CN107489591A - Utilize the method for buoyancy output power - Google Patents

Abstract

The invention discloses a kind of method that power is exported using buoyancy, in the airtight chamber that one remains with gas to outer closure and the inside, high level fluid reservoir and low liquid level fluid reservoir are set, connection and the cut-off of the liquid in two fluid reservoirs are controlled using the first gate, buoyancy tank is set in airtight chamber, by controlling liquid into and out of buoyancy tank, make buoyancy tank shuttling movement between two fluid reservoirs, when buoyancy tank floats, the chain in chain chain-wheel mechanism is pulled using buoyancy tank, rotated using chain-driving sprocket wheel, power is exported using the sprocket wheel of rotation.It is an advantage of the invention that produce power using buoyancy, it is not necessary to burning fuel, be advantageous to environmental protection.

Description

Utilize the method for buoyancy output power

Technical field

It the present invention relates to the use of the technology that liquid buoyancy produces power.

Background technology

Existing PTO relies on burning fuel mostly, certain environmental pollution be present.

The content of the invention

It is an object of the invention to provide a kind of method that power is exported using buoyancy, this method is not required to burning fuel, favorably In environmental protection.

What the present invention was realized in：Using the method for buoyancy output power, outer closure and the inside are retained at one There are in the airtight chamber of gas two fluid reservoirs of setting, two fluid reservoirs are respectively high level fluid reservoir and low liquid level fluid reservoir, Liquid level of the liquid level of the liquid of high level fluid reservoir storage higher than the liquid of low liquid level fluid reservoir storage；

In the bottom of two fluid reservoirs, the first gate is set between two fluid reservoirs, when the first gate is opened, two liquid storages The fluid connection of room, when the first closing gate, the liquid cut-off of two fluid reservoirs；

The upper end of two fluid reservoirs is open, and the second gate is provided with the upper end open-mouth of high level fluid reservoir, when the second gate closes Can be by the open closing in the upper end of high level fluid reservoir when closing；

Buoyancy tank is provided with airtight chamber, buoyancy tank shuttling movement between two fluid reservoirs is made with following methods：In the first gate In the state of closing, make the liquid in low liquid level fluid reservoir enter buoyancy tank, buoyancy tank is sunk to the bottom of low liquid level fluid reservoir； The first gate is opened in the state of two closing gates, the buoyancy tank that low liquid level fluid reservoir bottom is sunk in order is moved to by the first gate The bottom of high level fluid reservoir, then recover to close the first gate；In the state of the first closing gate, the liquid in buoyancy tank is made The low liquid level fluid reservoir is flow back into, enters buoyancy tank with the gas in seasonal airtight chamber, in the process that liquid flows out from buoyancy tank In, make buoyancy tank rest on the bottom of high level fluid reservoir；After the liquid outflow in buoyancy tank, buoyancy tank is made in high level liquid storage The buoyancy float downward of indoor liquid is to liquid level；The second gate is opened, takes out and floats from the opening end of high level fluid reservoir Low liquid level fluid reservoir is returned to the buoyancy tank of liquid level, and by buoyancy tank；In the state of the first closing gate, low liquid level is made to store up again Liquid in liquid room enters buoyancy tank, hereafter continuous circulating repetition said process, so that buoyancy tank circulates between two fluid reservoirs Motion；

Chain sprocket mechanism is set in high level fluid reservoir, floats to the mistake of liquid level from the bottom of high level fluid reservoir in buoyancy tank Cheng Zhong, chain is pulled using buoyancy tank, is rotated using chain-driving sprocket wheel, power is exported using the sprocket wheel of rotation.

In one of the embodiments, the method that the described liquid made in low liquid level fluid reservoir enters buoyancy tank is, in institute State and air bleeding valve and liquid feed valve are set on buoyancy tank, the buoyancy tank is put into the liquid in the low liquid level fluid reservoir, opens the row Air valve and liquid feed valve, liquid is set to enter the buoyancy tank, after the buoyancy tank sinks to the bottom of the low liquid level fluid reservoir, closing should Air bleeding valve and liquid feed valve.

In one of the embodiments, described order sinks to the buoyancy tank of low liquid level fluid reservoir bottom by the movement of the first gate Method to the bottom of high level fluid reservoir is the first travel mechanism to be set in the bottom of the low liquid level fluid reservoir, by first The buoyancy tank for sinking to the low liquid level fluid reservoir bottom is accepted by travel mechanism, and drives described float by the first travel mechanism Case moves.

