CN112696327A

CN112696327A - High-efficiency kinetic energy conversion equipment and method

Info

Publication number: CN112696327A
Application number: CN202011622040.1A
Authority: CN
Inventors: 郭统霄
Original assignee: Individual
Current assignee: Individual
Priority date: 2020-12-31
Filing date: 2020-12-31
Publication date: 2021-04-23

Abstract

The invention relates to the field of machinery, in particular to high-efficiency kinetic energy conversion equipment and method. The power part drives the gears to rotate, and further drives the first power wheel (5) to be meshed with the second power wheel (6) to rotate reversely; the first power wheel (5) is meshed with the second power wheel (6) and rotates reversely to further drive the second hinged connecting rod (9) and the first hinged connecting rod (15) to move relatively, the second lever (10) and the first lever (18) are further pushed to rotate around a fulcrum, and a clamping gap is formed between the lower counterweight moving plate (19) and the upper counterweight moving plate (26); the moving directions of the lower counterweight moving plate (19) and the upper counterweight moving plate (26) are opposite, and when the distance between the lower counterweight moving plate (19) and the upper counterweight moving plate (26) is reduced to move, an object in the clamping gap can be clamped.

Description

High-efficiency kinetic energy conversion equipment and method

Technical Field

The invention relates to the field of machinery, in particular to high-efficiency kinetic energy conversion equipment and method.

Background

The existing mechanical design needs a large number of motors, but the existing machinery rarely moves to a complex lever principle, and does not use the complex lever principle to realize the relative movement of a plate-shaped structure, and the relative movement can realize various industrial effects such as clamping, equidistant movement and the like.

Disclosure of Invention

The purpose of the invention is as follows: the invention has been made in an effort to provide an efficient kinetic energy conversion apparatus and method, and has been embodied in a number of specific embodiments.

In order to achieve the purpose, the invention adopts the following technical scheme:

the first scheme is as follows:

the efficient kinetic energy conversion equipment is characterized by comprising a bottom support 1, wherein a power part 2 is fixed on the bottom support 1, two supports are fixed on the right side of the bottom support 1 and respectively comprise a force bearing support 16 and a working frame 27, two supporting points are arranged on the force bearing support 16 and respectively comprise bearings which are respectively arranged on a second right-angle iron rotating shaft 12 and a first right-angle iron rotating shaft 17, the second right-angle iron rotating shaft 12 and the first right-angle iron rotating shaft 17 respectively comprise a right-angle iron 30 and a rotating shaft 31, and the right-angle iron 30 and the rotating shaft 31 are welded into a whole to form the right-angle iron rotating shaft; the left sides of the second right-angle iron rotating shaft 12 and the first right-angle iron rotating shaft 17 are respectively hinged with a hinged connecting rod 33, and the two hinged connecting rods 33 are respectively a second hinged connecting rod 9 and a first hinged connecting rod 15; the second hinged connecting rod 9 and the first hinged connecting rod 15 are respectively rotatably mounted on a cam hinged structure and can be driven by the cam hinged structure to rotate and lift, the cam hinged structure is positioned on a square sheet to integrally form a rotating structure, the rotating structure can rotate around a shaft of the power wheel penetrating through the side wall 32 of the bracket so as to drive the second hinged connecting rod 9 and the first hinged connecting rod 15 to move relatively, the second lever 10 and the first lever 18 are further pushed to rotate around a fulcrum, the end parts of the second lever 10 and the first lever 18 are respectively hinged with a hinged shaft, the hinged shafts are connected with plates, and the two plates are respectively a lower counterweight moving plate 19 and an upper counterweight moving plate 26; a clamping gap is formed between the lower counterweight moving plate 19 and the upper counterweight moving plate 26; the power wheels corresponding to the second hinge connecting rod 9 and the first hinge connecting rod 15 are respectively a first power wheel 5 and a second power wheel 6, the moving directions of the first power wheel 5 and the second power wheel 6 are opposite, so that the moving directions of the lower counterweight moving plate 19 and the upper counterweight moving plate 26 are opposite, and when the distance between the lower counterweight moving plate 19 and the upper counterweight moving plate 26 is reduced to move, an object can be clamped in the clamping gap.

