CN219492456U - Isobaric liquid circulation buoyancy unit - Google Patents

Abstract

The utility model relates to the technical field of units, in particular to an isobaric liquid circulation buoyancy unit which comprises a shell and a crankcase, wherein four hexagonal rotors are arranged in the shell in a way of facing rotation, a trapezoid buoyancy tank is arranged between the hexagonal rotors in a way of rotating, a conical exhaust valve is uniformly and fixedly arranged on the bottom surface of the shell, and a plurality of compression cylinders are uniformly and fixedly arranged on the top surface of the crankcase; the crankshaft is rotatably arranged in the crankcase, pistons are slidably arranged in the compression cylinders, connecting rods are rotatably connected to the bottom surfaces of the pistons, the other ends of the connecting rods are rotatably connected with the crankshaft, one end of the crankshaft penetrates through the shell and the crankcase and is fixedly connected with the hexagonal rotor, the top surface of each compression cylinder is fixedly connected with an air duct, an air inlet check valve is fixedly connected to the joint of each compression cylinder and each air duct, and the end parts of the air ducts are fixedly connected with a plurality of air distribution pipes; the utility model can drive the crankshaft to rotate by utilizing the compressed air circulation, and stably convert kinetic energy into electric energy.

Description

Isobaric liquid circulation buoyancy unit

Technical Field

The utility model relates to the technical field of units, in particular to an isobaric liquid circulation buoyancy unit.

Background

Common thermal power plants, hydroelectric power plants, wind power plants and the like still cannot meet the requirement of solving the increasing electricity consumption, and people start developing more new units for generating power by utilizing various power to compensate and solve the problem of shortage of the electricity.

The Chinese patent with the application number of CN201420517045.1 discloses a water buoyancy generating set, which comprises a steel bracket, a top gear, a top platform, a base, a bottom gear, an inflator, a generator and a gear transmission box, is environment-friendly, pollution-free and good in safe operation performance, however, the generating set has low buoyancy utilization efficiency and more energy loss, and therefore, an isobaric liquid circulation buoyancy generating set is needed.

Disclosure of Invention

Aiming at the defects in the prior art, the utility model provides an isobaric liquid circulation buoyancy unit which is used for solving the problems of low buoyancy utilization efficiency and more energy loss of the conventional unit.

In order to solve the technical problems, the utility model adopts the following technical scheme:

the isobaric liquid circulation buoyancy unit comprises a shell and a crankcase, wherein four hexagonal rotors are rotatably arranged in the shell, a trapezoid buoyancy tank is rotatably arranged between the hexagonal rotors, a conical exhaust valve is uniformly and fixedly arranged on the bottom surface of the shell, and a plurality of compression cylinders are uniformly and fixedly arranged on the top surface of the crankcase;

the inside bent axle that rotates of crankcase installs, the inside equal slidable mounting of compression cylinder has the piston, the equal rotation in piston bottom surface is connected with the connecting rod, the connecting rod other end rotates with the bent axle and is connected, bent axle one end passes shell and crankcase and with hexagonal rotor fixed connection, compression cylinder top surface fixedly connected with air duct, compression cylinder and air duct junction fixedly connected with check valve that admits air, air duct tip fixedly connected with a plurality of reposition of redundant personnel trachea.

Like this, when the equipment is required to be operated, let in compressed gas from the check valve that admits air, compressed gas gets into the air duct, get into inside the shell through the reposition of redundant personnel trachea, begin to drive trapezoidal buoyancy tank come-up, the buoyancy that trapezoidal buoyancy tank produced drives hexagonal rotor and bent axle rotation, the bent axle begins to drive the connecting rod and removes, the connecting rod drives the piston and begins to slide along compression cylinder, the air of the inside cavity of compression cylinder gets into the air duct, when the inside atmospheric pressure of shell is too high, the air can follow the toper discharge valve and discharge, the compression air of circulation can drive the bent axle and rotate from this, the external generator of bent axle just can be steadily with kinetic energy conversion electric energy.

Further, the volume ratio of the trapezoid buoyancy tank to the compression cylinder is equal to or greater than that of the compression cylinder, so that buoyancy generated by the trapezoid buoyancy tank is ensured to be enough to drive the compression cylinder to operate.

Further, the inside fixed mounting of shell has the gas baffle, gas baffle forms the liquid guiding gutter with the shell, is convenient for guide liquid from this and flows in the shell inside, drives trapezoidal flotation tank and produces buoyancy.

Furthermore, the first base is fixedly arranged on the bottom surface of the shell, and the second base is fixedly arranged on the bottom surface of the crankcase, so that the influence of external factors on equipment can be reduced, and a stable environment is provided for the operation of the equipment.

Drawings

FIG. 1 is a schematic perspective view of an embodiment of an isobaric liquid circulation buoyancy unit according to the present utility model;

FIG. 2 is a schematic perspective view (another orientation) of an embodiment of an isobaric hydronic buoyancy unit according to the present utility model;

FIG. 3 is a schematic diagram of an embodiment of an isobaric liquid circulation buoyancy module according to the present utility model;

FIG. 4 is a schematic diagram of a right-hand view of an embodiment of an isobaric hydronic buoyancy unit according to the present utility model;

reference numerals in the drawings of the specification:

the device comprises a shell 1, a hexagonal rotor 101, a trapezoid buoyancy tank 102, a conical exhaust valve 103, a split-flow air pipe 104, a crankcase 2, a compression cylinder 201, a crankshaft 202, a piston 203, a connecting rod 204, an air duct 205, an air inlet one-way valve 206, an air baffle 301, a liquid diversion trench 302, a first stand 401 and a second stand 402.

Detailed Description

In order that those skilled in the art will better understand the present utility model, the following technical scheme of the present utility model will be further described with reference to the accompanying drawings and examples.

