CN201671897U - Piston-type deep-sea water pressure compensation energy accumulator - Google Patents

Abstract

The utility model relates to a deep-sea water pressure compensation energy accumulator, which is mainly used for energy accumulation of hydraulic mechanical equipment for deep-sea oil drilling and production. A cylindrical upper shell and a cylindrical lower shell are respectively fixed at both ends of a cylindrical connection separator in a threaded mode. A piston rod is arranged in a center hole of the connection separator. Both ends of the piston rod are respectively connected with an upper piston and a lower piston. The upper piston, the lower piston and the connection separator divide the deep-sea water pressure compensation energy accumulator into four cavities, namely a gas cavity, a fluid cavity, a sea cavity and a vacuum cavity. The utility model skillfully utilizes hydrostatic pressure of sea water to make the energy accumulator not influenced by static pressure when the energy accumulator works in deep sea and improves discharge of effective fluid volume of the energy accumulator so as to utilize a small number of energy accumulators to provide enough energy for work of underwater hydraulic equipment and machine tools for deep-sea operation, reduce weight and effective occupied space of the underwater equipment and reduce manufacturing cost.

Description

Piston-type deep sea water pressure compensation energy accumulator

Technical field

The utility model relates to deep-sea oil drilling and production technology field, and particularly the hydraulic machinery equipment of deep ocean work is a kind of novel deep sea water pressure compensation energy accumulator.

Background technique

Along with the continuous increase of the mankind to oil demand, the petroleum resources of land reduces rapidly, the emphasis of oil-gas exploration and development turns to the ocean by land, and constantly march to the deep-sea, this just has higher requirement to the accumulator of deep-sea drilling hydraulic equipment and facility use, though and conventional accumulator can satisfy the requirement of deep-sea work, efficient is but very low.

At present, conventional accumulator is a certain amount of gas of preliminary filling at first on the water, produce certain preliminary filling pressure, when accumulator is put into underwater operation, the hydrostatic pressure of seawater makes that the pressure of preliminary filling gas increases greatly in the accumulator, so the discharging of pressure liquid must overcome under water hydrostatic pressure during accumulator work.Along with the increase of the depth of water, hydrostatic pressure is increasing, and the required resistance potential energy that overcomes of pressure liquid discharging is big more, and the effective liquid measure that causes accumulator to be discharged is fewer and feweri, and working efficiency is just low more.The company of the manufacturer of preventer under water Cameroon that the U.S. is famous, rule of thumb formula calculates: under 3000 meters depth of waters, effective liquid measure that conventional accumulator is discharged only has an appointment 10%.In order to satisfy the required energy of preventer work under water, need to install a large amount of accumulators.Along with accumulator quantity increases, improved the device fabrication cost greatly, increased the weight of blowout preventer set simultaneously and effectively taken up room under water.

Summary of the invention

The purpose of this utility model is: a kind of piston-type deep sea water pressure compensation energy accumulator is provided, eliminate the seawater hydrostatic pressing to discharging the influence of liquid measure, improve the discharge of the effective liquid measure of accumulator, utilize a spot of accumulator to provide sufficient energy, and reduce manufacture cost for the underwater hydraulic equipment and the facility work of deep ocean work.

The technical solution adopted in the utility model: piston-type deep sea water pressure compensation energy accumulator, mainly be made up of air cavity end cap, gas charging valve, upper piston, upper shell, connection dividing plate, sea water filter device, hydraulic valve, piston rod, lower piston, vacuum chamber end cap, sealing plug, it is characterized in that: the two ends at cylindrical connection dividing plate are fixed with cylindrical shape upper shell and lower shell body respectively.

The other end screw thread at upper shell is fixed with cylinder bodily form air cavity end cap, and the air cavity end cap has the air-filled pore with the upper shell internal communication, is fixed with unidirectional gas charging valve in the air-filled pore outer end.

The other end screw thread at lower shell body is fixed with cylinder bodily form vacuum chamber end cap, and the vacuum chamber end cap has the through hole with the lower shell body internal communication, is fixed with the sealing plug in the through hole outer end.

Connecting dividing plate has center hole, in the center hole that connects dividing plate piston rod is arranged, and piston rod is slidingly matched with being connected the dividing plate center hole, is fixed with upper piston in the upper end of piston rod, and upper piston and upper enclosure inner wall are slidingly matched; Lower end at piston rod is fixed with lower piston, and lower piston and lower shell body inwall are slidingly matched; When piston rod reciprocatingly slided in the center hole of connection dividing plate, upper piston reciprocatingly slided in upper shell; Lower piston reciprocatingly slides in lower shell body.

