A siphon liquid circulation energy providing device and system
By using a multi-stage shell structure and safety monitoring components in a siphon liquid circulation energy supply device, the problems of single power output and adaptability to cold environments in traditional devices are solved, achieving efficient energy conversion and improved safety, making it suitable for cold environments and the renovation of old factories.
Patent Information
- Authority / Receiving Office
- CN · China
- Patent Type
- Applications(China)
- Current Assignee / Owner
- FUZHI ELECTRICAL EQUIPMENT (ZAOZHUANG) CO LTD
- Filing Date
- 2026-04-29
- Publication Date
- 2026-06-05
AI Technical Summary
Traditional liquid circulation power units suffer from problems such as single power output, low circulation efficiency, inability to be expanded to multiple stages, easy freezing and failure in cold environments, lack of safety monitoring, and inability to adapt to the renovation of old factories.
It adopts a siphon liquid circulation energy supply device, which includes a multi-stage shell structure, impeller disk, liquid downflow and upflow pipelines, solenoid valves, pressure display, thermometer and safety valve, etc. It realizes dual work and multi-stage series connection, supports low freezing point media, and is equipped with safety monitoring and inert gas protection. It is suitable for extremely cold environments and old factory renovation.
It improves energy conversion efficiency, supports high power output, adapts to cold environments, provides safety monitoring and protection, is compatible with old factory renovation, and reduces operating energy consumption and renovation costs.
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Figure CN122148472A_ABST
Abstract
Description
Technical Field
[0001] This invention relates to the field of fluid dynamic energy conversion technology, specifically to a siphon liquid circulation energy supply device and system. Background Technology
[0002] Traditional liquid circulation power units generally suffer from problems such as single power output, low circulation efficiency, inability to be expanded to multiple stages, easy freezing and failure in cold environments, lack of safety monitoring, and inability to be adapted to the renovation of old factories.
[0003] The existing technology has the following drawbacks:
[0004] The single-cycle structure has limited output power and cannot achieve multi-stage series expansion, making it difficult to meet the demand for high-power output.
[0005] The nozzleless pressurization structure results in weak liquid impact kinetic energy and low energy conversion efficiency.
[0006] It cannot adapt to low temperature and extremely cold environments; ordinary media are prone to freezing, which can damage the device.
[0007] Without real-time monitoring of pressure, temperature, and liquid level, the operation safety is poor.
[0008] Lacking electrostatic protection and inert gas protection, its use in enclosed environments poses safety hazards.
[0009] It cannot flexibly connect multiple units in series and is not suitable for old factory renovation or multi-unit linkage scenarios with the same medium. Therefore, a siphon liquid circulation energy supply device and system is proposed. Summary of the Invention
[0010] In view of this, the present invention provides two siphon liquid circulation energy supply devices and systems. The first one is to solve or alleviate the technical problems existing in the prior art, and at least provides a beneficial alternative.
[0011] The technical solution of the present invention is implemented as follows: A siphon liquid circulation energy supply device includes a first housing, a first partition plate fixedly connected to the inner side wall of the first housing, a first energy output shaft rotatably connected to the inner side wall of the first housing via a bearing, one end of the first energy output shaft penetrating the first housing and the first partition plate, impeller disks fixedly connected to the outer side wall of the first energy output shaft above and below the first partition plate, a first liquid downflow pipe symmetrically connected to the outer side wall of the first housing above the first partition plate, two second liquid downflow pipes symmetrically connected to the outer side wall of the first housing below the first partition plate, a liquid pump connected to one end of the first liquid downflow pipe, the liquid outlet end of the liquid pump connected to the second liquid downflow pipe, a second solenoid valve installed on the outer side wall of the first liquid downflow pipe, two liquid upflow pipes symmetrically connected to the outer side wall of the first housing, and a third solenoid valve installed on the outer side wall of the liquid upflow pipe.
