CN115199338A - Novel energy transmission device for converting potential energy into mechanical energy - Google Patents

Abstract

The invention provides a novel energy transmission device for converting potential energy into mechanical energy, which comprises a base and a cover plate arranged at the right end of the base, wherein a first concave hole and a second concave hole are formed in the right end of the base, the first concave hole is communicated with the lower end of the second concave hole, a large impeller is movably arranged in the first concave hole, a plurality of convex blades are arranged at the outer end of the large impeller at equal intervals and attached to the inner wall of the first concave hole, an additional wheel is movably arranged in the second concave hole and attached to the upper end of the large impeller, a plurality of concave tooth holes are formed at the outer end of the additional wheel at equal intervals, an air inlet hole is formed in the rear side of the left end of the base and is arranged at the rear side of the attachment position of the additional wheel and the large impeller, an air outlet hole is formed in the front side of the left end of the base and is arranged at the front side of the attachment position of the additional wheel and the large impeller, and the design can directly convert the potential energy of high-pressure gas into the mechanical energy which can rotate.

Description

Novel energy transmission device for converting potential energy into mechanical energy

Technical Field

The invention relates to a novel energy transmission device for converting potential energy into mechanical energy, belonging to the technical field of energy transmission.

Background

Mechanical energy is a physical quantity representing the motion state and height of an object, the mechanical energy and potential energy of the object can be converted, and in the rotating machinery for converting the energy into the energy, such as an engine, a generator, a pneumatic device and the like, the energy transmission device for converting the potential energy into the mechanical energy in the prior art generally adopts a structure of matching fan blades and a gear set to carry out energy transmission, so that consumption can be generated in the energy transmission process, the energy transmission efficiency is influenced, larger noise is easy to generate, the operation balance is poor, and therefore a novel energy transmission device for converting the potential energy into the mechanical energy needs to be designed to solve the problems.

Disclosure of Invention

Aiming at the defects in the prior art, the invention aims to provide a novel energy transmission device for converting potential energy into mechanical energy so as to solve the problems in the background technology.

In order to achieve the purpose, the invention is realized by the following technical scheme: the utility model provides a novel energy transfer device that potential energy changes mechanical energy into, includes the base and installs the apron at the base right-hand member, the base right-hand member is seted up first shrinkage pool and second shrinkage pool and first shrinkage pool and the second shrinkage pool is in the apron left end, first shrinkage pool intercommunication sets up at second shrinkage pool lower extreme, the big impeller of movable mounting in the first shrinkage pool, big impeller outer end equidistance sets up and is a plurality of convex blades and the laminating of convex blade that circular was arranged on first shrinkage pool inner wall, the activity sets up the laminating of additional wheel and additional wheel in the second shrinkage pool in the big impeller upper end, additional wheel outer end equidistance sets up and is a plurality of concave tooth holes that use with the convex blade cooperation of circular arrangement, base left end rear end is seted up and is set up just inlet port and first shrinkage pool intercommunication, the inlet port sets up at additional wheel and big impeller laminating position rear side, base left end front side processing venthole and first shrinkage pool intercommunication, the venthole sets up at additional wheel and big impeller laminating position front side.

Furtherly, the inside bottom intermediate position of first shrinkage pool rotates connects the fixed big impeller in first pivot and first pivot outer end, first pivot runs through the apron and rotates with the apron through sealed bearing and is connected, the inside bottom intermediate position of second shrinkage pool rotates connects the fixed driving wheel in second pivot and second pivot outer end, the second pivot runs through the apron and rotates with the apron through sealed bearing and be connected.

Furthermore, first grooves are formed in the middle positions of the left end and the right end of the large impeller, and second grooves are formed in the middle positions of the left end and the right end of the attached wheel.

Furthermore, a third groove is formed in the middle of one end, away from the large impeller, of the convex blade, and a first reinforcing piece is fixed inside the third groove.

Furthermore, the edge positions of the upper side and the lower side of the right end of the base are provided with notch grooves, the notch grooves extend to the outward end of the base, the notch grooves are formed in the left end of the cover plate, the left wall in the notch grooves is symmetrically provided with two first through holes, and the four corner positions of the right end of the cover plate are provided with second through holes, and the center lines of the second through holes are overlapped with the center lines of the first through holes.

Further, a second reinforcing piece is installed in the notch groove and located at the left end of the cover plate, and the second reinforcing piece is arranged between the two first through holes in the corresponding notch groove.

Furthermore, a plurality of first positioning columns are installed at the left end of the second reinforcing part at equal intervals and are located in first positioning holes formed in the base, and a plurality of second positioning columns are arranged at the right end of the second reinforcing part at equal intervals and are located in second positioning holes machined in the cover plate.

The invention has the beneficial effects that: the invention relates to a novel energy transmission device for converting potential energy into mechanical energy.