Form air cavity in upper shell and between upper piston and upper end cap, upper piston forms sap cavity with being connected between the dividing plate; In lower shell body and connecting formation seawater chamber between dividing plate and the lower piston, form vacuum chamber between lower piston and the lower end cap.

Connecting dividing plate has axial bore and radial hole, and axial bore is communicated with formation pressure liquid path with radial hole, and the other end of axial bore is communicated with sap cavity, and the radial hole the other end is fixed with hydraulic valve.By pressure liquid path, can in sap cavity, inject highly pressurised liquid or highly pressurised liquid flows out in sap cavity.

Connecting dividing plate has axial bore and radial hole, and axial bore is communicated with formation seawater path with radial hole, and the other end of axial bore is communicated with the seawater chamber, and the radial hole the other end is fixed with the sea water filter device.By sea water filter device and seawater path, can make seawater turnover seawater chamber.

In order to improve sealability, between upper end cap and upper shell, seal ring is arranged; Between lower end cap and lower shell body, seal ring is arranged; Between upper piston and upper shell, seal ring is arranged; Between lower piston and lower shell body, seal ring is arranged; Between upper end outer wall that connects dividing plate and upper enclosure inner wall, seal ring is arranged; Between lower end outer wall that connects dividing plate and lower shell body inwall, seal ring is arranged; On the hole wall of connection dividing plate center, seal ring is arranged.

Upper piston and lower piston are equipped with the seal ring that the twice cross section is a T shape, lower piston is free to slide in lower shell body and keeps good sealing, at connection dividing plate endoporus cross section, three roads being housed is the seal ring of T shape, piston rod is free to slide in connecting dividing plate and keeps good sealing, its T section seal ring, frictional force is little, not yielding and distortion, sealing is better, characteristics such as durable.

According to the structural principle of the utility model piston-type deep sea water pressure compensation energy accumulator, can derive three kinds multi-form: differential type deep sea water pressure compensation energy accumulator, spring deep sea water pressure compensation energy accumulator and differential spring formula deep sea water pressure compensation energy accumulator.

The differential type deep sea water pressure compensation energy accumulator: the internal diameter ratio of upper shell and lower shell body is between 1: 1.5～3.The diameter ratio of upper piston and lower piston is between 1: 1.5～3, under the constant situation of seawater pressure, increased the area of contact of seawater and lower piston, thereby increased the pulling force of connecting rod, make the pressure in the sap cavity increase the discharge that can improve the effective liquid measure of accumulator.

Spring deep sea water pressure compensation energy accumulator: in air cavity, add spring, promptly on the upper-end surface of upper piston, be fixed with pressure spring, can also be fixed with an auxiliary piston in the upper end of spring.Utilizing after the length of spring compressed can stored energy, and the spring deep sea water pressure compensation energy accumulator can utilize the static pressure of seawater, has changed pneumatic accumulator simultaneously and has been affected by the external environment, and effective liquid measure of discharge is improved.What described spring can adopt is inside and outside double-deck pressure spring, improves the ability of spring stored energy.

Differential spring formula deep sea water pressure compensation energy accumulator: be that the differential type deep sea water pressure compensation energy accumulator combines with the structural feature of spring deep sea water pressure compensation energy accumulator, promptly the internal diameter ratio at upper shell and lower shell body is between 1: 1.5～3, the diameter ratio of upper piston and lower piston is between 1: 1.5～3, and on the upper-end surface of upper piston, be fixed with pressure spring, utilize differential type deep sea water pressure compensation energy accumulator and spring deep sea water pressure compensation energy accumulator advantage separately, effective liquid measure that accumulator is discharged further improves.

The using method of piston-type deep sea water pressure compensation energy accumulator is divided into assembling, preacceleration inflation, accumulation of energy and four steps of release.

Assembling: the suction line of oil hydraulic pump waterborne connects fuel tank waterborne, and outlet line connects one-way valve waterborne; The pipeline of the hydraulic valve of 2～10 piston-type deep sea water pressure compensation energy accumulators is composed in parallel accumulator group under water, be connected accumulator group waterborne on the pipeline between one-way valve and the one-way valve waterborne under water.Accumulator group pipeline is connected under water one-way valve to the pipeline between the hydraulic inlet of selector valve under water.The hydraulic pressure outlet line of selector valve connects the hydraulic pressure recovery valve, and hydraulic pressure recovery valve pipeline connects fuel tank waterborne.The work import of selector valve is connected underwater installation with exit from do, and underwater installation comprises the hydraulic jack of hydraulic blow out preventer etc.