In one of the embodiments, the described liquid made in buoyancy tank flows back into the low liquid level fluid reservoir, with season The method that gas in airtight chamber enters buoyancy tank is two self-sealing pipe joints to be connected on the buoyancy tank, in the height The air inlet pipe and discharging tube that the bottom setting of liquid level fluid reservoir is docked with the buoyancy tank, air inlet pipe and discharging tube dock with buoyancy tank One end be connected with self-sealing pipe joint, the other end of air inlet pipe is communicated to the gassiness portion in the airtight chamber Position, the other end of discharging tube is communicated to the low liquid level fluid reservoir, when the buoyancy tank is moved to the high liquid by the first gate The bottom of position fluid reservoir, and after closing first gate, make the self-sealing pipe joint of air inlet pipe and discharging tube respectively with Two self-sealing pipe joints docking on buoyancy tank, then make the liquid in buoyancy tank flow back into the low liquid level by discharging tube and store up Liquid room, while liquid flows out out of buoyancy tank, the gas in the airtight chamber enters the buoyancy tank by air inlet pipe, works as institute State after the liquid in buoyancy tank flows back to the low liquid level fluid reservoir, by the self-sealing pipe joint of air inlet pipe and discharging tube and buoyancy tank Two self-sealing pipe joints separation.

In one of the embodiments, the described liquid made in buoyancy tank flows back into the low liquid level liquid storage by discharging tube The method of room is to be drawn back the liquid in buoyancy tank to low liquid level fluid reservoir with the infusion pump being connected in discharging tube；Or by institute State buoyancy tank and elevate the liquid level in higher than the low liquid level fluid reservoir, the liquid in the buoyancy tank is flowed under gravity Return the low liquid level fluid reservoir.

In one of the embodiments, it is described to make the self-sealing pipe joint of air inlet pipe and discharging tube and two on buoyancy tank The method of individual self-sealing pipe joint docking and separation is to set pipeline docking mechanism in the bottom of the high level fluid reservoir, Pipeline docking mechanism is connected with the self-sealing pipe joint of the air inlet pipe and the discharging tube, and institute is driven by pipeline docking mechanism The self-sealing pipe joint movement of air inlet pipe and the discharging tube is stated, makes the self-sealing pipe joint of the air inlet pipe and discharging tube Two self-sealing pipe joints with buoyancy tank are docked and separated.

In one of the embodiments, the method for the described bottom for making buoyancy tank rest on high level fluid reservoir is electricity consumption Magnet holds the buoyancy tank.

In one of the embodiments, the opening end from high level fluid reservoir takes out the buoyancy tank for floating to liquid level, And it is that the second travel mechanism and derricking gear are set in the airtight chamber that buoyancy tank is returned into low liquid level fluid reservoir method, Second travel mechanism is connected with derricking gear, and derricking gear is connected with the hanging mechanisms that can lift the buoyancy tank, by the second movement Derricking gear is moved to the top of the high level fluid reservoir by mechanism, is hung the buoyancy tank by hanging mechanisms by derricking gear Rise, then derricking gear is moved to the top of the low liquid level fluid reservoir by the second travel mechanism, put down by derricking gear floating Case, make the buoyancy tank fall in the liquid of the low liquid level fluid reservoir, then make hanging mechanisms depart from the buoyancy tank.

In one of the embodiments, the method that the described sprocket wheel using rotation exports power is, in the chain chain At least one sprocket wheel connection power output shaft in mechanism is taken turns, by sprocket wheel driving power output shaft rotation, power output shaft stretches out Outside to the high level fluid reservoir.

In one of the embodiments, the method using buoyancy tank pulling chain is to set and lead on the chain Draw portion, during the buoyancy tank floats to liquid level from the bottom of the high level fluid reservoir, the buoyancy tank is withstood upwards to be led Draw portion, the chain is pulled by tractive unit.

It is an advantage of the invention that produce power using buoyancy, it is not necessary to burning fuel, be advantageous to environmental protection.

Brief description of the drawings

Fig. 1 is the system structure diagram that the inventive method uses；

Fig. 2 to Fig. 9 the inventive method action process schematic diagram；

Figure 10 is the schematic diagram of another embodiment of chain sprocket mechanism；

Figure 11 is the schematic diagram with guide rail constraint buoyancy tank.

