CN114017247B - A floating device for new energy buoyancy power generation - Google Patents

Abstract

The invention discloses a new energy buoyancy power generation floating device which comprises a cylindrical hollow shell, a forward conical protruding structure arranged at the top end of the cylindrical hollow shell and an inverse conical protruding structure arranged at the bottom end of the cylindrical hollow shell. According to the invention, the volume of the liquid which can enter the device is changed through the driving motor, so that the buoyancy of the device in the liquid is changed, when the buoyancy is required to be provided, the oxygen generator is utilized to generate gas which can be positioned in the device, in other words, the buoyancy is further provided, in the aspect of buoyancy provision, the device can not only change the volume of the liquid in the device, but also generate gas with the mass of oxygen and the like which is smaller than that of the liquid, thereby accelerating the generation of the buoyancy, and the buoyancy is also enhanced, so that the upward moving speed of the device is accelerated under the action of the buoyancy, thereby driving the connecting rod to move upwards, generating a power generation effect with stronger effect, and the device has outstanding substantive characteristics and remarkable progress.

Description

Floating device for new energy buoyancy power generation

Technical Field

The invention relates to the technical field of new energy power generation, in particular to a floating device for new energy buoyancy power generation.

Background

At present, existing new energy sources comprise various types, wherein ocean tidal power generation is utilized to have a certain scale, buoyancy power generation is included in the existing tidal power generation, a general mode is that a floating device suspended below the ocean liquid level is driven to move up and down by tide rising and falling, then a connecting rod and a gear are driven, and finally a generator is driven to rotate to work, but the tide rising and falling is slower when the ocean is generated, and buoyancy provided by the buoyancy device is smaller when the buoyancy device floats up and down, so that the power generation efficiency is very low.

Disclosure of Invention

The invention aims to provide a new energy buoyancy power generation floating device, which aims to solve the problems in the background technology.

In order to achieve the above purpose, the present invention provides the following technical solutions: the utility model provides a new forms of energy buoyancy power generation is with floating device, includes the hollow shell of cylindricality, set up the positive toper protruding structure on the hollow shell top of cylindricality and set up the back taper protruding structure in the hollow shell bottom of cylindricality, the inside of the hollow shell of cylindricality is equipped with a main part movable space, the inside of the protruding structure of back taper is equipped with the back taper space of its below space of intercommunication and main part movable space bottom, a driving motor is installed on the inside top of the hollow shell of cylindricality, and the tip of the protruding structure of positive toper is equipped with the body of rod mounting groove, and driving motor's motor main shaft runs through the inner structure of the hollow shell of cylindricality, and the axis body extends to the inside of main part movable space, and the main gear is installed to the bottom of motor main shaft, the hollow shell is equipped with an inboard bellied spacing groove respectively in the both sides that are located the main gear symmetry, and a gear mounting groove is all laid to the transverse position of every spacing groove, and a rotatable pinion is put to the inside card respectively, and the center of pinion is equipped with the main screw hole, and the inside of main screw hole is equipped with a main screw thread through main thread structure screw thread one can reciprocating motion, a bottom mounting plate of two main screw rods, and the protruding structure of piston is equipped with the inside oxygen wire system and the inside oxygen wire hole of the hollow shell and the oxygen system is all connected with the inside oxygen wire of the protruding structure.

Further, the main thread structure comprises an internal thread structure arranged in the main threaded hole and an external thread structure arranged on the main threaded rod body.

Further, waterproof sealing strips are respectively arranged at the end parts of the main wire guide holes of the cylindrical hollow shell and the inverted cone-shaped protruding structures.

Further, the tooth structures of the main gear and the auxiliary gear are meshed with each other at the contact position.

Further, a sealing ring is installed on the side face of the piston plate.

Further, the waterproof sealing strip comprises a straight-face shell for the waterproof sealing strip, an inclined-face shell for the waterproof sealing strip, a straight-shaped hole for the waterproof sealing strip, an inclined hole for the waterproof sealing strip, a sealing ring for the waterproof sealing strip, a first through hole for the waterproof sealing strip and a second through hole for the waterproof sealing strip.

Further, the bottom of straight face shell for waterproof sealing strip is equipped with the inclined plane shell for waterproof sealing strip of integral type, straight face shell for waterproof sealing strip and the inside of inclined plane shell for waterproof sealing strip are equipped with straight hole for waterproof sealing strip and waterproof sealing strip for the intersection intercommunication, and the top in straight hole for waterproof sealing strip communicates external space, and the sealing washer for waterproof sealing strip of sealed external wire body is installed to the tip, and the side of straight face shell for waterproof sealing strip and inclined plane shell for waterproof sealing strip is equipped with waterproof sealing strip for first through-hole and waterproof sealing strip second through-hole respectively.