A further solution of the invention consists in that the first power wheel 5 and the second power wheel 6 are two gears meshing with each other.

The further technical scheme of the invention is that a first power wheel 5 and a second power wheel 6 can be driven by a power part 2 to rotate, gears are arranged on power output shafts of the power part 2 and a speed reducer, the gears are driving wheels 3, the driving wheels 3 are meshed with the first power wheel 5, and the first power wheel 5 is meshed with the second power wheel 6.

The invention further adopts the technical scheme that a lower steel wire fixing position 22 is arranged on the lower counterweight moving plate 19, the lower steel wire fixing position 22 is connected with a steel wire rope, the upper part of the steel wire rope is fixed on an upper counterweight moving plate 26 after passing around an upper fixed pulley 28, and the upper fixed pulley 28 is arranged above a working frame 27.

The further technical scheme of the invention is that the steel wire ropes comprise four groups and are positioned at four corners of the counterweight moving plate 19 below.

The invention further adopts the technical scheme that the auxiliary limiting structure comprises an auxiliary limiting hinge shaft I, one end 13 of the auxiliary limiting hinge shaft I is hinged on the bearing support 16, the auxiliary limiting hinge shaft I is hinged with an auxiliary limiting hinge shaft II 24, the auxiliary limiting hinge shaft II 24 is hinged with an auxiliary limiting hinge shaft III 23, a lower counterweight moving plate 19 is hinged below the auxiliary limiting hinge shaft III 23, and the auxiliary limiting hinge shaft I, the auxiliary limiting hinge shaft II 24 and the auxiliary limiting hinge shaft III 23 can limit the lifting amplitude of the lower counterweight moving plate 19.

The invention further adopts the technical scheme that the periphery of the working frame 27 is provided with angle steel, and the four corners of the lower counter weight moving plate 19 and the upper counter weight moving plate 26 are limited in the angle steel, so that the working frame can be vertically arranged.

The invention further adopts the technical scheme that a shaft of the second power wheel 6 is coaxially provided with a power generation wheel or provided with a power generation wheel through a clutch, the power generation wheel can drive a generator driving wheel 36 to rotate, and the generator driving wheel 36 can drive a generator 34 to rotate through a generator transmission part 35.

A high-efficiency kinetic energy conversion method is characterized in that a power part drives gears to rotate, and further drives a first power wheel 5 to be meshed with a second power wheel 6 to rotate reversely;

the first power wheel 5 is meshed with the second power wheel 6 to rotate reversely to further drive the second hinged connecting rod 9 and the first hinged connecting rod 15 to move relatively, the second lever 10 and the first lever 18 are further pushed to rotate around a fulcrum, and a clamping gap is formed between the lower counterweight moving plate 19 and the upper counterweight moving plate 26; the moving directions of the lower counterweight moving plate 19 and the upper counterweight moving plate 26 are opposite, and when the distance between the lower counterweight moving plate 19 and the upper counterweight moving plate 26 is reduced to move, an object in the clamping gap can be clamped;

meanwhile, a shaft of the second power wheel 6 is coaxially provided with a power generation wheel or provided with a power generation wheel through a clutch, the power generation wheel can drive a generator driving wheel 36 to rotate, and the generator driving wheel 36 can drive a generator 34 to rotate through a generator transmission part 35; the clutch can select whether to generate electricity or not, and then adjust the clamping force between the lower counterweight moving plate 19 and the upper counterweight moving plate 26.

Compared with the prior art, the invention adopting the technical scheme has the following beneficial effects: the lever has better acting effect, and the two groups of levers are skillfully combined in the two groups of connecting rod structures and are driven by rotation to realize the movement of the connecting rods, thereby realizing the orderly and standard opposite movement.