1. A closed cavity which appears circularly is formed between the occlusion part of the large impeller and the additional wheel and a convex blade on the large impeller which is closest to the occlusion part, and the convex blade on the large impeller moves towards the direction far away from the occlusion part when high-pressure gas is input into an air inlet hole, so that high-speed clockwise rotation is realized, the potential energy of the high-pressure gas is directly converted into mechanical energy for rotating the additional wheel, and the high-speed clockwise rotation can be applied to rotating machinery for converting energy such as an engine, a generator, pneumatic equipment and the like.

2. Utilize the breach groove to make apron and base fastening appear one section with the screw thread pole portion of bolt and expose the section, when appearing unable dismantlement between bolt and the nut, can cut off the processing to the section that exposes of bolt, realize conveniently dismantling between apron and the base.

3. The first positioning column and the first positioning hole are utilized to position and install the rectangular block and the base, and the second positioning column on the rectangular block is inserted into the second positioning hole on the cover plate, so that the rectangular block and the cover plate are positioned and installed, the purpose of positioning and placing the cover plate and the base is achieved, the first through hole is aligned with the second through hole, and the subsequent bolt is convenient to install.

4. The first rotating shaft and the second rotating shaft can be provided with the load parts, so that the purpose of rotating the two load parts by using the first rotating shaft and the second rotating shaft is achieved, and the application of mechanical energy is realized.

Drawings

Other features, objects and advantages of the invention will become more apparent upon reading of the detailed description of non-limiting embodiments with reference to the following drawings:

FIG. 1 is a schematic diagram of a novel energy transfer device for converting potential energy to mechanical energy in accordance with the present invention;

FIG. 2 is an assembly view of the base, the large impeller and the additional impeller of the novel energy transmission device for converting potential energy into mechanical energy;

FIG. 3 is a perspective view of a base of a novel energy transfer device for converting potential energy into mechanical energy in accordance with the present invention;

FIG. 4 is a perspective view of a large impeller of a novel energy transfer device for converting potential energy into mechanical energy in accordance with the present invention;

fig. 5 is a perspective view of an additional wheel in the novel energy transmission device for converting potential energy into mechanical energy according to the present invention.

In the figure: the device comprises a base 1, a large impeller 2, an auxiliary impeller 3, a concave tooth hole 4, a cover plate 5, a convex blade 6, an air inlet 7, an air outlet 8, a first positioning column 11, a rectangular block 12, a second positioning column 13, a notch groove 14, a first through hole 15, a first concave hole 16, a second concave hole 17, a first rotating shaft 21, a first groove 22, a second rotating shaft 31, a second groove 32 and a rectangular plate 61.

Detailed Description

In order to make the technical means, the creation characteristics, the achievement purposes and the effects of the invention easy to understand, the invention is further described with the specific embodiments.

Referring to fig. 1, fig. 2 and fig. 3, the present invention provides a technical solution: the utility model provides a novel potential energy change mechanical energy transfer device, include base 1 and install apron 5 at the 1 right-hand member of base, breach groove 14 and breach groove 14 extend to base 1 towards the outer end all are seted up to both sides edge position about the 1 right-hand member of base, breach groove 14 sets up at 5 left ends of apron, two first through-holes 15 are seted up to 14 inside left wall symmetries in breach groove, four edges and corners positions of 5 right-hand members of apron all process second through-hole and second through-hole central line and 15 central lines of first through-hole coincide together, first through-hole 15 uses with the cooperation of second through-hole, can provide installation space for the bolt, and then make the fastening installation between apron 5 and the base 1.

Specifically, can laminate apron 5 to base 1 right-hand member, and make 15 central lines of first through-hole and second through-hole central line coincide together, then run through the second through-hole on the apron 5 with the bolt, first through-hole 15 on breach groove 14 on the base 1 and with corresponding nut threaded connection, thereby make the fastening installation between apron 5 and the base 1, breach groove 14 can make one section exposure section appear in the screw thread pole portion of bolt this moment, when unable dismantlement appears between bolt and the nut, can cut off the processing to the exposure section of bolt, realize convenient the dismantlement between apron 5 and the base 1.

As shown in fig. 1, fig. 2 and fig. 3, a second reinforcement is installed in the notch groove 14 and located at the left end of the cover plate 5, the second reinforcement is disposed on the notch groove 14, which increases the connection strength between the cover plate 5 and the base 1, thereby effectively preventing the deformation of the cover plate 5 due to the bolt installation, the second reinforcement can be a rectangular block 12, the second reinforcement is disposed between two first through holes 15 in the corresponding notch groove 14, the left end of the second reinforcement is equidistantly provided with a plurality of first positioning posts 11, the first positioning posts 11 are located in first positioning holes formed in the base 1, the first positioning posts 11 are used in cooperation with the first positioning holes, so as to achieve the positioning installation between the second reinforcement and the base 1, the right end of the second reinforcement is equidistantly provided with a plurality of second positioning posts 13, the second positioning posts 13 are located in second positioning holes processed on the cover plate 5, the second positioning posts 13 are used in cooperation with the second positioning holes, and the positioning installation between the cover plate 5 and the second reinforcement.