Further, the first through hole for the waterproof sealing strip and the second through hole for the waterproof sealing strip are respectively communicated with the main wire guide hole positioned in the cylindrical hollow shell and the inverted cone-shaped protruding structure, and the communicating part is subjected to sealing treatment.

Further, the straight-face shell for the waterproof sealing strip and the inclined-face shell for the waterproof sealing strip are respectively and fixedly arranged on the side faces of the cylindrical hollow shell and the inverted cone-shaped protruding structure.

Compared with the prior art, the invention has the beneficial effects that: according to the invention, the volume of the liquid which can enter the device is changed through the driving motor, so that the buoyancy of the device in the liquid is changed, when the buoyancy is required to be provided, the oxygen generator is utilized to generate gas which can be positioned in the device, in other words, the buoyancy is further provided, in the aspect of buoyancy provision, the device can not only change the volume of the liquid in the device, but also generate gas with the mass of oxygen and the like which is smaller than that of the liquid, thereby accelerating the generation of the buoyancy, and the buoyancy is also enhanced, so that the upward moving speed of the device is accelerated under the action of the buoyancy, thereby driving the connecting rod to move upwards, generating a power generation effect with stronger effect, and the device has outstanding substantive characteristics and remarkable progress.

Drawings

FIG. 1 is a schematic diagram of a full section of a floating device for new energy buoyancy power generation;

FIG. 2 is a schematic diagram of a front view of a floating device for buoyancy power generation using new energy sources according to the present invention;

FIG. 3 is a schematic diagram of a waterproof sealing strip in a new energy buoyancy power generation floating device;

In the figure: 1, cylindrical hollow shell, 2, positive conical bulge structure, 3, reverse conical bulge structure, 5, rod body mounting groove, 6, limit groove, 7, gear mounting groove, 8, main part movable space, 9, reverse conical space, 11, waterproof sealing strip, 111, straight-face shell for waterproof sealing strip, 112, inclined-face shell for waterproof sealing strip, 113, straight-shape hole for waterproof sealing strip, 114, inclined hole for waterproof sealing strip, 115, sealing ring for waterproof sealing strip, 116, first through hole for waterproof sealing strip, 117, second through hole for waterproof sealing strip, 12, driving motor, 13, main wire hole, 14, motor main shaft, 15, main gear, 16, piston plate, 17, main threaded rod, 18, auxiliary gear, 19, main threaded structure, 20, electrode oxygen generating head, 21, main threaded hole.

Detailed Description

The following description of the embodiments of the present invention will be made clearly and completely with reference to the accompanying drawings, in which it is apparent that the embodiments described are only some embodiments of the present invention, but not all embodiments. All other embodiments, which can be made by those skilled in the art based on the embodiments of the invention without making any inventive effort, are intended to be within the scope of the invention.

Referring to fig. 1-2, an embodiment of the present invention is provided: comprises a cylindrical hollow shell 1, a forward conical bulge structure 2 arranged at the top end of the cylindrical hollow shell 1 and an inverse conical bulge structure 3 arranged at the bottom end of the cylindrical hollow shell 1, wherein a main component movable space 8 is arranged in the cylindrical hollow shell 1, an inverse conical space 9 which is used for communicating the lower space of the reverse conical bulge structure 3 with the bottom of the main component movable space 8 is arranged in the reverse conical bulge structure 3, a driving motor 12 is arranged at the top end of the interior of the cylindrical hollow shell 1, a rod body mounting groove 5 is arranged at the end of the forward conical bulge structure 2, a motor main shaft 14 of the driving motor 12 penetrates through the interior structure of the cylindrical hollow shell 1, a shaft body extends to the interior of the main component movable space 8, a main gear 15 is arranged at the bottom end of the motor main shaft 14, the cylindrical hollow shell 1 is provided with inwards protruding limit grooves 6 respectively on two symmetrical sides of the main gear 15, a gear mounting groove 7 is arranged at the transverse position of each limit groove 6, a rotatable pinion 18 is respectively clamped in the two gear mounting grooves 7, a main threaded hole 21 is arranged in the center of the pinion 18, the inside of the main threaded hole 21 is in threaded engagement with a main threaded rod 17 capable of conducting reciprocating motion through a main threaded structure 19, piston plates 16 are fixed at the bottom ends of the two main threaded rods 17, an electrode oxygen generating head 20 is respectively arranged on two opposite sides of the inverted conical protruding structure 3, and main wire holes 13 for communicating the side surfaces of the cylindrical hollow shell 1 and the driving motor 12 and the electrode oxygen generating head 20 are respectively arranged in the cylindrical hollow shell 1 and the inverted conical protruding structure 3.