Preacceleration inflation: before piston-type deep sea water pressure compensation energy accumulator is put into the seabed, open gas charging valve, plug, sea water filter device and hydraulic valve, charge into preliminary filling gas by the air-filled pore in the air cavity end cap to air cavity, promoting upper piston moves down, thereby the gas that moves down in the extruding vacuum chamber by connecting rod drive lower piston all flows out by through hole, screws plug.Continuation charges into gas and reaches 7-14MPa (use under the different depth of waters, best preacceleration inflation is different in air cavity.) preacceleration inflation, close gas charging valve and hydraulic valve then, finish preacceleration inflation.

Accumulation of energy: the accumulator group is put into the seabed under water, and oil hydraulic pump waterborne is by pipeline pressurising accumulation of energy in accumulator group waterborne, and the centre has one-way valve waterborne to prevent liquid return; Simultaneously to accumulator group pressurising accumulation of energy under water.Accumulator waterborne and one-way valve is under water arranged between the accumulator group under water prevents liquid return.Piston-type deep sea water pressure compensation energy accumulator is in the seabed, because the hydrostatic pressure of seawater self, seawater enters in the seawater chamber by the seawater path; In pressurising accumulation of energy process, pressure liquid path is to sap cavity charged pressure liquid, and overcome hydrostatic pressure and preacceleration inflation and try hard to recommend moving upper piston and move up, the preliminary filling gas in the compression air cavity reaches the work rated pressure of accumulator, drive on the lower piston by connecting rod simultaneously and move, the seawater chamber diminishes, and vacuum chamber forms and slowly becomes big, and promptly the pressure of sap cavity reaches 21-70Mpa (different working condition, select different rated working pressures for use) rated working pressure, finish punching press accumulation of energy process.

Discharge: when underwater operation equipment needs deep sea water pressure compensation energy accumulator that energy is provided, the commutation of control oil channel selector valve, pressure liquid by in the working equipment oil circuit under the water inlet of pressure liquid path, makes underwater operation equipment carry out work by sap cavity.The low pressure fluid that underwater operation equipment is discharged is recovered to fuel tank waterborne by the hydraulic pressure recovery valve.

Best preacceleration inflation is different under the different depth of water situations, can both do preacceleration inflation as long as say the pressure of the work of being lower than in principle; Rated working pressure also is the same, under different operating modes, select the accumulator of different operating pressure, for example: the rated working pressure at dark marine site of 500m and the accumulator selected in the dark marine site of 3000m is different, with the underwater operation equipment of selecting relation is arranged also in addition.Those skilled in the art can understand.

The beneficial effects of the utility model: the utility model piston-type deep sea water pressure compensation energy accumulator, to go up lower piston by connecting rod connects, the ingenious hydrostatic pressure of utilizing seawater self, be not subjected to the influence of sea water static pressure power when making the working of accumulator at the deep-sea, with working on the water surface is the same, improve the discharge of the effective liquid measure of accumulator, utilize a spot of accumulator to provide sufficient energy for the underwater hydraulic equipment and the facility work of deep ocean work, reduce the weight of underwater installation and effectively take up room the reduction manufacture cost.

Description of drawings

Fig. 1 a is a piston-type deep sea water pressure compensation energy accumulator structural profile schematic representation, is the preacceleration inflation view.

Fig. 1 b is a piston-type deep sea water pressure compensation energy accumulator structural profile schematic representation, is the energy accumulating state schematic representation.

Fig. 1 c is a piston-type deep sea water pressure compensation energy accumulator structural profile schematic representation, is the releasing state schematic representation.

Group of accumulator under water that Fig. 2 is made up of a plurality of piston-type deep sea water pressure compensation energy accumulators and GCU, control apparatus and underwater operation equipment connection diagram under water.

Fig. 3 is a differential type deep sea water pressure compensation energy accumulator structural representation.

Fig. 4 is a spring deep sea water pressure compensation energy accumulator structural representation.

Fig. 5 is a differential spring formula deep sea water pressure compensation energy accumulator structural representation.