[0012] More preferably, two first pressure displays are symmetrically mounted on the outer side wall of the first housing, and a first thermometer is mounted on the outer side wall of the first housing.
[0013] More preferably, the outer wall of the first housing is connected to two first liquid inlet pipes, the outer wall of the first housing is connected to a first exhaust pipe, and the outer walls of the first liquid inlet pipe and the first exhaust pipe are each equipped with a first solenoid valve.
[0014] More preferably, the outer wall of the first housing is connected to two first safety valves.
[0015] More preferably, a first gas diversion plate is installed on the inner sidewall of the first housing, and a first liquid diversion plate is installed on the inner sidewall of the first housing below the first gas diversion plate.
[0016] More preferably, two first level gauges are installed on the outer side wall of the first housing.
[0017] Further preferably, the device also includes a second housing, the inner wall of which is fixedly connected to a second partition plate. The inner wall of the second housing is rotatably connected to a second energy output shaft via a bearing. One end of the second energy output shaft passes through the second housing and the second partition plate. The outer wall of the second energy output shaft is symmetrically connected to four upper cavity nozzles above the second partition plate. The outer wall of the second energy output shaft is fixedly connected to a liquid downward cavity below the second partition plate. The outer wall of the liquid downward cavity is symmetrically connected to four lower cavity nozzles. Two electric push rods are symmetrically installed on the inner wall of the second housing. The telescopic ends of the electric push rods are fixedly connected to baffles. Six liquid inlet holes are symmetrically opened on the outer wall of the second energy output shaft.
[0018] More preferably, a second gas diverter plate is fixedly connected to the inner wall of the second housing, and a second liquid diverter plate is fixedly connected to the inner wall of the second housing below the second gas diverter plate.
[0019] More preferably, the outer wall of the second housing is connected to two second liquid inlet pipes, the outer wall of the second housing is connected to a second exhaust pipe, the outer walls of the second liquid inlet pipe and the second exhaust pipe are each equipped with a fourth solenoid valve, the outer wall of the second housing is equipped with two second safety valves, the outer wall of the second housing is symmetrically equipped with two second level gauges, the outer wall of the second housing is equipped with two second pressure displays, and the outer wall of the second housing is equipped with a second thermometer.
[0020] The second type of siphon liquid circulation energy supply system includes a third housing and a third energy output shaft, a fourth housing and a fourth energy output shaft, a fifth housing and a fifth energy output shaft, a sixth housing and a sixth energy output shaft, a seventh housing and a seventh energy output shaft, and an eighth housing and an eighth energy output shaft.
[0021] The embodiments of the present invention have the following advantages due to the adoption of the above technical solutions:
[0022] This invention features dual impeller impact drive or nozzle jet drive, significantly improving energy conversion efficiency. It allows for flexible multi-stage series connection and expansion, supporting arbitrary extension and combination of the third, fourth, fifth, sixth, seventh, and eighth housings. It can achieve single-axis, dual-axis, and multi-axis output, suitable for high-power applications. It supports low-freezing-point media such as ethanol, isopropanol, and propylene glycol, and does not freeze at -40℃, making it suitable for frigid regions such as Northeast and Northwest China. It features real-time monitoring of pressure, temperature, and liquid level, equipped with safety valves and inert gas filling, providing anti-static, explosion-proof, and leakage-proof protection. It is suitable for retrofitting existing factories. The multi-stage housings do not require equal height or rigid connections, and can share the same liquid medium, making retrofitting simple and cost-effective. The closed-loop siphon circulation requires no continuous external energy source, relying on pressure difference + siphon + pump-assisted circulation, resulting in low operating energy consumption and stable output.
