate (19) has the same thickness as the medium-pressure nozzle adjusting plate (30) and is fixed on the lower end face of the lower partition plate of the medium-pressure support plate (21) through bolts; the wave rotor (17) is positioned below the high-temperature nozzle adjusting plate (19) and the medium-pressure nozzle adjusting plate (30) and above the base (34), and the wave rotor (17) is connected with the transmission shaft (24) through bolts and rotates at a fixed speed under the drive of the transmission shaft (24); the lower end of a transmission shaft (24) is inserted into a base (34), the middle part of the transmission shaft penetrates through a cylinder of a medium-pressure support plate (21), the upper end of the transmission shaft penetrates through a flat cover end socket (22) and a medium-pressure side bearing cover (25), the lower end of the transmission shaft (24) is fixed through a second bearing group (33), and the middle part of the transmission shaft is fixed through a first bearing group (27);

the flat cover end enclosure (22) seals the top end of the medium-pressure side bearing cover (25) and the shell (31) into a whole, and an angle fixing plate (26) is arranged on the flat cover end enclosure (22); the deflection angle adjusting plate (23) is of an annular structure, a tooth type indexing disc (37) is arranged on the outer side edge of the deflection angle adjusting plate, the included angle of the center lines of two adjacent teeth of the tooth type indexing disc (37) is 0.5-5 degrees, and the total number of teeth is 2-100 degrees; the deflection angle adjusting plate (23) is connected with the top end of the medium-pressure side bearing cover (25) through a bolt and is fixed on the flat cover end enclosure (22); the lower end of the medium-pressure side bearing gland (25) is connected with a medium-pressure support plate (21) through a bolt; the angle fixing plate (26) is provided with threaded through holes corresponding to indexing teeth of the tooth-type indexing disc (37), the number of the angle fixing plates (26) is equal to that of the tooth-type indexing disc (37), the number of the threaded through holes in the angle fixing plate (26) is equal to the number of layers of the indexing teeth, and the locking screw (38) is inserted into a space between two adjacent indexing teeth through the threaded through holes to lock an angle; the rotation of the deflection angle adjusting plate (23) can drive the middle pressure side bearing cover (25) connected with the deflection angle adjusting plate and the middle pressure support plate (21) connected with the middle pressure side bearing cover (25) to rotate by the same angle, so that the deflection angle adjustment between the middle pressure gas generating nozzle (29) and the high pressure gas inlet nozzle (16) is realized.

2. The condensing-separating gas wave booster device according to claim 1, wherein: 10-200 constant-section oscillating tubes (18) with openings at two ends and 50-1000 mm in length are circumferentially arranged on the wave rotor (17), and the cross section is square, fan-shaped or circular; in order to ensure that the wave rotor (17) rotates, a gap of 0.05mm-5mm is required to be kept between the lower end surface of the wave rotor and the high-pressure air inlet nozzle (16), the low-temperature air outlet nozzle (35), the high-pressure air return nozzle (32) and the low-pressure air inlet nozzle (36), and a gap of 0.05mm-5mm is required to be kept between the upper end surface of the wave rotor and the high-temperature nozzle adjusting plate (19) and the medium-pressure nozzle adjusting plate (30).

3. A condensing split type gas wave pressure boosting device according to claim 1 or 2, wherein: the ratio of the arc length of the central line of the high-temperature nozzle adjusting plate (19) to the arc length of the central line of the medium-pressure nozzle adjusting plate (30) to the circumference length of the middle diameter of the wave rotor (17) is 0.1-0.4; the two adjusting plates are fan rings with through holes, the shapes and the sizes of the holes are the same as those of the corresponding high-temperature gas outlet nozzle (20) and the medium-pressure gas outlet nozzle (29), when the adjusting plates are connected with the medium-pressure supporting plate (21), the through holes of the adjusting plates are completely coincided with the nozzles, and the ratio of the arc length of the central lines on the two sides to the circumference length of the central diameter of the wave rotor is 0.01-0.2.

4. A method for pressurizing a condensing-separating type gas wave pressurizing apparatus according to claim 2 or 3, wherein: the method comprises the following steps:

step (a), when the wave rotor (17) rotates, the lower end of each oscillating tube (18) is sequentially communicated with a high-pressure air inlet nozzle (16), high-pressure air in the high-pressure air inlet cavity (2) is injected into the oscillating tubes (18) through the high-pressure air inlet nozzle (16), and original air in the tubes is compressed, so that the original air in the tubes is heated and pressurized into high-temperature air; when the upper end of the oscillating pipe (18) is screwed to be communicated with the high-temperature gas outlet nozzle (20), high-temperature gas is sprayed into the high-temperature gas outlet cavity (13) through the opening at the upper end of the oscillating pipe, the high-temperature nozzle adjusting plate (19) and the high-temperature gas outlet nozzle (20) in sequence; because the high-temperature air outlet cavity (13) is connected with the high-pressure air return cavity (4) through the heat recoverer (15), high-temperature air flows out of the high-temperature air outlet cavity (13), enters the heat recoverer (15) to release heat energy, and then enters the high-pressure air return cavity (4) to become high-pressure air return;

step (b), the wave rotor (17) continues to rotate, the lower end of the oscillating pipe (18) is communicated with the low-temperature gas outlet nozzle (35), the high-pressure gas after expansion work is reduced in temperature and converted into low-temperature gas, the low-temperature gas is discharged from the lower end of the oscillating pipe (18) and is discharged into the low-temperature gas outlet cavity (3) through the low-temperature gas outlet nozzle (35); the low-temperature discharged air enters a gas heat exchanger (8) under the driving of a driving fan (6), enters a low-pressure air return cavity (12) after cold energy is released, and then enters an oscillating pipe (18) to be used as low-pressure air return to push the low-temperature gas to be discharged;

step (c), as the wave rotor (17) continues to rotate, the lower end of the oscillating tube (18) is communicated with the high-pressure return air nozzle (32), at the moment, high-pressure return air in the high-pressure return air cavity (4) is injected into the oscillating tube (18), and gas in the tube is compressed, so that the gas in the tube is boosted into medium-pressure produced gas; when the oscillating pipe (18) is rotated to be communicated with the medium-pressure gas generating nozzle (29), medium-pressure gas enters the medium-pressure gas generating nozzle (29) through the opening at the upper end of the oscillating pipe (18) and then enters the medium-pressure gas generating cavity (10) through the flow guide channel (28); when the oscillating pipe (18) rotates to be communicated with the low-pressure air inlet nozzle (36), low-pressure inlet air in the low-pressure air inlet cavity (5) is sucked into the oscillating pipe (18) by a low-pressure area formed after high-pressure air in the oscillating pipe (18) expands, so that low-pressure inlet air is injected; the medium-pressure gas flows out of the medium-pressure gas generating cavity (10) and then enters the gas heat exchanger (8), condensation is realized by utilizing the energy released by the low-temperature gas outlet, and when the medium-pressure gas flows through the gas-liquid separator (7), the medium-pressure gas generating cavity is dehumidified, so that the whole condensation separation type gas wave pressurization process is completed.