CN211288052U - Wind energy water pumping equipment on ocean - Google Patents

Abstract

The utility model discloses an offshore wind energy water pumping device, which comprises a seabed foundation, a seabed connecting piece, a lower floating box, more than two vertical supporting columns, a fixed cylinder assembly, an upper telescopic cylinder assembly and a lower telescopic cylinder assembly, wherein the upper telescopic cylinder assembly conveys seawater to the position above a seawater plane when the tide falls, the top ends of the more than two vertical supporting columns are provided with a platform, a compressed gas control part is arranged above the platform, a plurality of upright columns higher than the sea level are arranged near the platform, the top end of each upright column is provided with a wind energy compressed gas preparation unit, the compressed gas prepared by the wind energy compressed gas preparation unit is introduced into the compressed gas control part, the lower telescopic cylinder assembly comprises a lower telescopic cylinder body and a water-gas separated type diving box body which moves up and down along a vertical supporting column, the lower telescopic cylinder assembly conveys the seawater to a position above the seawater level through the fixed cylinder assembly when ascending. The utility model discloses wind energy pumping equipment on ocean can improve the efficiency that the sea water carried to the sea water on the plane.

Description

Wind energy water pumping equipment on ocean

Technical Field

The utility model relates to a wind energy water pumping equipment on ocean.

Background

The change of moon attraction causes a tidal phenomenon, which causes the sea water level to rise and fall periodically, and the energy generated by the sea water falling and flowing is called tidal energy. Ocean tidal energy is as a clean energy, and people have already worked on the utilization of ocean tidal energy, and chinese patent discloses a ocean tidal energy telescopic cylinder water pump, including body assembly, telescoping cylinder and lower base jar, the body assembly be located the top of telescoping cylinder, lower base jar be located the below of telescoping cylinder, lower base jar have the outlet, the telescoping cylinder constitute by two ring flanges and telescoping cylinder body, the telescoping cylinder body is located between two ring flanges, the body assembly have a plurality of hollow flotation pontoon portions, the cavity of flotation pontoon portion in have the sea water that increases flotation pontoon portion weight when falling the tide. The floating body assembly is provided with an upper supporting cylinder, the hollow floating cylinder parts are connected with the upper supporting cylinder into a whole, and the upper supporting cylinder is provided with a telescopic cylinder water inlet control valve. The two flange plates of the telescopic cylinder are respectively connected with the upper supporting cylinder and the lower base cylinder through bolt and nut connecting pairs, the top of the floating cylinder part is provided with a floating cylinder part vent pipe, and the bottom of the floating cylinder part is provided with a floating cylinder part water inlet and outlet control valve. A bottom plate is fixedly connected below the lower base cylinder, a support column is fixed on the bottom plate, and the support column penetrates through the edge of the lower base cylinder and the edge of the upper support cylinder. And a telescopic cylinder water discharge control valve is arranged at a water discharge port of the lower base cylinder. The ocean tidal energy telescopic cylinder water pump can be widely applied to the aspects of ocean tidal water storage and power generation, seawater desalination, seawater culture, seawater solar salt and the like. However, the whole weight of the water inlet and outlet floating drum is increased by controlling the floating drum part to be filled with seawater at a high tide level by using the fall of ocean tides only during the tide falling process, so that the telescopic cylinder is compressed to enable the seawater in the lower base cylinder to generate high pressure in the tide falling process, and the water pumping is realized. The ocean tidal energy telescopic cylinder water pump with the structure has high transportation and installation cost due to the implementation on the sea, and has important significance on how to improve the efficiency of conveying seawater to the seawater level.

SUMMERY OF THE UTILITY MODEL

The utility model aims to solve the technical problem that a wind energy pumping equipment on ocean is provided, this kind of wind energy pumping equipment on ocean can improve the sea water and carry the efficiency on the sea water plane, can adapt to marine geographic environment, reduces use cost.