Embodiment

For the ease of understanding the present invention, the present invention is described more fully with reference to the accompanying drawings.Given in accompanying drawing The better embodiment of the present invention.But the present invention can realize in many different forms, however it is not limited to described herein Embodiment.The purpose for providing these embodiments is the more thorough and comprehensive for making to understand the disclosure.

It should be noted that when an element is considered as " connection " another element, it can be directly to separately One element may be simultaneously present centering elements.Term as used herein "left", "right" and similar statement are For illustrative purposes." first " of the present invention, " second " do not represent specific quantity and order, are used only for the area of title Point.

Using the method for buoyancy output power as shown in figure 1, airtight chamber 1 provided with one to outer closure, airtight chamber 1 The inside remain with gas.The gas can be but not limited to air.Two fluid reservoirs of setting in airtight chamber 1, two Fluid reservoir is respectively high level fluid reservoir 2 and low liquid level fluid reservoir 3.The liquid level for the liquid 4 that high level fluid reservoir 2 is deposited is high In the liquid level for the liquid 5 that low liquid level fluid reservoir 3 is deposited.The liquid 4,5 is same liquid, can be but not limited to Water.First gate 6 is set between the bottom of two fluid reservoirs 2,3, when the first gate 6 is opened, the liquid of two fluid reservoirs 2,3 Body 4,5 connects, and when the first gate 6 is closed, the liquid 4,5 of two fluid reservoirs 2,3 separates.The upper end of two fluid reservoirs 2,3 opens Mouthful.The second gate 7 is provided with the upper end open-mouth of high level fluid reservoir 2., can be by high level liquid storage when the second gate 7 is closed The open closing in the upper end of room 2.Buoyancy tank 8 is provided with airtight chamber 1.

The shuttling movement between two fluid reservoirs 2,3 of buoyancy tank 8 is made with following methods：In the state of the closing of the first gate 6, As shown in Fig. 2 buoyancy tank 8 is put into the liquid 5 in low liquid level fluid reservoir 3, liquid 5 is entered buoyancy tank 8, when buoyancy tank 8 sink to it is low Behind the bottom of liquid level fluid reservoir 3, as shown in figure 3, opening the first gate 6 in the state of the closing of the second gate 7, buoyancy tank 8 is made to pass through Cross the bottom that the first gate 6 is moved to high level fluid reservoir 2.Then as shown in fig. 6, in the state of the closing of the first gate 6, order Liquid in buoyancy tank 8 flows back into low liquid level fluid reservoir 3, enters buoyancy tank 8 with the gas in seasonal airtight chamber 1.In liquid from floating During case 8 flows out, buoyancy tank 8 is made to rest on the bottom of high level fluid reservoir 2.After the liquid outflow in buoyancy tank 8, such as Shown in Fig. 7, the buoyancy float downward of liquid 4 of the buoyancy tank 8 in high level fluid reservoir 2 is made to liquid level.Floated in buoyancy tank 8 same When, or after buoyancy tank 8 floats to liquid level, open the second gate 7.Then as shown in Fig. 8 to Fig. 9, from high level fluid reservoir 2 Opening end takes out the buoyancy tank 8 for floating to liquid level, and buoyancy tank 8 is returned into low liquid level fluid reservoir 3.Then the step shown in Fig. 2 is repeated Suddenly, buoyancy tank 8 is placed again into the liquid 5 in low liquid level fluid reservoir 3, in the state of the closing of the first gate 6, makes low liquid again Liquid 5 in the fluid reservoir 3 of position enters buoyancy tank 8.Hereafter continuous circulating repetition said process, make buoyancy tank 8 two fluid reservoirs 2,3 it Between shuttling movement.

As shown in figure 1, the chain sprocket mechanism being made up of chain 9 and sprocket wheel 10 is set in high level fluid reservoir 2.Floating During case 8 floats to liquid level from the bottom of high level fluid reservoir 2, as shown in Figure 6 to 7, chain 9 is pulled using buoyancy tank 8, Rotated using chain 9 with movable sprocket 10, power is exported using the sprocket wheel 10 of rotation.The method that power is exported using sprocket wheel 10, can To be that the rotating shaft 11 extending out to outside high level fluid reservoir 2 is connected on sprocket wheel 10, power output shaft is used as using the rotating shaft 11. Can connect power output shaft respectively on multiple sprocket wheels 10 in chain sprocket mechanism.Power output shaft 11 can both stretch out To outside airtight chamber 1, airtight chamber 1 can also need not be stretched out.