The main thread structure 19 includes an internal thread structure provided inside the main thread hole 21 and an external thread structure provided on the body of the main thread rod 17.

The tooth structures of the main gear 15 and the auxiliary gear 18 are meshed with each other at the contact position.

A sealing ring is mounted on the side of the piston plate 16.

Referring to fig. 3, the cylindrical hollow shell 1 and the inverted cone-shaped protruding structure 3 are respectively provided with a waterproof sealing strip 11 at the end of the main wire guide 13; the waterproof sealing strip 11 comprises a straight surface shell 111 for the waterproof sealing strip, a bevel shell 112 for the waterproof sealing strip, a straight hole 113 for the waterproof sealing strip, an inclined hole 114 for the waterproof sealing strip, a sealing ring 115 for the waterproof sealing strip, a first through hole 116 for the waterproof sealing strip and a second through hole 117 for the waterproof sealing strip, wherein the bottom end of the straight surface shell 111 for the waterproof sealing strip is provided with the integrated bevel shell 112 for the waterproof sealing strip, the straight surface shell 111 for the waterproof sealing strip and the inclined hole 114 for the waterproof sealing strip, which are communicated at the intersection, are arranged in the straight surface shell 111 for the waterproof sealing strip and the inclined shell 112 for the waterproof sealing strip, the top end of the straight hole 113 for the waterproof sealing strip is communicated with the external space, the sealing ring 115 for the waterproof sealing strip for sealing the external conducting wire body is arranged at the end part, and the side surfaces of the straight surface shell 111 for the waterproof sealing strip and the inclined shell 112 for the waterproof sealing strip are respectively provided with the first through hole 116 for the waterproof sealing strip and the second through hole 117 for the waterproof sealing strip; the first through hole 116 for the waterproof sealing strip and the second through hole 117 for the waterproof sealing strip are respectively communicated with the main wire guide hole 13 positioned in the cylindrical hollow shell 1 and the inverted cone-shaped bulge structure 3, and the communicated parts are subjected to sealing treatment; the straight-face shell 111 for the waterproof sealing strip and the inclined-face shell 112 for the waterproof sealing strip are respectively and fixedly arranged on the side faces of the cylindrical hollow shell 1 and the inverted cone-shaped protruding structure 3.

The specific use mode is as follows: in the operation of the invention, firstly, a wire for providing power is arranged on the surface of a movable rod in a buoyancy power generation device, then, the power output end of the wire is respectively arranged in the power input end of a driving motor 12 and the power input end of an electrode oxygen generating head 20, finally, the bottom end of the movable rod in the buoyancy power generation device is arranged in a rod body mounting groove 5, the device is immersed in liquid, during operation, a driving motor 12 is controlled to drive a pinion gear 18 to rotate, under the action of a main thread structure 19, a piston plate 16 generates a leftward movement trend, at the moment, the liquid enters the inside of a movable space 8 of a main part, at the moment, the buoyancy of the device is smaller than the gravity of the device, the device drives the movable rod to move downwards under the action of the gravity, when the device moves to the limit part of the movable rod, the driving motor 12 is controlled to reversely rotate, so that the entered liquid is discharged to the outside of the movable space 8 of the main part, at the moment, the electrode oxygen generating head 20 is opened, part of the air is reserved in the interior of a reverse conical space 9, the part of the air generates upward buoyancy, the device is further driven to further drive the device to move upwards, the device is driven to rotate, and the power generator is driven to rotate upwards, and the power generator is rotated to generate electricity, and the power is turned upwards, and the power generator is rotated and the power generator is turned upwards and moved upwards.

It will be evident to those skilled in the art that the invention is not limited to the details of the foregoing illustrative embodiments, and that the present invention may be embodied in other specific forms without departing from the spirit or essential characteristics thereof. The present embodiments are, therefore, to be considered in all respects as illustrative and not restrictive, the scope of the invention being indicated by the appended claims rather than by the foregoing description, and all changes which come within the meaning and range of equivalency of the claims are therefore intended to be embraced therein. Any reference sign in a claim should not be construed as limiting the claim concerned.

