CN112096581A - Kinetic energy device for transmission by utilizing magnetic field and lever - Google Patents

Abstract

The invention relates to the technical field of kinetic energy equipment, and particularly discloses a kinetic energy device for transmission by utilizing a magnetic field and a lever. Has the advantages that: the repulsion that the rotation of utilizing two magnets that the magnetic pole is relative produced realizes the transmission of power, then utilizes magnet to drive the connecting rod rotatory, and then drives lever reciprocating motion from top to bottom, utilizes lever principle to carry out the transmission, utilizes very little power can pry the equipment work that possess great resistance to realize utilizing the low-power supply to drive the work of high-power kinetic energy consumer, the energy can be saved.

Description

Kinetic energy device for transmission by utilizing magnetic field and lever

Technical Field

The invention relates to the technical field of kinetic energy equipment, in particular to a kinetic energy device for transmission by utilizing a magnetic field and a lever.

Background

The kinetic energy machine is a device for providing kinetic energy, and the existing kinetic energy machine has large kinetic energy loss and low output power when generating power.

Disclosure of Invention

The present invention provides a kinetic energy device using a magnetic field and a lever for transmission to solve the above problems.

The technical scheme of the invention is realized as follows:

the utility model provides an utilize magnetic field and lever to carry out driven kinetic energy device, includes the power supply, the power supply is connected with magnetic drive device through the clutch transmission, magnetic drive device goes up articulated have first connecting rod, first connecting rod tip articulates there is first vertical lift pole, first vertical lift pole tip slidable mounting is on the lever, the lever is fixed on the supporting seat through the round pin axle, lever other end slidable mounting has second vertical lift pole, the articulated second connecting rod that is fixed with of second vertical lift pole, second connecting rod end fixing is on the crank of bent axle, bent axle tip key-type connection is fixed with the transmission gear wheel, bent axle one side is provided with power output shaft, the last key connection of power output shaft have with the driven transmission pinion of transmission gear wheel meshing.

Further, the power source includes any one of an internal combustion engine and an electric motor.

Furthermore, the hinge point of the supporting seat and the lever is close to the second vertical lifting rod.

Furthermore, at least one crank is arranged on the crank shaft, and each crank is connected with a power source through the lever in a transmission manner.

Further, magnetic transmission device includes the fixing base, be fixed with the transmission shaft through the bearing on the fixing base, transmission shaft one end key is connected with first magnet, the first magnet outside is provided with to rotate and installs the epaxial second magnet of transmission, lock nut is installed through the screw thread to the transmission shaft tip, first magnet with between the second magnet with all be provided with the transition axle sleeve between the lock nut, the transition axle sleeve nestification is in on the transmission shaft.

Furthermore, the transmission shaft comprises a transition shaft shoulder, first bearing installation shaft sections are formed at two ends of the transition shaft shoulder, a first spline shaft section is formed at the outer end of one of the first bearing installation shaft sections in an integrated mode, a second spline shaft section is formed at the outer end of the other first bearing installation shaft section in an integrated mode, a second bearing installation shaft section is formed at the outer end of the second spline shaft section in an integrated mode, and an external thread groove is machined at the outer end of the second bearing installation shaft section.

Furthermore, first magnet includes first mount, first mount key-type connection is fixed on the second spline shaft section, first mount tip integrated into one piece has first fixed case, first fixed incasement is fixed with first magnetic block.

Furthermore, the second magnet comprises a second fixing frame, the second fixing frame is fixed to the second bearing mounting shaft section through a bearing, a second fixing box is integrally formed at the end of the second fixing frame, a second magnetic block is fixed in the second fixing box, the magnetic poles of the first magnetic block and the second magnetic block are opposite, and the first connecting rod is hinged to the center of the outer side of the second magnet.

By adopting the technical scheme, the invention has the beneficial effects that: the repulsion that the rotation of utilizing two magnets that the magnetic pole is relative produced realizes the transmission of power, then utilizes magnet to drive the connecting rod rotatory, and then drives lever reciprocating motion from top to bottom, utilizes lever principle to carry out the transmission, utilizes very little power can pry the equipment work that possess great resistance to realize utilizing the low-power supply to drive the work of high-power kinetic energy consumer, the energy can be saved.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of the present invention;

FIG. 2 is a schematic structural diagram of a second embodiment of the present invention;

FIG. 3 is a schematic view of the magnetic actuator of the present invention;

FIG. 4 is a side view of the magnetic actuator of the present invention;

fig. 5 is a schematic view of the drive shaft structure of the present invention.