As preferred forms, as shown in figure 1, set air bleeding valve 12 and liquid feed valve 13 on buoyancy tank 8, when buoyancy tank 8 such as When being put into shown in Fig. 2 in the liquid 5 in low liquid level fluid reservoir 3, air bleeding valve 12 and liquid feed valve 13 are opened, liquid 5 is entered buoyancy tank 8, after buoyancy tank 8 sinks to the bottom of low liquid level fluid reservoir 3, turn off air bleeding valve 12 and liquid feed valve 13.Air bleeding valve 12 and liquid feed valve 13 can use existing mechanical touching formula valve, or electric-controlled type valve.If, can be low using mechanical touching formula valve The bottom of liquid level fluid reservoir 3 is provided for touching the projection of valve.It is described after buoyancy tank 8 sinks to the bottom of low liquid level fluid reservoir 3 Projection just touches with air bleeding valve 12 and liquid feed valve 13, so that air bleeding valve 12 and liquid feed valve 13 are opened.When air bleeding valve 12 and enter After liquid valve 13 leaves projection with moving for buoyancy tank 8, air bleeding valve 12 and liquid feed valve 13 in the presence of therein spring from It is dynamic to close.If air bleeding valve 12 and liquid feed valve 13 use electric-controlled type valve, buoyancy tank 8 can be monitored using position sensor Position, after buoyancy tank 8 sinks to the bottom of low liquid level fluid reservoir 3, air bleeding valve 12 and liquid feed valve 13 is controlled to open by electric signal, when After buoyancy tank 8 leaves low liquid level fluid reservoir 3, air bleeding valve 12 and liquid feed valve 13 is controlled to close by electric signal.

As preferred forms, as shown in figure 1, setting the first travel mechanism 14 in the bottom of low liquid level fluid reservoir 3.Such as Shown in Fig. 2 to Fig. 3, the buoyancy tank 8 for sinking to the bottom of low liquid level fluid reservoir 3 is accepted by the first travel mechanism 14, and moved by first Motivation structure 14 drives buoyancy tank 8 to pass through the bottom that the first gate 6 is moved to high level fluid reservoir 2.First travel mechanism 14 can adopt With but be not limited to leading screw and nut mechanism or pinion and rack.

As preferred forms, as shown in figure 1, two self-sealing pipe joints 15,16 are connected on buoyancy tank 8, in height The bottom of liquid level fluid reservoir 2 sets the air inlet pipe 17 docked with buoyancy tank 8 and discharging tube 18.Air inlet pipe 17 and discharging tube 18 with it is floating One end that case 8 docks is connected to self-sealing pipe joint 19,20.The other end of air inlet pipe 17 is communicated in airtight chamber 1 Gassiness position, the other end of discharging tube 18 is communicated to low liquid level fluid reservoir 3.As shown in figure 5, when buoyancy tank 8 is moved to The bottom of high level fluid reservoir 2, and the first gate 6 is in the state of closing, and makes the self-styled of air inlet pipe 17 and discharging tube 18 Formula pipe joint 19,20 is docked with two self-sealing pipe joints 15,16 on buoyancy tank 8 respectively.Then, with being connected on discharging tube Infusion pump 21 in 18 draws back the liquid in buoyancy tank 8 to low liquid level fluid reservoir 3.Or infusion pump 21 can also not had to, but Using the method that buoyancy tank 8 is elevated to the liquid level in higher than low liquid level fluid reservoir 3, the liquid in buoyancy tank 8 is set to make in gravity Low liquid level fluid reservoir 3 is flowed back under.While liquid flows out from buoyancy tank 8, the gas in airtight chamber 1 can pass through air inlet pipe 17 Naturally buoyancy tank 8 is entered.After the liquid outflow in buoyancy tank 8, the self-sealing pipeline of air inlet pipe 17 and discharging tube 18 is connect First 19,20 separate with two self-sealing pipe joints 15,16 on buoyancy tank 8.All self-sealing pipe joints 15,16,19,20 are certainly Dynamic closing.The self-sealing pipe joint can use commercially available finished product, or use and the air bleeding valve 12 and liquid feed valve on buoyancy tank 8 13 mutually isostructural valves, the closing and unlatching of control joint are come in a manner of Mechanical course or electric signal control.