Among the figure: 1. air-filled pore, 2. air cavity, 3. sap cavity, 4. pressure liquid path, 5. seawater path, 6. seawater chamber, 7. vacuum chamber, 8. through hole, 9. sealing plug, 10. vacuum chamber end cap, 11. lower pistons, 12. piston rods, 13. lower shell body, 14. connect dividing plate, 15. hydraulic valves, 16. the sea water filter device, 17. upper shells, 18. upper pistons, 19. the air cavity end cap, 20. gas charging valves, 21. oil hydraulic pumps, 22. one-way valve waterborne, 23. accumulator groups waterborne, 24. one-way valves under water, 25. accumulator group under water, 26. selector valves, 27. underwater operation equipment, 28. the hydraulic pressure recovery valve, 29. fuel tanks, 30. springs

Embodiment

Embodiment 1: with a kind of volume is that the piston-type deep sea water pressure compensation energy accumulator of 52L, working pressure 35MPa is an example, and the utility model is described in further detail.

Consult Fig. 1 a.The utility model deep sea water pressure compensation energy accumulator mainly is made up of air cavity end cap 19, gas charging valve 20, upper piston 18, upper shell 17, connection dividing plate 14, sea water filter device 16, hydraulic valve 15, piston rod 12, lower piston 11, vacuum chamber end cap 10, sealing plug 9.

Be fixed with cylindrical shape upper shell 17 and lower shell body 13 respectively at the two ends of cylindrical connection dividing plate 14.305 millimeters of the internal diameters of upper shell 17 and lower shell body 13,1200 millimeters of length, 50 millimeters of wall thickness;

The other end screw thread at upper shell 17 is fixed with an air cavity end cap 19, and air cavity end cap 19 is the cylinder bodily form, and air cavity end cap 19 has an air-filled pore 1 with upper shell 17 internal communication, is fixed with a unidirectional gas charging valve 20 in air-filled pore 1 outer end.

The other end screw thread at lower shell body 13 is fixed with a vacuum chamber end cap 10, and vacuum chamber end cap 10 is the cylinder bodily form, and vacuum chamber end cap 10 has a through hole 8 with lower shell body 13 internal communication, is fixed with a sealing plug 9 at through hole 8 outer end screw threads.

Connecting dividing plate 14, an internal diameter is arranged is 50 millimeters center hole, it is 50 millimeters piston rod 12 that a diameter is arranged in connecting the center hole of dividing plate 14, be fixed with a upper piston 18 in the upper end of piston rod 12,305 millimeters of upper piston 18 diameters, upper piston 18 is slidingly matched with upper shell 17 inwalls; Be fixed with lower piston 11 in the lower end of piston rod 12,305 millimeters of lower piston 11 diameters, lower piston 11 is slidingly matched with lower shell body 13 inwalls.Upper piston 18 upper-end surfaces are 1200 millimeters to the length of lower piston 11 lower end surfaces, and the extreme length that piston rod 12 slides in connecting dividing plate 14 center holes is 1100 millimeters.

In upper shell 17 and between upper piston 18 and upper end cap 19, form air cavity 2, upper piston 18 be connected formation sap cavity 3 between the dividing plate 14; In lower shell body 13 and connecting formation seawater chamber 6 between dividing plate 14 and the lower piston 11, form vacuum chamber 7 between lower piston 11 and the lower end cap 10.

A side that connects dividing plate 14 has an axial bore and a radial hole, and axial bore is communicated with formation pressure liquid path 4 with radial hole, and the other end of axial bore is communicated with sap cavity 3, and the other end of radial hole is fixed with a hydraulic valve 15.

Connecting dividing plate 14 has an axial bore and a radial hole, and axial bore is communicated with formation seawater path 5 with radial hole, and the other end of axial bore is communicated with seawater chamber 6, and the radial hole the other end is fixed with a sea water filter device 16.Sea water filter device 16 prevents that the foreign material in the seawater from entering in the accumulator.

Between upper shell 17, seal ring is arranged at upper end cap 19; Between lower shell body 13, seal ring is arranged at lower end cap 10; It is the seal ring of T shape that the twice cross section is arranged on upper piston 18; It is the seal ring of T shape that seal ring twice cross section is arranged on lower piston 11; Between upper shell 17 inwalls, seal ring is arranged at the upper end outer wall that connects dividing plate 14; Between lower shell body 13 inwalls, seal ring is arranged at the lower end outer wall that connects dividing plate 14; On connection dividing plate 14 center hole walls cross section, three roads being arranged is the seal ring of T shape.