Specifically, place rectangular block 12 in breach groove 14 earlier, and make first reference column 11 on the rectangular block 12 assign to first locating hole in, thereby make the location installation between rectangular block 12 and the base 1, then place base 1 right-hand member with apron 5, and make second reference column 13 on the rectangular block 12 assign to the second locating hole on the apron 5, thereby make the location installation between rectangular block 12 and the apron 5, reach the purpose that the location was placed between apron 5 and the base 1, thereby guarantee first through-hole 15 and second through-hole align, make things convenient for the installation of follow-up bolt.

As shown in fig. 1, 2, 3, 4 and 5, a first concave hole 16 and a second concave hole 17 are arranged at the right end of a base 1, the first concave hole 16 and the second concave hole 17 are arranged at the left end of a cover plate 5, the first concave hole 16 is used for providing an installation space for a large impeller 2, the second concave hole 17 is used for providing an installation space for an additional impeller 3, the first concave hole 16 is communicated with the lower end of the second concave hole 17, the large impeller 2 is movably installed in the first concave hole 16, the large impeller 2 is used for providing an installation carrier for components such as a convex blade 6, and the like, a first groove 22 is arranged at the middle position of the left end and the right end of the large impeller 2, the first groove 22 is arranged on the large impeller 2, the production material quantity of the large impeller 2 is effectively reduced, a plurality of convex blades 6 which are circularly arranged are equidistantly arranged at the outer end of the large impeller 2, the convex blades 6 are attached to the inner wall of the first concave hole 16, the convex blades 6 are arranged on the large impeller 2, the large impeller 2 can rotate, a third groove is formed in the middle position of one end, away from the large impeller 2, of the convex blade 6, installation space is provided for a first reinforcing part by the third groove, the first reinforcing part is fixed in the third groove, the strength of the convex blade 6 is increased by the first reinforcing part, the first reinforcing part can be a rectangular plate 61, an additional wheel 3 is movably arranged in a second concave hole 17, the additional wheel 3 is attached to the upper end of the large impeller 2, second grooves 32 are formed in the middle positions of the left end and the right end of the additional wheel 3, the second groove 32 is formed in the additional wheel 3, the production material quantity of the additional wheel 3 is reduced, a plurality of concave tooth holes 4 which are circularly arranged and matched with the convex blade 6 are formed in the outer end of the additional wheel 3 at equal intervals, the convex blade 6 is matched with the concave tooth holes 4 for use, energy transfer operation is realized, an air inlet hole 7 is formed in the rear side of the left end of the base 1, and the air inlet hole 7 is communicated with the first concave hole 16, utilize inlet port 7 to carry high-pressure gas in first shrinkage pool 16, inlet port 7 sets up in the position rear side of attaching movable wheel 3 and big impeller 2 laminating position, and base 1 left end front side processing venthole 8 and venthole 8 communicate with first shrinkage pool 16, utilize venthole 8 to discharge high-pressure gas, and venthole 8 sets up in attaching movable wheel 3 and big impeller 2 laminating position front side.

Specifically, a large impeller 2 is arranged in a first concave hole 16, a plurality of convex blades 6 are arranged at the outer end of the large impeller 2, and the convex blades 6 are attached to the inner wall of the first concave hole 16, so that a plurality of cavities which are equidistantly and circularly arranged are formed in the first concave hole 16 by utilizing the large impeller 2, the plurality of convex blades 6 and a cover plate 5, a circularly-appearing closed cavity is formed between the occlusion part of the large impeller 2 and an additional impeller 3 and one convex blade 6 which is closest to the occlusion part on the large impeller 2, the convex blade 6 on the large impeller 2 can move away from the occlusion part when high-pressure gas is input into an air inlet 7 in the cavity, and high-speed clockwise rotation is realized, and the convex blades 6 on the large impeller 2 can be continuously engaged with the concave tooth holes 4 of the additional impeller 3, so that the additional impeller 3 rotates, the potential energy of the high-pressure gas is directly converted into mechanical energy of the rotation of the additional impeller 3, and the high-speed high-energy-driving device can be applied to rotary machines such as engines, generators and pneumatic devices.