In order to solve the technical problem, the technical scheme of the utility model is that: an offshore wind energy water pumping device comprises a seabed foundation, a seabed connecting piece, a lower floating box, more than two vertical supporting columns, a fixed cylinder assembly, an upper telescopic cylinder assembly and a lower telescopic cylinder assembly, wherein the lower ends of the more than two vertical supporting columns are fixedly connected with the lower floating box, the upper end of the seabed connecting piece is connected with the lower floating box, the lower end of the seabed connecting piece is connected with the seabed foundation, the fixed cylinder assembly comprises a fixed cylinder fixedly connected on the vertical supporting columns and a water pipe component communicated with the fixed cylinder, the upper telescopic cylinder assembly is positioned at the upper part of the fixed cylinder assembly, the lower telescopic cylinder assembly is positioned at the lower part of the fixed cylinder assembly, the upper telescopic cylinder assembly and the lower telescopic cylinder assembly both move up and down along the vertical supporting columns, the upper telescopic cylinder assembly conveys seawater to a seawater level when the upper telescopic cylinder assembly falls into tide, the top ends of the more than two vertical supporting columns are provided with a platform, a compressed gas control part is, the device comprises a platform, a plurality of vertical columns, a wind energy compressed gas preparation unit, a compressed gas control part, a lower telescopic cylinder assembly, a water-gas separation type diving box body and a fixing cylinder, wherein the vertical columns are arranged near the platform, the wind energy compressed gas preparation unit is arranged at the top end of each vertical column, the compressed gas prepared by the wind energy compressed gas preparation unit is introduced into the compressed gas control part, the lower telescopic cylinder assembly comprises a lower telescopic cylinder body and the water-gas separation type diving box body which moves up and down along a vertical supporting column, the water-gas separation type diving box body is arranged below the lower telescopic cylinder body, the water-gas separation type diving box body is driven by the compressed gas prepared by the wind energy compressed gas preparation units to ascend and descend, the upper part of the lower telescopic cylinder body is communicated with the fixing cylinder, a limiting part for supporting the water-gas separation type diving box body is arranged at the lower part of the vertical supporting.

The wind energy compressed gas preparation unit comprises a wind wheel assembly, a wind wheel assembly output shaft, a rotating disc, a wind energy inflator fixing seat, a wind energy air guide pipe and a plurality of wind energy inflators, the wind wheel component is positioned above the upright post and is provided with a wind wheel component output shaft, a rotating disc is arranged at the extending end of the wind wheel component output shaft, a plurality of wind energy inflators are fixedly connected on a wind energy inflator fixing seat, compressed gas generated by each wind energy inflator is output through a wind energy air duct, the central line of a piston rod of each wind energy inflator is parallel to the central line of the wind wheel component output shaft, the extending end of the piston rod of each wind energy inflator is connected with the rotating disc, and the end surface of the rotating disc is provided with a plurality of alternate protruding areas and recessed areas which are in smooth transition, when the output shaft of the wind wheel component drives the rotating disc to rotate, the extending end of the piston rod of the wind energy inflator is always jointed with the end face of the rotating disc.

The center line of the piston rod of each wind energy inflator is positioned on a concentric circle which takes the center line of the rotating disc as the center of a circle.

The water-gas separation type diving box body comprises a compressed gas storage cavity, a gas drainage cavity, a gas guide piece and a compressed gas guide-in piece, wherein the compressed gas storage cavity is a closed space located in the middle of the water-gas separation type diving box body, compressed gas is contained in the compressed gas storage cavity, seawater is arranged in the gas drainage cavity, the top of the compressed gas storage cavity is communicated with the compressed gas guide-in piece and the gas guide piece communicated with the gas drainage cavity, the compressed gas enters the compressed gas storage cavity through the compressed gas guide-in piece, and the compressed gas in the compressed gas storage cavity enters the upper part of the gas drainage cavity through the gas guide piece.

The compressed air guiding part is provided with a diving box body air inlet one-way valve.

The compressed gas storage cavity is provided with a sleeve in a vertical state, and the vertical support column penetrates through the sleeve.

The water-gas separation type diving box body is formed by assembling a compressed gas storage part, more than three floating and sinking parts with the same structure and a fixing seat, wherein the compressed gas storage part is provided with a compressed gas storage cavity, the floating and sinking parts are provided with a gas drainage cavity, the more than three floating and sinking parts surround the compressed gas storage part, and the more than three floating and sinking parts are connected with the compressed gas storage part into a whole through the fixing seat.

The upper telescopic cylinder assembly comprises an upper telescopic cylinder body, an upper supporting cylinder and a floating barrel part, the upper supporting cylinder is positioned above the upper telescopic cylinder body, the lower part of the upper telescopic cylinder body is communicated with the fixed cylinder, and the upper supporting cylinder and the floating barrel part are connected into a whole.