[0023] The above overview is for illustrative purposes only and is not intended to be limiting in any way. In addition to the illustrative aspects, embodiments, and features described above, further aspects, embodiments, and features of the invention will become readily apparent from the accompanying drawings and the following detailed description. Attached Figure Description
[0024] To more clearly illustrate the technical solutions in the embodiments of this application or the prior art, the drawings used in the description of the embodiments or the prior art will be briefly introduced below. Obviously, the drawings described below are only some embodiments of this application. For those skilled in the art, other drawings can be obtained based on these drawings without creative effort.
[0025] Figure 1 This is a structural diagram of the first housing of the present invention;
[0026] Figure 2 This is a structural view of the first housing of the present invention from one perspective;
[0027] Figure 3 This is a two-view structural diagram of the first housing of the present invention;
[0028] Figure 4 This is a cross-sectional view of the first housing of the present invention;
[0029] Figure 5 This is a structural diagram of the second housing of the present invention;
[0030] Figure 6 This is a structural view of the second housing of the present invention from one perspective;
[0031] Figure 7 This is a cross-sectional view of the second housing of the present invention;
[0032] Figure 8 This is a cross-sectional view of the hollow energy output shaft in this invention;
[0033] Figure 9 The module of the present invention Figure 1 ;
[0034] Figure 10 The module of the present invention Figure 2 .
[0035] Reference numerals: 1. First housing; 2. First energy output shaft; 3. First partition plate; 4. Impeller disk; 5. First gas distributor plate; 6. First liquid distributor plate; 7. First inlet pipe; 8. First exhaust pipe; 9. First solenoid valve; 10. First thermometer; 11. First pressure display; 12. First safety valve; 13. First level gauge; 14. First liquid downflow pipe; 15. Liquid pump; 16. Second liquid downflow pipe; 17. Second solenoid valve; 18. Liquid upflow pipe; 19. 20. Third solenoid valve; 21. Second housing; 22. Second energy output shaft; 23. Second partition; 24. Liquid inlet; 25. Liquid downward chamber; 26. Lower chamber nozzle; 27. Upper chamber nozzle; 28. Electric push rod; 29. Baffle; 30. Second gas diverter plate; 31. Second liquid diverter plate; 32. Second liquid inlet pipe; 33. Second exhaust pipe; 34. Fourth solenoid valve; 35. Second safety valve; 36. Second level gauge; 37. Second thermometer; 38. Second pressure display. Detailed Implementation
[0036] In the following description, only certain exemplary embodiments are briefly described. As those skilled in the art will recognize, the described embodiments can be modified in various ways without departing from the spirit or scope of the invention. Therefore, the drawings and description are considered to be exemplary in nature and not restrictive.
[0037] The embodiments of the present invention will now be described in detail with reference to the accompanying drawings.
[0038] like Figure 1-10 As shown, this embodiment of the invention provides a siphon liquid circulation energy supply device, including a first housing 1. A first partition 3 is fixedly connected to the inner wall of the first housing 1. A first energy output shaft 2 is rotatably connected to the inner wall of the first housing 1 via a bearing. One end of the first energy output shaft 2 passes through the first housing 1 and the first partition 3. Impeller disks 4 are fixedly connected to the outer wall of the first energy output shaft 2 above and below the first partition 3. A first liquid downpipe 14 is symmetrically connected to the outer wall of the first housing 1 above the first partition 3. Two second liquid downpipes 16 are symmetrically connected to the outer wall of the first housing 1 below the first partition 3. A liquid pump 15 is connected to one end of the first liquid downpipe 14. The outlet end of the liquid pump 15 is connected to the second liquid downpipe 16. A second solenoid valve 17 is installed on the outer wall of the first liquid downpipe 14. Two liquid uppipes 18 are symmetrically connected to the outer wall of the first housing 1. A third solenoid valve 19 is installed on the outer wall of the liquid uppipe 18.
[0039] In one embodiment, two first pressure displays 11 are symmetrically mounted on the outer side wall of the first housing 1, and a first thermometer 10 is mounted on the outer side wall of the first housing 1.