As shown in fig. 1, fig. 2, fig. 4 and fig. 5, the middle position of the bottom end inside the first concave hole 16 is rotatably connected to the first rotating shaft 21, the outer end of the first rotating shaft 21 fixes the large impeller 2, the first rotating shaft 21 penetrates through the cover plate 5 and is rotatably connected to the cover plate 5 through the sealing bearing, the middle position of the bottom end inside the second concave hole 17 is rotatably connected to the second rotating shaft 31, the outer end of the second rotating shaft 31 fixes the additional wheel 3, the second rotating shaft 31 provides the mounting carrier for the additional wheel 3, and the second rotating shaft 31 penetrates through the cover plate 5 and is rotatably connected to the cover plate 5 through the sealing bearing.

Specifically, the first rotating shaft 21 and the second rotating shaft 31 can be both provided with the load parts, so that the first rotating shaft 21 can rotate in the rotating process of the large impeller 2, and the large impeller 2 can rotate to rotate the additional wheel 3 under the matching action of the convex blades 6 and the concave tooth holes 4, so that the second rotating shaft 31 can rotate, the purpose of rotating the two load parts by using the first rotating shaft 21 and the second rotating shaft 31 is achieved, and the application of mechanical energy is realized.

Furthermore, it should be understood that although the present description refers to embodiments, not every embodiment may contain only a single embodiment, and such description is for clarity only, and those skilled in the art should integrate the description, and the embodiments may be combined as appropriate to form other embodiments understood by those skilled in the art.

Claims (7)

1. A novel energy transmission device for converting potential energy into mechanical energy is characterized in that: including base (1) and install apron (5) at base (1) right-hand member, base (1) right-hand member is seted up first shrinkage pool (16) and second shrinkage pool (17) and first shrinkage pool (16) and second shrinkage pool (17) are in apron (5) left end, first shrinkage pool (16) intercommunication sets up on second shrinkage pool (17) lower extreme, movable mounting impeller (2) in first shrinkage pool (16), impeller (2) outer end equidistance sets up and is a plurality of convex blade (6) and convex blade (6) laminating of circular arrangement on first shrinkage pool (16) inner wall, second shrinkage pool (17) internalization sets up and attaches driving wheel (3) and attach driving wheel (3) laminating in impeller (2) upper end, attach driving wheel (3) equidistance sets up and is a plurality of circular arrangement and concave tooth hole (4) that the laminating of convex blade (6) used with, base (1) left end rear end sets up and attaches driving wheel (7) and shrinkage pool (7) and first shrinkage pool (16) intercommunication base (7) front side inlet port (8) and the processing impeller (2) front end position inlet port (8) and concave hole (8) and concave tooth (2) and concave hole (8) and concave wheel (2) front end laminating are set up the concave tooth hole (8) and attach driving wheel (3) and attach driving wheel (8) rear end, base (8) front end intercommunication .

2. A novel energy transfer device for converting potential energy into mechanical energy, as claimed in claim 1, wherein: first shrinkage pool (16) inside bottom intermediate position rotates and connects first pivot (21) and the fixed big impeller (2) of first pivot (21) outer end, first pivot (21) run through apron (5) and rotate through sealed bearing and apron (5) and be connected, second pivot (31) and the fixed driving wheel (3) that attaches of second pivot (31) and second pivot (31) outer end are rotated to inside bottom intermediate position of second shrinkage pool (17), second pivot (31) run through apron (5) and rotate through sealed bearing and apron (5) and be connected.

3. A novel energy transfer device for converting potential energy into mechanical energy, as defined in claim 1, wherein: first grooves (22) are formed in the middle positions of the left end and the right end of the large impeller (2), and second grooves (32) are formed in the middle positions of the left end and the right end of the attached driving wheel (3).

4. A novel energy transfer device for converting potential energy into mechanical energy, as defined in claim 1, wherein: and a third groove is formed in the middle of one end, deviating from the large impeller (2), of the convex blade (6), and a first reinforcing piece is fixed in the third groove.

5. A novel energy transfer device for converting potential energy into mechanical energy, as defined in claim 1, wherein: base (1) right-hand member both sides edge position all sets up breach groove (14) and extends to base (1) outward end, breach groove (14) set up at apron (5) left end, two first through-holes (15) are seted up to the inside left wall symmetry in breach groove (14), four edges and corners positions of apron (5) right-hand member all process second through-hole and second through-hole central line and first through-hole (15) central line coincide and be in the same place.

6. A novel energy transfer device for converting potential energy into mechanical energy, as defined in claim 5, wherein: the second reinforcing part is arranged in the notch groove (14) and is positioned at the left end of the cover plate (5), and the second reinforcing part is arranged between the two first through holes (15) in the corresponding notch groove (14).

7. A novel energy transfer device for converting potential energy into mechanical energy, as defined in claim 6, wherein: a plurality of first positioning columns (11) are installed at the left end of the second reinforcing part at equal intervals, the first positioning columns (11) are located in first positioning holes formed in the base (1), a plurality of second positioning columns (13) are arranged at the right end of the second reinforcing part at equal intervals, the second positioning columns (13) are located in second positioning holes machined in the cover plate (5).

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