The utility model discloses wind energy pump water equipment on ocean adopts such structure, has increased the lower telescopic cylinder assembly that is located below the sea level, and lower telescopic cylinder assembly passes through the air supporting principle and displaces from top to bottom along vertical support column to the adjustment aqueous vapor disconnect-type caisson body rises and descends, and the fixed cylinder assembly of rethread is carried the sea water to on the sea level. The utility model relates to an efficiency on sea wind energy pumping equipment can improve the sea water and carry to the sea water plane on, because implement at sea, transportation and installation cost are high, and it is significant to improve the efficiency that the sea water carried to the sea water plane on.

Drawings

The marine wind energy water pumping equipment of the present invention will be further described in detail with reference to the accompanying drawings;

fig. 1 is a schematic structural view of the offshore wind energy water pumping device of the present invention;

FIG. 2 is a schematic view of the water-gas separating caisson shown in FIG. 1;

FIG. 3 is a schematic structural view of the wind energy compressed gas preparation unit shown in FIG. 1;

in fig. 1, 2, and 3, 1 is a float part; 2. a platform; 3. a telescopic cylinder water inlet control valve; 4. an upper support cylinder; 5. the float cylinder part enters the water discharge control valve; 6. a water tube assembly; 7. a lower telescopic cylinder body; 8. a vertical support column; 9. a wind energy compressed gas preparation unit; 10. a column; 11. a float bowl part ventilation pipe; 12. a compressed gas introduction member; 13. a limiting member; 14. a lower buoyancy tank; 15. a subsea connection; 16. a subsea foundation; 17. a water-gas separation type diving box body; 18. an upper telescopic cylinder body; 19. a fixed cylinder; 20. a stationary cylinder fastener; 22. an air inlet control valve of the air drainage cavity; 23. a diving box body air inlet and water outlet control valve; 24. a gas guide; 25. an air inlet one-way valve of the diving box body; 26. a compressed gas storage chamber; 27. a sleeve; 28. a gas drainage cavity; 29. a water inlet and outlet of the air drainage cavity; 30. a wind wheel assembly; 31. an air wheel assembly output shaft; 32. rotating the disc; 33. a wind energy inflator; 34. a wind energy inflator fixing seat; 35. a wind energy air duct.

Detailed Description

As shown in fig. 1, 2 and 3, the offshore wind energy water pumping device comprises a seabed foundation 16, a seabed connecting piece 15 and a lower floating box 14, the device comprises more than two vertical supporting columns 8, a fixed cylinder assembly, an upper telescopic cylinder assembly, a lower telescopic cylinder assembly, a platform 2 and a device for preparing compressed gas by wind energy, wherein the platform 2 is arranged at the top end of the more than two vertical supporting columns 8, the lower ends of the more than two vertical supporting columns 8 are fixedly connected with a lower floating box 14, the upper end of a seabed connecting piece 15 is connected with the lower floating box 14, the lower end of the seabed connecting piece 15 is connected with a seabed foundation 16, the fixed cylinder assembly comprises a fixed cylinder 19 fixedly connected to the vertical supporting columns 8 and a water pipe component 6 communicated with the fixed cylinder, the fixed cylinder 19 is fixedly connected to the vertical supporting columns 8 through fixed cylinder fastening pieces 20, the upper telescopic cylinder assembly is located at the upper parts of the fixed cylinder assemblies, the lower telescopic cylinder assembly is located at the lower parts of the fixed cylinder assemblies, and the upper telescopic cylinder assembly and the lower telescopic.

The upper telescopic cylinder assembly comprises an upper telescopic cylinder body 18, an upper supporting cylinder 4 and a buoy part 1, wherein the upper supporting cylinder 4 is positioned above the upper telescopic cylinder body 18, the lower part of the upper telescopic cylinder body 18 is communicated with a fixed cylinder 19, the upper supporting cylinder 4 and the buoy part 1 are connected into a whole, the buoy part 1 is provided with a plurality of hollow buoy parts, seawater for increasing the weight of the buoy part is arranged in a cavity of the buoy part when tide, the upper supporting cylinder 4 is provided with a telescopic cylinder water inlet control valve 3, a flange plate is arranged between the upper telescopic cylinder body 18 and the upper supporting cylinder 4, a vertical supporting column 8 penetrates through the upper supporting cylinder 4, the top of the buoy part 1 is provided with a buoy part vent pipe 11, the bottom of the buoy part 1 is provided with a buoy part water inlet and outlet control valve 5, and seawater is conveyed to a seawater plane when the upper telescopic cylinder assembly tide.