The reference numerals are explained below:

1. a power source; 2. a magnetic transmission device; 21. a fixed seat; 22. a drive shaft; 221. a transition shoulder; 222. a first bearing mounting shaft section; 223. a first splined shaft section; 224. a second splined shaft section; 225. the second bearing is provided with a shaft section; 226. an outer thread groove; 23. a first magnet; 231. a first fixing frame; 232. a first stationary box; 233. a first magnetic block; 24. a second magnet; 241. a second fixing frame; 242. a second stationary box; 243. a second magnetic block; 25. a transition shaft sleeve; 26. locking the nut; 3. a first link; 4. a first vertical lift rod; 5. a lever; 6. a supporting seat; 7. a second vertical lift rod; 8. a second link; 9. a crankshaft; 10. a driving gearwheel; 11. a drive pinion; 12. and a power output shaft.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

The first embodiment is as follows:

as shown in fig. 1, 3, 4 and 5, a kinetic energy device utilizing a magnetic field and a lever for transmission comprises a power source 1, wherein the power source 1 comprises any one of an internal combustion engine and an electric motor and is used for generating smaller power, the power source 1 is connected with a magnetic transmission device 2 through a clutch in a transmission way, a first connecting rod 3 is hinged on the magnetic transmission device 2, a first vertical lifting rod 4 is hinged at the end part of the first connecting rod 3, the end part of the first vertical lifting rod 4 is slidably arranged on the lever 5, the lever 5 is fixed on a supporting seat 6 through a pin shaft, a second vertical lifting rod 7 is slidably arranged at the other end of the lever 5, a hinged point of the supporting seat 6 and the lever 5 is close to the second vertical lifting rod 7, transmission is carried out by utilizing the lever principle, equipment with larger load driven by small force can be started and operated, a second connecting rod 8 is hinged and fixed on the, the end part of the second connecting rod 8 is fixed on a crank of a crankshaft 9, the end part of the crankshaft 9 is in key connection with a transmission big gear 10, one side of the crankshaft 9 is provided with a power output shaft 12, the upper key of the power output shaft 12 is connected with a transmission small gear 11 in meshing transmission with the transmission big gear 10, the number of teeth of the transmission big gear 10 is greater than that of the transmission small gear 11, and the rotating speed of the power output shaft 12 can be improved.

In this embodiment, the magnetic transmission device 2 includes a fixed seat 21, a transmission shaft 22 is fixed on the fixed seat 21 through a bearing, one end of the transmission shaft 22 is keyed with a first magnet 23, a second magnet 24 rotatably mounted on the transmission shaft 22 is disposed on the outer side of the first magnet 23, a lock nut 26 is mounted on the end of the transmission shaft 22 through a thread, transition shaft sleeves 25 are disposed between the first magnet 23 and the second magnet 24 and between the second magnet 24 and the lock nut 26, and the transition shaft sleeves 25 are nested on the transmission shaft 22.

In this embodiment, the transmission shaft 22 includes a transition shaft shoulder 221, first bearing mounting shaft sections 222 are formed at two ends of the transition shaft shoulder 221, a first spline shaft section 223 is formed at an outer end of one of the first bearing mounting shaft sections 222, a second spline shaft section 224 is formed at an outer end of the other one of the first bearing mounting shaft sections 222, a second bearing mounting shaft section 225 is formed at an outer end of the second spline shaft section 224, and an external thread groove 226 is processed at an outer end of the second bearing mounting shaft section 225.

In this embodiment, the first magnet 23 includes a first fixing frame 231, the first fixing frame 231 is fixed on the second spline shaft section 224 by a key connection, a first fixing box 232 is integrally formed at an end of the first fixing frame 231, a first magnetic block 233 is fixed in the first fixing box 232, and the first fixing frame 231 and the first fixing box 232 are made of a material that does not produce magnetization, such as plastic, ceramic, aluminum, etc., so as to avoid magnetization caused by long-term use.

In this embodiment, the second magnet 24 includes a second fixing frame 241, the second fixing frame 241 is fixed on the second bearing mounting shaft section 225 through a bearing, the end of the second fixing frame 241 is integrally formed with a second fixing box 242, a second magnetic block 243 is fixed in the second fixing box 242, the magnetic poles of the first magnetic block 233 and the second magnetic block 243 are opposite, the first connecting rod 3 is hinged at the center of the outer side of the second magnet 24, when the first magnet 23 rotates along with the transmission shaft 22, the second magnet 24 can be driven to rotate, power transmission by using a magnetic field is realized, the second fixing frame 241 and the second fixing box 242 are made of materials which do not produce magnetization, such as plastics, ceramics, aluminum and the like, so that magnetization caused by long-time use is avoided, and magnetic field force of the two magnets is not affected at the same time.