Claims (9)

1. A floating device for buoyancy power generation of new energy, comprising a cylindrical hollow shell (1), a positive conical protrusion structure (2) arranged at the top end of the cylindrical hollow shell (1) and an inverted conical protrusion structure (3) arranged at the bottom end of the cylindrical hollow shell (1), wherein a main component activity space (8) is arranged inside the cylindrical hollow shell (1), and the main component activity space (8) is arranged inside the inverted conical protrusion structure (3), characterized in that: an inverted conical space (9) is arranged inside the inverted conical protrusion structure (3) to connect the space below it and the bottom of the main component activity space (8), a driving motor (12) is installed at the top end of the cylindrical hollow shell (1), a rod body installation groove (5) is arranged at the end of the positive conical protrusion structure (2), a motor main shaft (14) of the driving motor (12) passes through the internal structure of the cylindrical hollow shell (1), and the shaft body extends to the inside of the main component activity space (8), and a main gear is installed at the bottom end of the motor main shaft (14) (15), the cylindrical hollow housing (1) is provided with a limiting groove (6) protruding inward on both sides symmetrically located on the main gear (15), a gear placement groove (7) is placed in the lateral part of each limiting groove (6), a rotatable sub-gear (18) is respectively clamped inside the two gear placement grooves (7), a main threaded hole (21) is provided at the center of the sub-gear (18), the inside of the main threaded hole (21) is threadedly engaged with a main threaded rod (17) that can reciprocate through a main threaded structure (19), a piston plate (16) is fixed at the bottom end of the two main threaded rods (17), an electrode oxygen generator (20) is respectively installed on the opposite sides of the inverted cone convex structure (3), and the inside of the cylindrical hollow housing (1) and the inverted cone convex structure (3) are both provided with a main wire hole (13) connecting the side thereof with the drive motor (12) and the electrode oxygen generator (20). 2. A floating device for renewable energy buoyancy power generation according to claim 1, characterized in that: the main thread structure (19) includes an internal thread structure arranged inside the main thread hole (21) and an external thread structure arranged on the rod body of the main thread rod (17). 3. A floating device for renewable energy buoyancy power generation according to claim 1, characterized in that: the cylindrical hollow shell (1) and the inverted cone-shaped protruding structure (3) are respectively installed with waterproof sealing strips (11) at the ends of the main guide hole (13). 4. A floating device for renewable energy buoyancy power generation according to claim 1, characterized in that the tooth structures of the main gear (15) and the auxiliary gear (18) mesh with each other at the contact portion. 5. A floating device for renewable energy buoyancy power generation according to claim 1, characterized in that a sealing ring is installed on the side of the piston plate (16). 6. A floating device for new energy buoyancy power generation according to claim 3, characterized in that: the waterproof sealing strip (11) includes a straight shell (111) for the waterproof sealing strip, an inclined shell (112) for the waterproof sealing strip, a straight hole (113) for the waterproof sealing strip, an oblique hole (114) for the waterproof sealing strip, a sealing ring (115) for the waterproof sealing strip, a first through hole (116) for the waterproof sealing strip and a second through hole (117) for the waterproof sealing strip. 7. A floating device for new energy buoyancy power generation according to claim 6, characterized in that: the bottom end of the straight shell (111) for waterproof sealing strip is provided with an integrated inclined shell (112) for waterproof sealing strip, and the straight shell (111) for waterproof sealing strip and the inclined shell (112) for waterproof sealing strip are provided with a straight hole (113) for waterproof sealing strip and an inclined hole (114) for waterproof sealing strip connected at the intersection, the top of the straight hole (113) for waterproof sealing strip is connected to the external space, and a sealing ring (115) for waterproof sealing strip is installed at the end to seal the external conductor body, and the sides of the straight shell (111) for waterproof sealing strip and the inclined shell (112) for waterproof sealing strip are respectively provided with a first through hole (116) for waterproof sealing strip and a second through hole (117) for waterproof sealing strip. 8. A floating device for new energy buoyancy power generation according to claim 7, characterized in that: the first through hole (116) for waterproof sealing strip and the second through hole (117) for waterproof sealing strip are respectively connected to the main wire hole (13) located inside the cylindrical hollow shell (1) and the inverted cone-shaped protruding structure (3), and the connecting parts are sealed. 9. A floating device for renewable energy buoyancy power generation according to claim 7, characterized in that the straight-surface shell (111) for waterproof sealing strip and the inclined-surface shell (112) for waterproof sealing strip are respectively fixedly mounted on the sides of the cylindrical hollow shell (1) and the inverted cone-shaped protruding structure (3).