[0040] In one embodiment, the outer wall of the first housing 1 is connected to two first liquid inlet pipes 7, and the outer wall of the first housing 1 is connected to a first exhaust pipe 8. A first solenoid valve 9 is installed on the outer wall of both the first liquid inlet pipe 7 and the first exhaust pipe 8.
[0041] In one embodiment, the outer wall of the first housing 1 is connected to two first safety valves 12.
[0042] In one embodiment, a first gas diversion plate 5 is installed on the inner wall of the first housing 1, and a first liquid diversion plate 6 is installed on the inner wall of the first housing 1 below the first gas diversion plate 5.
[0043] In one embodiment, two first level gauges 13 are installed on the outer side wall of the first housing 1.
[0044] In one embodiment, the system further includes a second housing 20, with a second partition 22 fixedly connected to the inner wall of the second housing 20. A second energy output shaft 21 is rotatably connected to the inner wall of the second housing 20 via a bearing. One end of the second energy output shaft 21 passes through the second housing 20 and the second partition 22. Four upper cavity nozzles 26 are symmetrically connected to the outer wall of the second energy output shaft 21 above the second partition 22. A liquid downward cavity 24 is fixedly connected to the outer wall of the second energy output shaft 21 below the second partition 22. Four lower cavity nozzles 25 are symmetrically connected to the outer wall of the liquid downward cavity 24. Two electric push rods 27 are symmetrically installed on the inner wall of the second housing 20. A baffle 28 is fixedly connected to the telescopic end of the electric push rod 27. Six liquid inlet holes 23 are symmetrically opened on the outer wall of the second energy output shaft 21.
[0045] In one embodiment, a second gas diversion plate 29 is fixedly connected to the inner wall of the second housing 20, and a second liquid diversion plate 30 is fixedly connected to the inner wall of the second housing 20 below the second gas diversion plate 29.
[0046] In one embodiment, the outer wall of the second housing 20 is connected to two second inlet pipes 31, the outer wall of the second housing 20 is connected to a second exhaust pipe 32, the outer walls of the second inlet pipes 31 and the second exhaust pipe 32 are each equipped with a fourth solenoid valve 33, the outer wall of the second housing 20 is equipped with two second safety valves 34, the outer wall of the second housing 20 is symmetrically equipped with two second level gauges 35, the outer wall of the second housing 20 is equipped with two second pressure displays 37, and the outer wall of the second housing 20 is equipped with a second thermometer 36.
[0047] A siphonic liquid circulation energy supply system includes a third housing and a third energy output shaft, a fourth housing and a fourth energy output shaft, a fifth housing and a fifth energy output shaft, a sixth housing and a sixth energy output shaft, a seventh housing and a seventh energy output shaft, and an eighth housing and an eighth energy output shaft.
[0048] In operation, before use, the first safety valve 12 is adjusted to a reasonable safety value according to the applicable scenario. Starting from when there is no liquid in the first housing 1, liquid is introduced into the first inlet pipe 7, the second solenoid valve 17 is opened, and liquid enters the lower cavity from the first liquid downpipe 14 and the second liquid downpipe 16. When the pressure is high, the liquid is vented. When the liquid is a certain distance away from the impeller disk 4 in the lower cavity, it is observed through the level gauge. The second solenoid valves 17 on both sides are then closed, and liquid continues to be introduced into the upper cavity until it is a certain distance away from the impeller disk 4 in the upper cavity. Stop liquid input and exhaust. Close the first solenoid valve 9 on the first inlet pipe 7 and the first exhaust pipe 8. Open the second solenoid valve 17 and the liquid pump 15. The liquid pump 15 can be smoothly regulated by a variable frequency motor. Open the third solenoid valve 19. The liquid in the upper chamber enters the lower chamber, pushing the impeller 4 to rotate, thereby driving the first energy output shaft 2 to rotate. The volume of the gas below decreases and the pressure increases. The volume of the gas in the upper chamber increases and the pressure decreases. The pressure difference between the upper and lower chambers increases. The liquid in the lower chamber begins to rise into the upper chamber through the liquid ascending pipe 18, pushing the upper impeller 4 and the lower impeller 4 to rotate in the same direction. The operation of the liquid pump 15 increases the pressure difference between the