As preferred forms, as shown in figure 1, setting pipeline docking mechanism 22, pipe in the bottom of high level fluid reservoir 2 Road docking mechanism 22 is connected with the self-sealing pipe joint 19,20 of air inlet pipe 17 and discharging tube 18.As shown in Fig. 4 to Fig. 5, by pipe Road docking mechanism 22 drives the self-sealing pipe joint 19,20 of air inlet pipe 17 and discharging tube 18 to move, and makes air inlet pipe 17 and discharge opeing The self-sealing pipe joint 19,20 of pipe 18 is docked with two self-sealing pipe joints 15,16 of buoyancy tank 8.Liquid in buoyancy tank 8 After outflow, drive the self-sealing pipe joint 19,20 of air inlet pipe 17 and discharging tube 18 to move by pipeline docking mechanism 22, make The self-sealing pipe joint 19,20 of air inlet pipe 17 and discharging tube 18 separates with two self-sealing pipe joints 15,16 of buoyancy tank 8. Pipeline docking mechanism 22 can use but be not limited to leading screw and nut mechanism or pinion and rack.

As preferred forms, buoyancy tank locking mechanism can be set in the bottom of high level fluid reservoir 2.When buoyancy tank 8 is with entering When tracheae 17 and discharging tube 18 dock, buoyancy tank 8 is fixed by buoyancy tank locking mechanism, finished when the liquid in buoyancy tank 8 flows out, And after buoyancy tank 8 separates with air inlet pipe 17 and discharging tube 18, buoyancy tank 8 is discharged by buoyancy tank locking mechanism.Buoyancy tank locking mechanism can be with Using electromagnet.If buoyancy tank 8 does not have magnetic conductivity, can on buoyancy tank 8 magnetic conductor such as fixed iron piece.

As preferred forms, as shown in figure 1, setting the second travel mechanism 23 and derricking gear in airtight chamber 1 24, the second travel mechanism 23 is connected with derricking gear 24.The lifting rope of derricking gear 24 is connected with the hanging mechanisms that can lift buoyancy tank 8 25.As shown in figure 8, when buoyancy tank 8 is floated on liquid level, derricking gear 24 is moved to high level storage by the second travel mechanism 23 The top of liquid room 2, and being sling buoyancy tank 8 by lifting rope and hanging mechanisms 25 by derricking gear 24, then as shown in figure 9, by Derricking gear 24 is moved to the top of low liquid level fluid reservoir 3 by the second travel mechanism 23, then as shown in Fig. 2 by derricking gear 24 put down lifting rope, make buoyancy tank 8 fall in the liquid 5 of low liquid level fluid reservoir 3, then make hanging mechanisms 25 depart from buoyancy tank 8.Second Travel mechanism 23 can use but be not limited to leading screw and nut mechanism or pinion and rack.Derricking gear 24 can use but not It is limited to hoist engine.Second travel mechanism 23 can also be combined into a kind of combined member with derricking gear 24, hanging mechanisms 25, such as Manipulator.Hanging mechanisms 25 can use but be not limited to electromagnet.

As preferred forms, as shown in figure 1, setting tractive unit 26 on chain 9.As shown in Figure 6 to 7, floating During case 8 floats to liquid level from the bottom of high level fluid reservoir 2, buoyancy tank 8 withstands tractive unit 26 upwards, then by tractive unit 26 Pull chain 9.In order to allow tractive unit 26 to return to the bottom of high level fluid reservoir 2, as shown in figure 1, in the end of chain 9 It is connected with counterweight 27.After buoyancy tank 8 leaves high level fluid reservoir 2 as shown in Figure 9, chain 9 is pulled by counterweight 27, makes tractive unit 26 return to the bottom of high level fluid reservoir 2.

Chain sprocket mechanism can also use the structure of the chain circulation walking shown in Figure 10, be connected on chain 9 multiple Tractive unit 26.When one of tractive unit 26 is by buoyancy tank top to top, another tractive unit 26 is located just at high level liquid storage The bottom of room 2, to meet the arrival of buoyancy tank to be next time ready.