Drawings

To further illustrate the present invention, further description is provided below with reference to the accompanying drawings:

FIG. 1 is a schematic diagram of the inventive structure;

FIG. 2 is a schematic diagram of the basic structure of the invention;

FIG. 3 is a schematic view of the connection of the bottom of the inventive articulation link;

FIG. 4 is a schematic structural view of a right-angle iron rotating shaft part of the invention;

wherein: 1. a bottom bracket; 2. a power section; 3. a driving wheel; 4. a transmission section; 5. a first power wheel; 6. a second power wheel; 7. a second cam hinge structure; 8. a first cam hinge structure; 9. a second articulation link; 10. a second lever; 11. a bearing; 12. a second right-angle iron rotating shaft; 13. one end of an auxiliary limiting hinge shaft; 14. the hinge point of the upper moving part; 15. a first articulation link; 16. a force-bearing support; 17. a first right angle iron shaft; 18. a first lever; 19. a lower counterweight moving plate; 20. the lower counterweight moving plate is hinged; 21. a hinge shaft of the lower counterweight moving plate; 22. the lower steel wire is fixed in position; 23. a third auxiliary limiting articulated shaft; 24. a second auxiliary limiting hinged shaft; 25. the shaft is hinged with the shaft II; 26. an upper counterweight motion plate; 27. a working frame; 28. an upper fixed pulley; 29. a wire rope; 30. right-angle iron; 31. a rotating shaft; 32. a bracket side wall; 33. a hinged connecting rod; 34. a generator; 35. a generator transmission section; 36. the generator driving wheel.

Detailed Description

The present invention will be further illustrated with reference to the accompanying drawings and specific embodiments, which are to be understood as merely illustrative of the invention and not as limiting the scope of the invention. In the description of the present invention, it should be noted that the terms "center", "upper", "lower", "left", "right", "vertical", "horizontal", "inner", "outer", "top", "bottom", and the like indicate orientations or positional relationships based on those shown in the drawings, and are only for convenience of description and simplicity of description, but do not indicate or imply that the referred device or element must have a specific orientation, be constructed in a specific orientation, and be operated, and thus, should not be construed as limiting the present invention. Furthermore, unless expressly stated or limited otherwise, the terms "mounted," "connected," and "connected" are to be construed broadly, as they may be fixedly connected, detachably connected, or integrally connected, for example; can be mechanically or electrically connected; they may be connected directly or indirectly through intervening media, or they may be interconnected between two elements. The specific meanings of the above terms in the present invention can be understood in specific cases to those skilled in the art.

It is noted that, herein, relational terms such as first and second, and the like may be used solely to distinguish one entity or action from another entity or action without necessarily requiring or implying any actual such relationship or order between such entities or actions. Also, the terms "comprises," "comprising," or any other variation thereof, are intended to cover a non-exclusive inclusion, such that a process, method, article, or apparatus that comprises a list of elements does not include only those elements but may include other elements not expressly listed or inherent to such process, method, article, or apparatus.

The patent provides a plurality of parallel schemes, and different expressions belong to an improved scheme based on a basic scheme or a parallel scheme. Each solution has its own unique features. In addition, the technical features involved in the different embodiments of the present invention described below may be combined with each other as long as they do not conflict with each other. The fixing means, which is not described herein, may be any one of screw fixing, bolt fixing, or glue bonding.