upper and lower chambers, making the liquid thrust entering the liquid ascending pipe 18 greater, increasing the output power. Observe whether the first thermometer 10 and the first pressure display 11 are operating within the normal range. If they deviate from the normal operating range, take necessary measures to adjust them. For example, applicable scenarios include indoor non-icing, mostly water use, or manufacturer-owned liquid media, such as ultra-low temperature and long-term icing application scenarios, such as Northeast and Northwest China, etc., which require more... For media with low freezing points, such as ethanol, isopropanol, and propylene glycol, the media should be selected based on economic principles. For example, gaseous media related to anhydrous ethanol need to be replaced, such as by injecting inert gas or other gases. Safety should also be ensured in the event of static electricity or leakage in the first housing 1. The pressure difference value of the upper and lower pressure display 11 should be observed. If it is applied to moving parts such as automobiles and airplanes, multiple isolation plates with multiple inverted conical openings (large upper hole and small lower hole) with a wider upper part and a narrower lower part should be added to the liquid surface to prevent the liquid surface from impacting the impeller disk 4 during acceleration and deceleration.
[0049] Synchronous decompression operation:
[0050] The pressure can be increased and decreased through the first liquid inlet pipe 7. The pressure in the upper chamber can be reduced to near vacuum, which reduces the friction between the impeller disk 4 and the air, reduces the torque, increases the speed, and reduces the heat loss, thereby increasing the output power.
[0051] Synchronous boost operation:
[0052] Maintain the pressure difference between the upper and lower chambers. When the pressure in the lower chamber increases to the level of the first safety valve 12 located below the first partition 3, exhaust begins, and pressurization stops simultaneously. This increases torque and reduces speed.
[0053] Simultaneous depressurization and pressurization operation:
[0054] The upper chamber depressurizes and the lower chamber pressurizes, which can also increase the pressure difference between the upper and lower chambers, increase the upward speed and flow rate of the liquid, drive the impeller disk 4 to rotate faster, and increase the output power. In short, adjusting the pressure values of the upper and lower chambers can adjust the output power.
[0055] The cooling method should be selected based on the applicable scenario, such as fan, liquid cooling, or natural air circulation cooling. The insulation method can be indoor installation or bidirectional temperature regulation by connecting an air compressor, pressure tank, or venturi tube. Everything depends on the usage scenario, and the cooling method should be adopted accordingly.
[0056] Depending on the applicable scenario, adjust the second safety valve 34 to a reasonable safety value. Starting from when there is no liquid in the second housing 20, open the baffle 28 via the electric push rod 27, open the fourth solenoid valve 33, and inject liquid through the second inlet pipe 31. The liquid enters the lower chamber through the liquid descending chamber 24. Observe the second liquid level gauge 35 in the lower chamber. When it is a certain distance from the lower chamber nozzle 25, close the baffle 28 via the electric push rod 27. Continue to inject liquid into the upper chamber. According to the second liquid level gauge 35 in the upper chamber, when it is a certain distance from the upper chamber nozzle 26, stop the injection, close the fourth solenoid valve 33, and open the baffle 28 via the electric push rod 27. The liquid enters through the liquid descending chamber 24. The liquid enters the lower cavity through the lower cavity nozzle 25, causing the second energy output shaft 21 to rotate. The liquid level in the lower cavity rises, the gas volume decreases, and the gas pressure increases. At the same time, the gas volume in the upper cavity expands and the pressure decreases. The pressure difference pushes the liquid in the lower cavity through the liquid inlet 23 into the second energy output shaft 21, and then sprays it out through the upper cavity nozzle 26. This further increases the rotation speed of the second energy output shaft 21 and improves the energy output power. If applied to moving parts such as automobiles and airplanes, multiple upper and lower narrow isolation plates with multiple inverted conical (large upper hole and small lower hole) openings can be added to the liquid surface to prevent the liquid surface from impacting the upper cavity nozzle 26 and the lower cavity nozzle 25 during acceleration and deceleration.