The using method of piston-type deep sea water pressure compensation energy accumulator is divided into assembling, preacceleration inflation, accumulation of energy and four steps of release.

Assembling: consult Fig. 2.The suction line of oil hydraulic pump 21 waterborne connects fuel tank 29 waterborne, and outlet line connects one-way valve 22 waterborne, is connected accumulator group 23 waterborne on the pipeline between one-way valve 24 and the one-way valve 22 waterborne under water.The pipeline of the hydraulic valve 15 of three piston-type deep sea water pressure compensation energy accumulators is composed in parallel accumulator group 25 under water, and accumulator group 25 pipelines are connected under water one-way valve 24 to the pipeline between the hydraulic inlet of selector valve 26 under water.The hydraulic pressure outlet line of selector valve 26 connects hydraulic pressure recovery valve 28, and hydraulic pressure recovery valve 28 pipelines connect fuel tank 29 waterborne.The work import of selector valve 26 is connected underwater installation 27 with exit from do, underwater installation 27 is as hydraulic jack.

Preacceleration inflation: consult Fig. 1 a.Before piston-type deep sea water pressure compensation energy accumulator is put into the seabed, open gas charging valve 20, plug 9, sea water filter device 16 and hydraulic valve 15, charge into preliminary filling gas by the air-filled pore in the air cavity end cap 1 to air cavity 2, promoting upper piston moves for 18 times, thereby the gases that move down in the extruding vacuum chamber 7 by connecting rod 12 drive lower pistons 11 all flow out by through hole, screw plug 9.Continuation charges into gas and reaches the 10MPa preacceleration inflation in air cavity 3, close gas charging valve 20 and hydraulic valve 15 then, finishes preacceleration inflation.

Accumulation of energy: consult Fig. 1 b.Accumulator group 25 is put into the seabed under water, and oil hydraulic pump 21 waterborne is by pipeline pressurising accumulation of energy in accumulator group 23 waterborne, and the centre has one-way valve 22 waterborne to prevent liquid return; Simultaneously to accumulator group 25 pressurising accumulation of energys under water.Accumulator 23 waterborne and one-way valve 24 is under water arranged between the accumulator group 25 under water prevents liquid return.Piston-type deep sea water pressure compensation energy accumulator is in the seabed, because the hydrostatic pressure of seawater self, seawater enters in the seawater chamber 6 by seawater path 5; In pressurising accumulation of energy process, pressure liquid path 4 is to sap cavity 17 charged pressure liquid, and overcome hydrostatic pressure and preacceleration inflation and try hard to recommend moving upper piston 18 and move up, compress the preliminary filling gas in the air cavity, reach the work rated pressure of accumulator, drive on the lower pistons 11 by connecting rod 12 simultaneously and move, the seawater chamber diminishes, vacuum chamber 7 forms and slowly becomes big, and promptly the pressure of sap cavity 17 reaches the 25Mpa rated working pressure, finishes punching press accumulation of energy process.

Discharge: consult Fig. 1 c.When underwater operation equipment 27 needs deep sea water pressure compensation energy accumulator that energy is provided, 26 commutations of control oil channel selector valve, pressure liquid by in working equipment 27 oil circuits under 4 water inlets of pressure liquid path, makes underwater operation equipment 27 carry out work by sap cavity 17.The low pressure fluid that underwater operation equipment 27 is discharged is recovered to fuel tank 29 waterborne by hydraulic pressure recovery valve 28.

Consult table 1.Seabed at depth of water 3000m, effective liquid measure that single conventional accumulator is discharged has only about 10% of total amount, satisfy the 3000m work liquid measure of blowout preventer set under water, need to install conventional accumulator up to 184 52L, taken a large amount of expensive real estate of blowout preventer set, significantly increase simultaneously the weight of blowout preventer set, thereby make cost of transportation increase, transfer the increasing in seabed, the simple amount of money that calculates one group of so required accumulator of preventer has improved the cost of complete equipment greatly just up to 3,680,000.

Deep-water pressure compensation energy accumulator, effective liquid measure of discharging under 3000m deep water are 3.16 times that conventional accumulator is discharged effective liquid measure.Satisfy the 3000m work liquid measure of blowout preventer set under water, only need to install the deep sea water pressure compensation energy accumulator of 59 52L, save a large amount of expensive real estate of blowout preventer set, significantly reduce simultaneously the weight of blowout preventer set, thereby make cost of transportation reduce, the difficulty of transferring the seabed reduces, and the amount of money of one group of so required accumulator of preventer has only 1,180,000, can save cost up to 2,500,000 once the such equipment of cover.