The lower telescopic cylinder assembly comprises a lower telescopic cylinder body 7 and a water-gas separation type diving box body 17 which moves up and down along a vertical supporting column 8, the water-gas separation type diving box body 17 is positioned below the lower telescopic cylinder body 7, the water-gas separation type diving box body 17 is driven by compressed gas to ascend and descend, the upper portion of the lower telescopic cylinder body 7 is communicated with a fixed cylinder 19, a limiting part 13 for supporting the water-gas separation type diving box body 17 is arranged at the lower portion of the vertical supporting column 8, and when the lower telescopic cylinder assembly ascends, seawater is conveyed to the upper portion of a seawater plane through the fixed cylinder assembly. Water-gas separation formula caisson body 17 is including compressed gas storage chamber 26, gas drainage chamber 28, lead gas 24 and compressed gas leading-in 12, compressed gas storage chamber 26 is for being located the enclosure space at water-gas separation formula caisson body 17 middle part, compressed gas stores and contains compressed gas in the chamber 26, it has the sea water to arrange in the chamber 28, compressed gas storage chamber 26's top intercommunication has compressed gas leading-in 12 and leads the gas 24 that lets in gas drainage chamber 28, the compressed gas that the ocean energy preparation compressed gas device provided passes through compressed gas leading-in 12 and gets into compressed gas storage chamber 26, compressed gas storage chamber 26 is provided with the sleeve pipe 27 that is vertical state, vertical support column 8 passes sleeve pipe 27. The compressed gas of the compressed gas storage chamber 26 enters the upper part of the gas drainage chamber 28 through the gas guide 24, the gas guide 24 is provided with a diving box body gas inlet and drainage control valve 23, the top part of the gas drainage chamber 28 is provided with a gas drainage chamber gas inlet control valve 22, the lower part of the gas drainage chamber 28 is provided with a gas drainage chamber water inlet and outlet 29, and the compressed gas leading-in part 12 is provided with a diving box body gas inlet one-way valve 25.

The water-gas separation type diving box body 17 is not limited to the above structure, when the volume is large, in order to facilitate transportation and installation, the water-gas separation type diving box body 17 is formed by assembling a compressed gas storage part, a floating part and a fixing seat of the same structure more than three, the compressed gas storage part is provided with a compressed gas storage cavity, the floating part is provided with a gas drainage cavity, the floating part surrounds the compressed gas storage part more than three, and the floating part of the same structure more than three is connected with the compressed gas storage part into a whole through the fixing seat. The water-gas separation type diving box body 17 can also be made into a structure with a compressed gas storage cavity outside and a gas drainage cavity inside.

The utility model discloses an in the description, it should be understood that the generalized should be done with lower telescoping cylinder body to go up the telescoping cylinder body, goes up the telescoping cylinder body and can constitute by a plurality of flexible telescoping cylinders with lower telescoping cylinder body, and flexible telescoping cylinder can have telescoping cylinder flange dish and telescoping cylinder unit connecting plate, links into an organic whole through the connecting piece, also can weld as an organic whole.

The device for preparing the compressed gas by wind energy comprises a plurality of upright columns 10 which are arranged near the platform 2 and are higher than the sea level, a wind energy compressed gas preparation unit 9 arranged at the top end of each upright column 10 and a compressed gas control part, wherein the compressed gas control part is positioned above the platform 2, and the compressed gas prepared by the wind energy compressed gas preparation unit is introduced into the compressed gas control part. The wind energy compressed gas preparation unit comprises a wind wheel assembly 30, a wind wheel assembly output shaft 31, a rotating disc 32, a wind energy inflator fixing seat 34, a wind energy air guide pipe 35 and a plurality of wind energy inflators 33, the wind wheel assembly adopts mature technology of wind power generation, the wind wheel assembly 30 is provided with the wind wheel assembly output shaft 31, the rotating disc 32 is arranged on the extending end of the wind wheel assembly output shaft 31, the wind energy inflators 33 are fixedly connected on the wind energy inflator fixing seat 34, compressed gas generated by each wind energy inflator 33 passes through the wind energy air guide pipe 35, the central line of the piston rod of each wind energy inflator 33 is parallel to the central line of the wind wheel assembly output shaft 31, the extending end of the piston rod of each wind energy inflator 33 is connected with the rotating disc 32, the end face of the rotating disc 32 is provided with a plurality of alternate protruding areas and recessed areas which are in smooth transition, and when the wind wheel, the extending end of the piston rod of the air pump 33 is always engaged with the end surface of the rotary disk 32, and the center line of the piston rod of each air pump 33 is positioned on a concentric circle with the center line of the rotary disk 32 as the center. Because the position of each wind energy inflator 33 is fixed, the rotating disc 32 rotates, when the top end of the piston rod of each wind energy inflator is at the lowest position in the depressed area of the rotating disc 32, the piston rod of each wind energy inflator extends the longest, and when the top end of the piston rod of each wind energy inflator is at the highest position in the protruding area of the rotating disc 32, the piston rod of each wind energy inflator extends the shortest, and the diameter of the rotating disc can be determined to be larger according to the requirement.