[0057] Synchronous decompression operation:
[0058] The pressure can be increased and decreased through the second liquid inlet pipe 31 to ensure that the pressure in the upper cavity can be reduced to near vacuum during normal operation, thereby reducing the friction between the upper cavity nozzle 26 and the air, reducing torque, increasing rotational speed, and reducing heat loss, thus increasing output power.
[0059] Synchronous boost operation:
[0060] Maintaining the pressure difference between the upper and lower chambers, the pressure value of the lower chamber increases until the second safety valve 34 located below the second partition 22 begins to reduce exhaust, simultaneously stopping pressurization, increasing torque, and reducing speed;
[0061] Simultaneous depressurization and pressurization operation:
[0062] The upper chamber depressurizes and the lower chamber pressurizes, which can also increase the pressure difference between the upper and lower chambers, increase the upward speed and flow rate of the liquid, drive the upper chamber nozzle 26 to rotate faster, and increase the output power. In short, adjusting the pressure values of the upper and lower chambers can adjust the output power.
[0063] The cooling method should be selected based on the applicable scenario, such as fan, liquid cooling, or natural air circulation cooling. The insulation method can be indoor installation or bidirectional temperature regulation by connecting an air compressor, pressure tank, or venturi tube. Everything depends on the usage scenario, and the cooling method should be adopted accordingly.
[0064] refer to Figure 9 The third, fourth, and fifth shells are basically the same as the upper half of the partition of the first shell;
[0065] refer to Figure 10 The sixth, seventh, and eighth shells are basically the same as the upper part of the first shell partition. The sixth and eighth shells are connected in series, each with an energy output shaft. The seventh and eighth shells are connected in series, each with an energy output shaft. The eighth shell is equivalent to having two energy output shafts. The sixth and seventh shells are not directly physically connected and do not need to be of equal height. They are mostly used for the renovation of old factory buildings, where the manufacturer has the same liquid medium.
[0066] In combinations where two chambers share a partition or a shaft, the impellers attached to the upper and lower chambers can each have three interchangeable combinations.
[0067] for example:
[0068] 1 External impact impeller
[0069] 2. Liquid from top to bottom external impact turbine
[0070] 3. An external nozzle (or other shape, as long as it sprays liquid from the inside to the outside) from the inside of the pipeline to the outside.
[0071] As long as the upward and downward work of the liquid causes the energy output axis to rotate in the same direction, that's sufficient.
[0072] All nine combinations are within the scope of protection of this patent.
[0073] exist Figure 9 Figure 10 As demonstrated, the various cavities are connected in series, or similar circuits are connected in parallel or in a mixed configuration. The impeller can be a turbine or a centrifugal external spray, etc., all of which are within the scope of protection of this patent.
[0074] The above description is merely a specific embodiment of the present invention, but the scope of protection of the present invention is not limited thereto. Any person skilled in the art can easily conceive of various variations or substitutions within the technical scope disclosed in the present invention, and these should all be included within the scope of protection of the present invention. Therefore, the scope of protection of the present invention should be determined by the scope of the claims.