Table 1: piston-type deep sea water pressure compensation energy accumulator and the contrast of conventional accumulator

Embodiment 2: consult Fig. 3.Embodiment 2 is substantially the same manner as Example 1, and difference is: the internal diameter ratio of upper shell 17 and lower shell body 13 is 1: 2.Upper piston 18 is 1: 2 with the diameter ratio of lower piston 11.Connect the connecting thread corresponding change simultaneously at dividing plate 14 two ends, can connect upper shell 17 and lower shell body 13.

Claims (5)

1. piston-type deep sea water pressure compensation energy accumulator, mainly form, it is characterized in that: at the two ends of cylindrical connection dividing plate (14) difference screw thread stationary cylinder shape upper shell (17) and lower shell body (13) by air cavity end cap (19), gas charging valve (20), upper piston (18), upper shell (17), connection dividing plate (14), sea water filter device (16), hydraulic valve (15), piston rod (12), lower piston (11), vacuum chamber end cap (10), sealing plug (9);

The other end screw thread at upper shell (17) is fixed with cylinder bodily form air cavity end cap (19), and air cavity end cap (19) has the air-filled pore (1) with upper shell (17) internal communication, is fixed with unidirectional gas charging valve (20) in air-filled pore (1) outer end;

The other end screw thread at lower shell body (13) is fixed with cylinder bodily form vacuum chamber end cap (10), and vacuum chamber end cap (10) has the through hole (8) with lower shell body (13) internal communication, is fixed with sealing plug (9) in through hole (8) outer end;

Connect dividing plate (14) center hole is arranged, in the center hole that connects dividing plate (14), piston rod (12) is arranged, piston rod (12) is slidingly matched with being connected dividing plate (14) center hole, is fixed with upper piston (18) in the upper end of piston rod (12), and upper piston (18) is slidingly matched with upper shell (17) inwall; Be fixed with lower piston (11) in the lower end of piston rod (12), lower piston (11) is slidingly matched with lower shell body (13) inwall;

Form air cavity (2) in upper shell (17) and between upper piston (18) and upper end cap (19), upper piston (18) forms sap cavity (3) with being connected between the dividing plate (14); In lower shell body (13) and connecting formation seawater chamber (6) between dividing plate (14) and the lower piston (11), form vacuum chamber (7) between lower piston (11) and the lower end cap (10);

Connecting dividing plate (14) has axial bore and radial hole, and axial bore is communicated with formation pressure liquid path (4) with radial hole, and the other end of axial bore is communicated with sap cavity (3), and the radial hole the other end is fixed with hydraulic valve (15);

Connecting dividing plate (14) has axial bore and radial hole, and axial bore is communicated with formation seawater path (5) with radial hole, and the other end of axial bore is communicated with seawater chamber (6), and the radial hole the other end is fixed with sea water filter device (16).

2. piston-type deep sea water pressure compensation energy accumulator according to claim 1 is characterized in that: the internal diameter ratio of upper shell (17) and lower shell body (13) is between 1: 1.5～3; The diameter ratio of upper piston (18) and lower piston (11) is between 1: 1.5～3.

3. piston-type deep sea water pressure compensation energy accumulator according to claim 1 is characterized in that: be fixed with pressure spring (30) on the upper-end surface of upper piston (18), what spring (30) adopted is inside and outside double-deck pressure spring.

4. piston-type deep sea water pressure compensation energy accumulator according to claim 3 is characterized in that: the internal diameter ratio at upper shell (17) and lower shell body (13) is between 1: 1.5～3, and the diameter ratio of upper piston (18) and lower piston (11) is between 1: 1.5～3.

5. according to claim 1,2,3 or 4 described piston-type deep sea water pressure compensation energy accumulators, it is characterized in that: between upper end cap (19) and upper shell (17), seal ring is arranged; Between lower end cap (10) and lower shell body (13), seal ring is arranged; Between upper piston (18) and upper shell (17), seal ring is arranged; Between lower piston (11) and lower shell body (13), seal ring is arranged; Between upper end outer wall that connects dividing plate (14) and upper shell (17) inwall, seal ring is arranged; Between lower end outer wall that connects dividing plate (14) and lower shell body (13) inwall, seal ring is arranged; On the hole wall of connection dividing plate (14) center, seal ring is arranged.

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