Wherein the drawings are for illustrative purposes only and are shown in schematic, non-physical, and not intended to be limiting of the present patent; for the purpose of better illustrating embodiments of the utility model, certain elements of the drawings may be omitted, enlarged or reduced and do not represent the size of the actual product; it will be appreciated by those skilled in the art that certain well-known structures in the drawings and descriptions thereof may be omitted.

Examples:

as shown in fig. 1-4, the isobaric liquid circulation buoyancy unit comprises a shell 1 and a crank case 2, wherein four hexagonal rotors 101 are rotatably arranged in the shell 1, a trapezoid buoyancy tank 102 is rotatably arranged between the hexagonal rotors 101, a conical exhaust valve 103 is uniformly and fixedly arranged on the bottom surface of the shell 1, and a plurality of compression cylinders 201 are uniformly and fixedly arranged on the top surface of the crank case 2;

the crankshaft 202 is rotatably arranged in the crankcase 2, the pistons 203 are slidably arranged in the compression cylinders 201, connecting rods 204 are rotatably connected to the bottom surfaces of the pistons 203, the other ends of the connecting rods 204 are rotatably connected with the crankshaft 202, one ends of the crankshaft 202 penetrate through the shell 1 and the crankcase 2 and are fixedly connected with the hexagonal rotor 101, air guide pipes 205 are fixedly connected to the top surfaces of the compression cylinders 201, air inlet check valves 206 are fixedly connected to the junctions of the compression cylinders 201 and the air guide pipes 205, and a plurality of air guide pipes 104 are fixedly connected to the end parts of the air guide pipes 205.

Thus, when the equipment is required to operate, compressed gas is introduced from the air inlet one-way valve 206, the compressed gas enters the air guide pipe 205 and enters the inside of the shell 1 through the air distribution pipe 104, the trapezoidal buoyancy tank 102 starts to be driven to float upwards, the buoyancy generated by the trapezoidal buoyancy tank 102 drives the hexagonal rotor 101 and the crankshaft 202 to rotate, the crankshaft 202 starts to drive the connecting rod 204 to move, the connecting rod 204 drives the piston 203 to start to slide along the compression cylinder 201, air in the cavity inside the compression cylinder 201 enters the air guide pipe 205, when the air pressure inside the shell 1 is too high, the air can be discharged from the conical exhaust valve 103, the circulated compressed air can drive the crankshaft 202 to rotate, and the crankshaft 202 is externally connected with the generator to stably convert kinetic energy into electric energy.

The volume ratio of the trapezoid buoyancy tank 102 to the compression cylinder 201 is 1.1:1 to 1.2:1, thereby ensuring that the buoyancy generated by the trapezoid buoyancy tank 102 is sufficient to drive the compression cylinder 201 to operate.

The air baffle 301 is fixedly arranged in the shell 1, and the air baffle 301 and the shell 1 form a liquid diversion trench 302, so that liquid can be conveniently guided to flow in the shell 1, and the trapezoid buoyancy tank 102 is driven to generate buoyancy.

The bottom surface of the shell 1 is fixedly provided with a first stand 401, and the bottom surface of the crankcase 2 is fixedly provided with a second stand 402, so that the influence of external factors on equipment can be reduced, and a stable environment is provided for the operation of the equipment.

The foregoing is merely exemplary of the present utility model, and the specific structures and features well known in the art are not described in any way herein, so that those skilled in the art will be able to ascertain all prior art in the field, and will not be able to ascertain any prior art to which this utility model pertains, without the general knowledge of the skilled person in the field, before the application date or the priority date, to practice the present utility model, with the ability of these skilled persons to perfect and practice this utility model, with the help of the teachings of this application, with some typical known structures or methods not being the obstacle to the practice of this application by those skilled in the art. It should be noted that modifications and improvements can be made by those skilled in the art without departing from the structure of the present utility model, and these should also be considered as the scope of the present utility model, which does not affect the effect of the implementation of the present utility model and the utility of the patent.

Claims (4)

1. An isobaric liquid circulation buoyancy unit is characterized in that: the device comprises a shell (1) and a crankcase (2), wherein four hexagonal rotors (101) are rotatably arranged in the shell (1), a trapezoid buoyancy tank (102) is rotatably arranged between the hexagonal rotors (101), a conical exhaust valve (103) is uniformly and fixedly arranged on the bottom surface of the shell (1), and a plurality of compression cylinders (201) are uniformly and fixedly arranged on the top surface of the crankcase (2);

crankshaft (202) are installed to inside rotation of crankcase (2), inside equal slidable mounting of compression cylinder (201) has piston (203), piston (203) bottom surface all rotates and is connected with connecting rod (204), connecting rod (204) other end and crankshaft (202) rotate and are connected, shell (1) and crankcase (2) are passed to crankshaft (202) one end and with hexagonal rotor (101) fixed connection, compression cylinder (201) top surface fixedly connected with air duct (205), compression cylinder (201) and air duct (205) junction fixedly connected with check valve (206) that admits air, air duct (205) tip fixedly connected with a plurality of reposition of redundant personnel air ducts (104).

2. An isobaric liquid circulation buoyancy unit according to claim 1, characterized in that: the volume ratio of the trapezoid buoyancy tank (102) to the compression cylinder (201) is 1.1:1 to 1.2:1.

3. An isobaric liquid circulation buoyancy unit according to claim 2, characterized in that: the air baffle plate (301) is fixedly arranged in the shell (1), and the air baffle plate (301) and the shell (1) form a liquid diversion trench (302).

4. An isobaric liquid circulation buoyancy unit according to claim 3, characterized in that: the bottom surface of the shell (1) is fixedly provided with a first stand (401), and the bottom surface of the crankcase (2) is fixedly provided with a second stand (402).