The first embodiment is as follows: with reference to all of the accompanying drawings; the efficient kinetic energy conversion equipment is characterized by comprising a bottom support 1, wherein a power part 2 is fixed on the bottom support 1, two supports are fixed on the right side of the bottom support 1 and respectively comprise a force bearing support 16 and a working frame 27, two supporting points are arranged on the force bearing support 16 and respectively comprise bearings which are respectively arranged on a second right-angle iron rotating shaft 12 and a first right-angle iron rotating shaft 17, the second right-angle iron rotating shaft 12 and the first right-angle iron rotating shaft 17 respectively comprise a right-angle iron 30 and a rotating shaft 31, and the right-angle iron 30 and the rotating shaft 31 are welded into a whole to form the right-angle iron rotating shaft; the left sides of the second right-angle iron rotating shaft 12 and the first right-angle iron rotating shaft 17 are respectively hinged with a hinged connecting rod 33, and the two hinged connecting rods 33 are respectively a second hinged connecting rod 9 and a first hinged connecting rod 15; the second hinged connecting rod 9 and the first hinged connecting rod 15 are respectively rotatably mounted on a cam hinged structure and can be driven by the cam hinged structure to rotate and lift, the cam hinged structure is positioned on a square sheet to integrally form a rotating structure, the rotating structure can rotate around a shaft of the power wheel penetrating through the side wall 32 of the bracket so as to drive the second hinged connecting rod 9 and the first hinged connecting rod 15 to move relatively, the second lever 10 and the first lever 18 are further pushed to rotate around a fulcrum, the end parts of the second lever 10 and the first lever 18 are respectively hinged with a hinged shaft, the hinged shafts are connected with plates, and the two plates are respectively a lower counterweight moving plate 19 and an upper counterweight moving plate 26; a clamping gap is formed between the lower counterweight moving plate 19 and the upper counterweight moving plate 26; the power wheels corresponding to the second hinge connecting rod 9 and the first hinge connecting rod 15 are respectively a first power wheel 5 and a second power wheel 6, the moving directions of the first power wheel 5 and the second power wheel 6 are opposite, so that the moving directions of the lower counterweight moving plate 19 and the upper counterweight moving plate 26 are opposite, and when the distance between the lower counterweight moving plate 19 and the upper counterweight moving plate 26 is reduced to move, an object can be clamped in the clamping gap. The technical scheme of the invention has the following substantial technical effects and the realization process: the lever has better acting effect, and the two groups of levers are skillfully combined in the two groups of connecting rod structures and are driven by rotation to realize the movement of the connecting rods, thereby realizing the orderly and standard opposite movement. A high-efficiency kinetic energy conversion method is characterized in that a power part drives gears to rotate, and further drives a first power wheel 5 to be meshed with a second power wheel 6 to rotate reversely;

example two: as a further development or in parallel or alternatively independently, both the first power wheel 5 and the second power wheel 6 are two gears meshing with each other.

The technical scheme of the invention has the following substantial technical effects and the realization process: this embodiment provides a specific implementation of opposite rotation power, and similar implementations are within the scope of this patent.

Example three: as a further improvement scheme or a parallel scheme or an optional independent scheme, the first power wheel 5 and the second power wheel 6 can be driven by the power part 2 to rotate, the power part 2 and a power output shaft of the speed reducer comprise gears, the gears are driving wheels 3, the driving wheels 3 are meshed with the first power wheel 5, and the first power wheel 5 is meshed with the second power wheel 6. The technical scheme of the invention has the following substantial technical effects and the realization process: this embodiment is a further improvement of the previous embodiment, and provides a specific gear connection structure, and similar implementation structures are within the scope of this patent.

Example four: as a further improvement or a parallel scheme or an alternative independent scheme, a lower wire fixing position 22 is arranged on the lower counterweight moving plate 19, a wire rope is connected to the lower wire fixing position 22, the upper portion of the wire rope is fixed on the upper counterweight moving plate 26 after passing around an upper fixed pulley 28, and the upper fixed pulley 28 is arranged above the working frame 27. The technical scheme of the invention has the following substantial technical effects and the realization process: the wires have the effect of further coordinating the movement, allowing the lower counterweight movement plate 19 and the upper counterweight movement plate 26 to move more in unison.

Example five: as a further improvement or a parallel scheme or an alternative independent scheme, the steel wire ropes comprise four groups and are positioned at four corners of the lower counterweight moving plate 19. The technical scheme of the invention has the following substantial technical effects and the realization process: the stress balance effect is good.