The utility model discloses a such structure compares with prior art, has increased the lower telescopic cylinder assembly that is located below the sea level on tidal energy water pumping device's basis, and lower telescopic cylinder assembly passes through air supporting principle and shifts from top to bottom along vertical support column to adjustment aqueous vapor disconnect-type caisson body rises and descends, and the fixed cylinder assembly of rethread is carried the sea water to on the sea level.

The wind energy is utilized to generate compressed gas, the compressed gas enters a compressed gas storage cavity of the water-gas separation type diving case body through the compressed gas leading-in part, when the water-gas separation type diving case body is positioned at the lowest position, the water-gas separation type diving case body is supported by the limiting part, high-pressure gas of the compressed gas storage cavity enters a gas drainage cavity through the gas guide part, a gas inlet control valve of the gas drainage cavity is in a closed state at the moment, the gas drainage cavity drains outwards through a water inlet and outlet of the gas drainage cavity under the action of pressure, the weight of the water-gas separation type diving case body is reduced, the water-gas separation type diving case body continuously rises under the action of buoyancy, the volume of a lower telescopic cylinder body is gradually reduced, seawater is continuously conveyed to a certain height above a seawater plane through a water pipe assembly under the action of the pressure, and when the water-gas separation type diving case body is positioned at the high position, the gas inlet control valve of the, the pressure intensity in the air drainage cavity is reduced, seawater rushes into the air drainage cavity through the water inlet and outlet of the air drainage cavity, the weight of the water-air separation type diving box body is increased, the water-air separation type diving box body descends along the vertical supporting columns under the action of gravity, the volume of the lower telescopic cylinder body is gradually increased, seawater enters the lower telescopic cylinder body through the lower telescopic cylinder water inlet control valve on the side wall of the lower fixed cylinder, the seawater enters the lower telescopic cylinder body along with the gradual increase of the volume of the lower telescopic cylinder body, and the seawater in the air drainage cavity continuously rushes in, reaches a low position and contacts with the limiting part to complete one cycle. The utility model discloses mainly utilize wind energy to produce compressed gas, lower telescopic cylinder assembly passes through the air supporting principle and displaces from top to bottom along vertical support column, and adjustment aqueous vapor disconnect-type caisson body rises, descends, carries the sea water to the sea water plane on through fixed cylinder assembly when lower telescopic cylinder assembly rises. The water-gas separation type diving box body can be assembled, and the construction, transportation and installation difficulty is reduced.

Claims (8)