Example two:

as shown in fig. 2: the content of this embodiment is substantially the same as that of the first embodiment, except that:

in this embodiment, the crankshaft 9 is provided with two opposite cranks, each crank is connected with one power source 1 through the transmission of the lever 5, the output force of the power sources 1 can be further reduced by the driving of the multiple power sources 1, and the equipment can be driven to work by utilizing smaller power.

Example three:

the content of this embodiment is substantially the same as that of the first embodiment, except that:

in this embodiment, the coils are arranged outside the first magnet 23 and the second magnet 24, and the coils are cut by the first magnet 23 and the second magnet 24 in the rotating process to generate current, so as to directly generate electricity, thus the energy in the power transmission process can be fully utilized, the energy utilization rate is improved, and when the power source 1 is a generator, the consumption of the commercial power can be reduced, and the purpose of saving energy is achieved.

The working principle of the invention is as follows: during the use, power source 1 produces power and drives transmission shaft 22 rotatory, transmission shaft 22 drives first magnet 23 and rotates, first magnet 23 promotes second magnet 24 rotatory through magnetic force when rotating, second magnet 24 drives lever 5 through first connecting rod 3 and first vertical lift pole 4 when rotatory and reciprocates, lever 5 drives bent axle 9 through second vertical lift pole 7 and second connecting rod 8 when reciprocating and rotates, bent axle 9 drives power output shaft 12 through the transmission of transmission gear wheel 10 and transmission pinion 11 when rotatory and rotates and export power, can connect the weaving machine on the power output shaft 12, equipment such as mill uses, can transmit at bent axle 9 or power output shaft 12 tip simultaneously and connect the generating equipment and generate electricity the use.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (8)

1. A kinetic energy device utilizing a magnetic field and a lever for transmission is characterized in that: including power supply (1), power supply (1) is connected with magnetic drive device (2) through the clutch transmission, it has first connecting rod (3) to articulate on magnetic drive device (2), first connecting rod (3) tip articulates there is first vertical lift pole (4), first vertical lift pole (4) tip slidable mounting is on lever (5), lever (5) are fixed on supporting seat (6) through the round pin axle, lever (5) other end slidable mounting has second vertical lift pole (7), second vertical lift pole (7) articulate and are fixed with second connecting rod (8), second connecting rod (8) tip is fixed on the crank of bent axle (9), bent axle (9) tip key-type connection is fixed with transmission gear wheel (10), bent axle (9) one side is provided with power output shaft (12), power output shaft (12) key-type connection have with transmission gear wheel (10) meshing driven transmission pinion (11).

2. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 1, wherein: the power source (1) includes any one of an internal combustion engine and an electric motor.

3. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 1, wherein: and the hinge point of the support seat (6) and the lever (5) is close to the second vertical lifting rod (7).

4. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 1, wherein: at least one crank is arranged on the crankshaft (9), and each crank is in transmission connection with one power source (1) through the lever (5).

5. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 1, wherein: magnetic drive device (2) are including fixing base (21), be fixed with transmission shaft (22) through the bearing on fixing base (21), transmission shaft (22) one end key-type connection has first magnet (23), first magnet (23) outside is provided with rotates and installs second magnet (24) on transmission shaft (22), lock nut (26) are installed through the screw thread to transmission shaft (22) tip, first magnet (23) with between second magnet (24) with all be provided with transition axle sleeve (25) between lock nut (26), it is nested in transition axle sleeve (25) on transmission shaft (22).

6. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 5, wherein: the transmission shaft (22) comprises a transition shaft shoulder (221), first bearing mounting shaft sections (222) are formed at two ends of the transition shaft shoulder (221), a first spline shaft section (223) is formed at the outer end of one first bearing mounting shaft section (222) in an integrated mode, a second spline shaft section (224) is formed at the outer end of the other first bearing mounting shaft section (222) in an integrated mode, a second bearing mounting shaft section (225) is formed at the outer end of the second spline shaft section (224), and an external thread groove (226) is machined at the outer end of the second bearing mounting shaft section (225).

7. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 6, wherein: the first magnet (23) comprises a first fixing frame (231), the first fixing frame (231) is fixedly connected with the second spline shaft section (224) in a key mode, a first fixing box (232) is integrally formed at the end of the first fixing frame (231), and a first magnetic block (233) is fixed in the first fixing box (232).

8. The kinetic energy device utilizing the magnetic field and the lever for transmission as claimed in claim 7, wherein: the second magnet (24) comprises a second fixing frame (241), the second fixing frame (241) is fixed to the second bearing mounting shaft section (225) through a bearing, a second fixing box (242) is integrally formed at the end of the second fixing frame (241), a second magnetic block (243) is fixed to the second fixing box (242), the first magnetic block (233) is opposite to the magnetic pole of the second magnetic block (243), and the first connecting rod (3) is hinged to the center of the outer side of the second magnet (24).

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