Claims
1. A siphon liquid circulation energy supply device, characterized in that: The system includes a first housing (1), with a first partition (3) fixedly connected to the inner wall of the first housing (1). A first energy output shaft (2) is rotatably connected to the inner wall of the first housing (1) via a bearing. One end of the first energy output shaft (2) passes through the first housing (1) and the first partition (3). Impeller disks (4) are fixedly connected to the outer wall of the first energy output shaft (2) above and below the first partition (3). A first liquid downflow pipe (14) is symmetrically connected to the outer wall of the first housing (1) above the first partition (3). The outer wall of the first housing (1) is symmetrically connected to two second liquid downpipes (16) below the first partition (3). One end of the first liquid downpipe (14) is connected to a liquid pump (15). The outlet end of the liquid pump (15) is connected to the second liquid downpipe (16). A second solenoid valve (17) is installed on the outer wall of the first liquid downpipe (14). The outer wall of the first housing (1) is symmetrically connected to two liquid uppipes (18). A third solenoid valve (19) is installed on the outer wall of the liquid uppipe (18).
2. The siphon liquid circulation energy supply device according to claim 1, characterized in that: Two first pressure displays (11) are symmetrically installed on the outer side wall of the first housing (1), and a first thermometer (10) is installed on the outer side wall of the first housing (1).
3. The siphon liquid circulation energy supply device according to claim 1, characterized in that: The outer wall of the first housing (1) is connected to two first liquid inlet pipes (7), and the outer wall of the first housing (1) is connected to a first exhaust pipe (8). The outer walls of the first liquid inlet pipe (7) and the first exhaust pipe (8) are both equipped with first solenoid valves (9).
4. The siphon liquid circulation energy supply device according to claim 1, characterized in that: The outer wall of the first housing (1) is connected to two first safety valves (12).
5. The siphon liquid circulation energy supply device according to claim 1, characterized in that: A first gas diversion plate (5) is installed on the inner wall of the first housing (1), and a first liquid diversion plate (6) is installed on the inner wall of the first housing (1) below the first gas diversion plate (5).
6. The siphon liquid circulation energy supply device according to claim 1, characterized in that: Two first level gauges (13) are installed on the outer side wall of the first housing (1).
7. The siphon liquid circulation energy supply device according to claim 1, characterized in that: It also includes a second housing (20), the inner wall of which is fixedly connected to a second partition (22), the inner wall of which is rotatably connected to a second energy output shaft (21) via a bearing, one end of which passes through the second housing (20) and the second partition (22), the outer wall of which is located above the second partition (22) and symmetrically connected to four upper cavity nozzles (26), the outer wall of which is located below the second partition (22) and is fixedly connected to a liquid downward cavity (24), the outer wall of which is symmetrically connected to four lower cavity nozzles (25), the inner wall of which is symmetrically installed with two electric push rods (27), the telescopic end of which is fixedly connected to a baffle (28), and the outer wall of which is symmetrically opened with six liquid inlet holes (23).
8. The siphon liquid circulation energy supply device according to claim 7, characterized in that: A second gas splitter plate (29) is fixedly connected to the inner wall of the second housing (20), and a second liquid splitter plate (30) is fixedly connected to the inner wall of the second housing (20) below the second gas splitter plate (29).
9. The siphon liquid circulation energy supply device according to claim 7, characterized in that: The outer wall of the second housing (20) is connected to two second liquid inlet pipes (31), the outer wall of the second housing (20) is connected to a second exhaust pipe (32), the outer walls of the second liquid inlet pipe (31) and the second exhaust pipe (32) are both equipped with a fourth solenoid valve (33), the outer wall of the second housing (20) is equipped with two second safety valves (34), the outer wall of the second housing (20) is symmetrically equipped with two second level gauges (35), the outer wall of the second housing (20) is equipped with two second pressure displays (37), and the outer wall of the second housing (20) is equipped with a second thermometer (36).
10. A siphon liquid circulation energy supply system, coupled with a siphon liquid circulation energy supply device as described in any one of claims 1-9, characterized in that: It includes a third housing and a third energy output shaft, a fourth housing and a fourth energy output shaft, a fifth housing and a fifth energy output shaft, a sixth housing and a sixth energy output shaft, a seventh housing and a seventh energy output shaft, and an eighth housing and an eighth energy output shaft.