1. The utility model provides an on ocean wind energy pumping equipment, it includes the seabed basis, the seabed connecting piece, lower flotation tank, two above vertical support columns, fixed cylinder assembly, go up telescoping cylinder assembly and lower telescoping cylinder assembly, the lower extreme and the lower flotation tank rigid coupling of two above vertical support columns, lower flotation tank is connected to the upper end of seabed connecting piece, the seabed basis is connected to the lower extreme of seabed connecting piece, fixed cylinder assembly includes fixed cylinder that rigid coupling is on vertical support column and the water pipe subassembly with fixed cylinder intercommunication, go up the telescoping cylinder assembly and be located the upper portion of fixed cylinder assembly, lower telescoping cylinder assembly is located the lower part of fixed cylinder assembly, go up telescoping cylinder assembly and lower telescoping cylinder assembly all along vertical support column displacement from top to bottom, go up the telescoping cylinder assembly when falling tide with the sea water transport to on the sea water level, its characterized in that: the top ends of the more than two vertical supporting columns are provided with a platform, a compressed gas control part is arranged above the platform, a plurality of upright columns higher than the sea level are arranged near the platform, the top end of each upright column is provided with a wind energy compressed gas preparation unit, the compressed gas prepared by the wind energy compressed gas preparation unit is introduced into the compressed gas control part, the lower telescopic cylinder assembly comprises a lower telescopic cylinder body and a water-gas separated type diving box body which moves up and down along a vertical supporting column, the water-gas separation type diving box body is positioned below the lower telescopic cylinder body and is driven to ascend and descend by compressed gas prepared by a plurality of wind energy compressed gas preparation units, the upper part of the lower telescopic cylinder body is communicated with the fixed cylinder, the lower part of the vertical supporting column is provided with a limiting piece for supporting the water-gas separated type diving box body, the lower telescopic cylinder assembly conveys the seawater to a position above the seawater level through the fixed cylinder assembly when ascending.

2. The offshore wind energy water pumping apparatus of claim 1, wherein: the wind energy compressed gas preparation unit comprises a wind wheel assembly, a wind wheel assembly output shaft, a rotating disc, a wind energy inflator fixing seat, a wind energy air guide pipe and a plurality of wind energy inflators, the wind wheel component is positioned above the upright post and is provided with a wind wheel component output shaft, a rotating disc is arranged at the extending end of the wind wheel component output shaft, a plurality of wind energy inflators are fixedly connected on a wind energy inflator fixing seat, compressed gas generated by each wind energy inflator is output through a wind energy air duct, the central line of a piston rod of each wind energy inflator is parallel to the central line of the wind wheel component output shaft, the extending end of the piston rod of each wind energy inflator is connected with the rotating disc, and the end surface of the rotating disc is provided with a plurality of alternate protruding areas and recessed areas which are in smooth transition, when the output shaft of the wind wheel component drives the rotating disc to rotate, the extending end of the piston rod of the wind energy inflator is always jointed with the end face of the rotating disc.

3. The offshore wind energy water pumping apparatus of claim 2, wherein: the center line of the piston rod of each wind energy inflator is positioned on a concentric circle which takes the center line of the rotating disc as the center of a circle.

4. An offshore wind energy water pumping apparatus according to claim 1, 2 or 3, characterized in that: the water-gas separation type diving box body comprises a compressed gas storage cavity, a gas drainage cavity, a gas guide piece and a compressed gas guide-in piece, wherein the compressed gas storage cavity is a closed space located in the middle of the water-gas separation type diving box body, compressed gas is contained in the compressed gas storage cavity, seawater is arranged in the gas drainage cavity, the top of the compressed gas storage cavity is communicated with the compressed gas guide-in piece and the gas guide piece communicated with the gas drainage cavity, the compressed gas enters the compressed gas storage cavity through the compressed gas guide-in piece, and the compressed gas in the compressed gas storage cavity enters the upper part of the gas drainage cavity through the gas guide piece.

5. The offshore wind energy water pumping apparatus of claim 4, wherein: the compressed air guiding part is provided with a diving box body air inlet one-way valve.

6. The offshore wind energy water pumping apparatus of claim 5, wherein: the compressed gas storage cavity is provided with a sleeve in a vertical state, and the vertical support column penetrates through the sleeve.

7. The offshore wind energy water pumping apparatus of claim 5, wherein: the water-gas separation type diving box body is formed by assembling a compressed gas storage part, more than three floating and sinking parts with the same structure and a fixing seat, wherein the compressed gas storage part is provided with a compressed gas storage cavity, the floating and sinking parts are provided with a gas drainage cavity, the more than three floating and sinking parts surround the compressed gas storage part, and the more than three floating and sinking parts are connected with the compressed gas storage part into a whole through the fixing seat.

8. The offshore wind energy water pumping apparatus of claim 7, wherein: the upper telescopic cylinder assembly comprises an upper telescopic cylinder body, an upper supporting cylinder and a floating barrel part, the upper supporting cylinder is positioned above the upper telescopic cylinder body, the lower part of the upper telescopic cylinder body is communicated with the fixed cylinder, and the upper supporting cylinder and the floating barrel part are connected into a whole.

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