Example six: as a further improvement scheme or a parallel scheme or an optional independent scheme, the device further comprises an auxiliary limiting structure, wherein the auxiliary limiting structure comprises an auxiliary limiting hinge shaft I, one end 13 of the auxiliary limiting hinge shaft I is hinged on the bearing support 16, the auxiliary limiting hinge shaft I is hinged with an auxiliary limiting hinge shaft II 24, the auxiliary limiting hinge shaft II 24 is hinged with an auxiliary limiting hinge shaft III 23, the lower counterweight motion plate 19 is hinged below the auxiliary limiting hinge shaft III 23, and the auxiliary limiting hinge shaft I, the auxiliary limiting hinge shaft II 24 and the auxiliary limiting hinge shaft III 23 can limit the lifting amplitude of the lower counterweight motion plate 19. The technical scheme of the invention has the following substantial technical effects and the realization process: can realize basic spacing, let spacing effect better.

Example seven: as a further modification or a parallel scheme or an alternative independent scheme, the working frame 27 is provided with angle steel around, and the four corners of the lower counter weight moving plate 19 and the upper counter weight moving plate 26 are limited in the angle steel so as to be capable of going straight up and straight down. The technical scheme of the invention has the following substantial technical effects and the realization process: this scheme is an alternative.

Example eight: as a further improvement or a parallel scheme or an optional independent scheme, a shaft of the second power wheel 6 is coaxially provided with a generator wheel or provided with a clutch, the generator wheel can drive a generator driving wheel 36 to rotate, and the generator driving wheel 36 can drive a generator 34 to rotate through a generator transmission part 35.

Meanwhile, a shaft of the second power wheel 6 is coaxially provided with a power generation wheel or provided with a power generation wheel through a clutch, the power generation wheel can drive a generator driving wheel 36 to rotate, and the generator driving wheel 36 can drive a generator 34 to rotate through a generator transmission part 35; the clutch can select whether to generate electricity or not, and then adjust the clamping force between the lower counterweight moving plate 19 and the upper counterweight moving plate 26. The gripping structure may be used to break up items, etc.

In addition, it should be noted that the position of the fulcrum is adjusted, the acting condition of the lever can be adjusted, and the common structure is more convenient to realize.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are intended to illustrate the principles of the invention, but that various changes and modifications may be made without departing from the spirit and scope of the invention, and the invention is to be limited to the embodiments described above.

Claims

1. The efficient kinetic energy conversion equipment and the efficient kinetic energy conversion method are characterized by comprising a bottom support (1), wherein a power part (2) is fixed on the bottom support (1), two supports are fixed on the right side of the bottom support (1), the two supports are respectively a force bearing support (16) and a working frame (27), the force bearing support (16) is provided with two fulcrums which are respectively bearings arranged on a second right-angle iron rotating shaft (12) and a first right-angle iron rotating shaft (17), the second right-angle iron rotating shaft (12) and the first right-angle iron rotating shaft (17) respectively comprise right-angle irons (30) and rotating shafts (31), and the right-angle irons (30) and the rotating shafts (31) are welded into a whole to form the right-angle iron rotating shafts; the left sides of the second right-angle iron rotating shaft (12) and the first right-angle iron rotating shaft (17) are respectively hinged with a hinged connecting rod (33), and the two hinged connecting rods (33) are respectively a second hinged connecting rod (9) and a first hinged connecting rod (15); the second hinged connecting rod (9) and the first hinged connecting rod (15) are respectively rotatably mounted on the cam hinged structure and can be driven by the cam hinged structure to rotate and lift, the cam hinged structure is positioned on a square sheet and integrally forms a rotating structure, the rotating structure can rotate around a shaft of the power wheel penetrating through the side wall (32) of the bracket so as to drive the second hinged connecting rod (9) and the first hinged connecting rod (15) to move relatively, the second lever (10) and the first lever (18) are further pushed to rotate around a fulcrum, the end parts of the second lever (10) and the first lever (18) are respectively hinged with a hinged shaft, the hinged shafts are connected with a plate, and the two plates are a lower counterweight moving plate (19) and an upper counterweight moving plate (26); a clamping gap is formed between the lower counterweight moving plate (19) and the upper counterweight moving plate (26); the power wheels corresponding to the second hinged connecting rod (9) and the first hinged connecting rod (15) are respectively a first power wheel (5) and a second power wheel (6), the moving directions of the first power wheel (5) and the second power wheel (6) are opposite, so that the moving directions of the lower counterweight moving plate (19) and the upper counterweight moving plate (26) are opposite, and when the distance between the lower counterweight moving plate (19) and the upper counterweight moving plate (26) is reduced to move, an object can be clamped in the clamping gap.