In order to allow power output shaft 11 only to be rotated towards single direction, can be installed between power output shaft 11 and sprocket wheel 10 single To bearing.Only when the buoyancy tank 8 that chain 9 is floated upwards pulls, sprocket wheel 10 just drives power output shaft 11 to rotate, and works as chain 9 when moving in the opposite direction, and sprocket wheel 10 dallies on power output shaft 11.

Power output shaft 11 can be connected directly between on sprocket wheel 10, can also be connected between power output shaft 11 and sprocket wheel 10 Gear shift is connect, sprocket wheel 10 drives power output shaft 11 to rotate by gear shift.

In order to ensure that buoyancy tank can be accurate to up to precalculated position in lifting process, buoyancy tank can be constrained using guide rail 28 Movement locus.Figure 11 is a kind of embodiment that buoyancy tank coordinates with guide rail 28.In terms of the overlook direction of buoyancy tank 8, four of buoyancy tank 8 Angle carries recess, and four guide rails 28 in four recesses, play a part of constraining the movement locus of buoyancy tank 8 respectively.Seen in Figure 11 To track 28 be track cross section.

Embodiment described above only expresses the several embodiments of the present invention, and its description is more specific and detailed, but simultaneously Can not therefore it be construed as limiting the scope of the patent.For the person of ordinary skill of the art, this is not being departed from On the premise of inventive concept, various modifications and improvements can be made, these belong to protection scope of the present invention.It is of the invention special The protection domain of profit should be determined by the appended claims.

Claims (10)

1. using the method for buoyancy output power, it is characterized in that：

Outer closure and the inside are remained with and two fluid reservoirs set in the airtight chamber of gas at one, two fluid reservoir difference For high level fluid reservoir and low liquid level fluid reservoir, the liquid level of the liquid of high level fluid reservoir storage is higher than low liquid level fluid reservoir The liquid level of the liquid of storage；

In the bottom of two fluid reservoirs, the first gate is set between two fluid reservoirs, when the first gate is opened, two liquid storages The fluid connection of room, when the first closing gate, the liquid cut-off of two fluid reservoirs；

The upper end of two fluid reservoirs is open, and the second gate is provided with the upper end open-mouth of high level fluid reservoir, when the second gate closes Can be by the open closing in the upper end of high level fluid reservoir when closing；

Buoyancy tank is provided with airtight chamber, buoyancy tank shuttling movement between two fluid reservoirs is made with following methods：In the first gate In the state of closing, make the liquid in low liquid level fluid reservoir enter buoyancy tank, buoyancy tank is sunk to the bottom of low liquid level fluid reservoir； The first gate is opened in the state of two closing gates, the buoyancy tank that low liquid level fluid reservoir bottom is sunk in order is moved to by the first gate The bottom of high level fluid reservoir, then recover to close the first gate；In the state of the first closing gate, the liquid in buoyancy tank is made The low liquid level fluid reservoir is flow back into, enters buoyancy tank with the gas in seasonal airtight chamber, in the process that liquid flows out from buoyancy tank In, make buoyancy tank rest on the bottom of high level fluid reservoir；After the liquid outflow in buoyancy tank, buoyancy tank is made in high level liquid storage The buoyancy float downward of indoor liquid is to liquid level；The second gate is opened, takes out and floats from the opening end of high level fluid reservoir Low liquid level fluid reservoir is returned to the buoyancy tank of liquid level, and by buoyancy tank；In the state of the first closing gate, low liquid level is made to store up again Liquid in liquid room enters buoyancy tank, hereafter continuous circulating repetition said process, so that buoyancy tank circulates between two fluid reservoirs Motion；

Chain sprocket mechanism is set in high level fluid reservoir, floats to the mistake of liquid level from the bottom of high level fluid reservoir in buoyancy tank Cheng Zhong, chain is pulled using buoyancy tank, is rotated using chain-driving sprocket wheel, power is exported using the sprocket wheel of rotation.

2. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：Described makes in low liquid level fluid reservoir Liquid to enter the method for buoyancy tank be that air bleeding valve and liquid feed valve are set on the buoyancy tank, the buoyancy tank is put into the low liquid In liquid in the fluid reservoir of position, open the air bleeding valve and liquid feed valve, liquid is entered the buoyancy tank, sink to when the buoyancy tank described in Behind the bottom of low liquid level fluid reservoir, the air bleeding valve and liquid feed valve are closed.

3. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：Low liquid level liquid storage is sunk in described order The method for the bottom that the buoyancy tank of room bottom is moved to high level fluid reservoir by the first gate is, in the low liquid level fluid reservoir Bottom sets the first travel mechanism, and the buoyancy tank for sinking to the low liquid level fluid reservoir bottom is accepted by the first travel mechanism, And the buoyancy tank is driven to move by the first travel mechanism.

4. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：The described liquid flow made in buoyancy tank The low liquid level fluid reservoir is back to, the method that buoyancy tank is entered with the gas in seasonal airtight chamber is connected on the buoyancy tank Two self-sealing pipe joints, the air inlet pipe docked with the buoyancy tank and discharge opeing are set in the bottom of the high level fluid reservoir One end docked with buoyancy tank of pipe, air inlet pipe and discharging tube is connected with self-sealing pipe joint, and the other end of air inlet pipe is communicated to Gassiness position in the airtight chamber, the other end of discharging tube are communicated to the low liquid level fluid reservoir, when described floating Case is moved to the bottom of the high level fluid reservoir by the first gate, and after closing first gate, make air inlet pipe and The self-sealing pipe joint of discharging tube is docked with two self-sealing pipe joints on buoyancy tank respectively, then makes the liquid in buoyancy tank The low liquid level fluid reservoir is flow back into by discharging tube, while liquid flows out out of buoyancy tank, the gas in the airtight chamber Body enters the buoyancy tank by air inlet pipe, after the liquid in the buoyancy tank flows back to the low liquid level fluid reservoir, by air inlet pipe and The self-sealing pipe joint of discharging tube separates with two self-sealing pipe joints on buoyancy tank.

5. as claimed in claim 4 using the method for buoyancy output power, it is characterized in that：The described liquid made in buoyancy tank leads to Crossing discharging tube and flowing back into the method for the low liquid level fluid reservoir is, with the infusion pump being connected in discharging tube by the liquid in buoyancy tank Draw back to low liquid level fluid reservoir；Or the buoyancy tank is elevated into the liquid level in higher than the low liquid level fluid reservoir, make institute State the liquid in buoyancy tank and flow back to the low liquid level fluid reservoir under gravity.

6. as claimed in claim 4 using the method for buoyancy output power, it is characterized in that：Described makes air inlet pipe and discharging tube Self-sealing pipe joint with two self-sealing pipe joints docking on buoyancy tank and the method that separates stored up in the high level The bottom of liquid room sets pipeline docking mechanism, and the self-sealing pipeline of pipeline docking mechanism and the air inlet pipe and the discharging tube connects Head connection, the self-sealing pipe joint for driving the air inlet pipe and the discharging tube by pipeline docking mechanism are moved, make it is described enter The self-sealing pipe joint of tracheae and discharging tube is docked and separated with two self-sealing pipe joints of buoyancy tank.

7. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：Described makes buoyancy tank rest on high liquid The method of the bottom of position fluid reservoir is to hold the buoyancy tank with electromagnet.

8. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：It is described from high level fluid reservoir Opening end, which takes out, floats to the buoyancy tank of liquid level, and buoyancy tank is returned into low liquid level fluid reservoir method is, in the airtight chamber Second travel mechanism and derricking gear are set, and the second travel mechanism is connected with derricking gear, and derricking gear, which is connected with, can lift institute The hanging mechanisms of buoyancy tank are stated, derricking gear are moved to the top of the high level fluid reservoir by the second travel mechanism, by lifting by crane The buoyancy tank is sling by hanging mechanisms by mechanism, and derricking gear then is moved into the low liquid level by the second travel mechanism stores up The top of liquid room, buoyancy tank is put down by derricking gear, make the buoyancy tank fall in the liquid of the low liquid level fluid reservoir, then order is hung Connection mechanism departs from the buoyancy tank.

9. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：Described is defeated using the sprocket wheel rotated Going out the method for power is, at least one sprocket wheel connects power output shaft in the chain sprocket mechanism, is moved by chain wheel drive Power output shaft is rotated, and power output shaft is extend out to outside the high level fluid reservoir.

10. as claimed in claim 1 using the method for buoyancy output power, it is characterized in that：Described utilizes buoyancy tank pulling chain The method of bar is to set tractive unit on the chain, and liquid is floated to from the bottom of the high level fluid reservoir in the buoyancy tank During face, the buoyancy tank withstands tractive unit upwards, and the chain is pulled by tractive unit.