2. A high efficiency kinetic energy conversion apparatus and method as in claim 1, characterized in that the first power wheel (5) and the second power wheel (6) are two gears meshing with each other.

3. A high efficiency kinetic energy conversion apparatus and method as in claim 2, wherein the first power wheel (5) and the second power wheel (6) are capable of being rotated by the power section (2), the power section (2) and the power take-off shaft of the reducer comprise gears, the gears are driving wheels (3), the driving wheels (3) engage the first power wheel (5), and the first power wheel (5) engages the second power wheel (6).

4. A high efficiency kinetic energy conversion apparatus and method as claimed in claim 1, wherein the lower counterweight moving plate (19) is arranged with a lower wire fixing position (22), the lower wire fixing position (22) is connected with a wire rope, the wire rope is fixed on the upper counterweight moving plate (26) after passing over an upper fixed pulley (28), and the upper fixed pulley (28) is arranged above the working frame (27).

5. A high efficiency kinetic energy conversion apparatus and method as claimed in claim 4, wherein the wire ropes are comprised of four groups, located at the four corners of the lower counterweight moving plate (19).

6. A high efficiency kinetic energy conversion device and method as claimed in claim 1, further comprising an auxiliary limiting structure, wherein the auxiliary limiting structure comprises a first auxiliary limiting hinge shaft, one end (13) of the first auxiliary limiting hinge shaft is hinged on the force bearing support (16), the first auxiliary limiting hinge shaft is hinged with a second auxiliary limiting hinge shaft (24), the second auxiliary limiting hinge shaft (24) is hinged with a third auxiliary limiting hinge shaft (23), the lower counterweight moving plate (19) is hinged below the third auxiliary limiting hinge shaft (23), and the first auxiliary limiting hinge shaft, the second auxiliary limiting hinge shaft (24) and the third auxiliary limiting hinge shaft (23) can limit the lifting amplitude of the lower counterweight moving plate (19).

7. A highly efficient kinetic energy conversion apparatus and method as claimed in claim 1, wherein the working frame (27) is surrounded by angle steel, and the four corners of the lower counter weight moving plate (19) and the upper counter weight moving plate (26) are restrained in the angle steel so as to be able to go straight up and down.

8. A high efficiency kinetic energy conversion device and method as in claim 3, characterized in that the second power wheel (6) is coaxially mounted on its shaft or is mounted with a generator wheel through a clutch, the generator wheel can drive the generator driving wheel (36) to rotate, the generator driving wheel (36) can drive the generator (34) to rotate through the generator transmission part (35).

9. A high-efficiency kinetic energy conversion device and method are characterized in that a power part drives gears to rotate, and further drives a first power wheel (5) to be meshed with a second power wheel (6) to rotate reversely;

the first power wheel (5) is meshed with the second power wheel (6) and rotates reversely to further drive the second hinged connecting rod (9) and the first hinged connecting rod (15) to move relatively, the second lever (10) and the first lever (18) are further pushed to rotate around a fulcrum, and a clamping gap is formed between the lower counterweight moving plate (19) and the upper counterweight moving plate (26); the moving directions of the lower counterweight moving plate (19) and the upper counterweight moving plate (26) are opposite, and when the distance between the lower counterweight moving plate (19) and the upper counterweight moving plate (26) is reduced to move, an object in the clamping gap can be clamped;

meanwhile, a shaft of the second power wheel (6) is coaxially provided with a power generation wheel or provided with the power generation wheel through a clutch, the power generation wheel can drive a generator driving wheel (36) to rotate, and the generator driving wheel (36) can drive a generator (34) to rotate through a generator transmission part (35); the clutch can select whether to generate electricity or not, and then the clamping force between the lower counterweight moving plate (19) and the upper counterweight moving plate (26) is adjusted.