CN210484539U - Energy-saving transmission mechanical device - Google Patents

Abstract

The utility model discloses an energy-conserving transmission mechanical device, include: the device comprises an outer shell, an inner gear ring, a planetary gear ring, a lever support general bearing, a central power general shaft, a first sliding shaft, an auxiliary lever arm, a pressure device and a pushing arm; an inner gear ring is arranged in the middle of the inner side of the outer shell; a sliding plate is arranged between the inner gear ring and the outer shell, and a track groove is formed between the inner gear ring and the outer shell; a planetary gear ring is arranged on the inner side of the internal gear ring; the planetary gear ring is connected with the track groove through a lever support assembly; an auxiliary lever arm is arranged on one side of the planetary gear rim; the auxiliary lever arm is connected with the lever support assembly through a loose pin; a central power main shaft is arranged in the planetary gear rim; a pushing arm and a pressure device are respectively arranged on the central power main shaft; the front end of the pressure device is vertically propped against the center of the auxiliary lever arm. The device has stable and reliable running performance, saves input force, has high working efficiency and can be widely applied to mechanical transmission of various power machines.

Description

Energy-saving transmission mechanical device

Technical Field

The utility model belongs to the technical field of mechanical transmission equipment technique and specifically relates to an energy-conserving transmission mechanical device is related to.

Background

The energy is the natural and big thing of all mankind, and the customs livelihood is happy and comfortable and well-being, and the customs country is beautiful and rich. Since the introduction of human beings into the scientific society, the demand for energy has been increasing. The pollution of a large amount of non-renewable energy to the environment is increased continuously, the global natural environment and the bad climate change are influenced, and the living quality of human beings is influenced. Therefore, the search for clean energy is urgent. The utilization of inexhaustible lever energy and super-strong steel rigidity energy is a natural science besieged for human beings. It has long been known that lever energy and super-strong rigidity energy are inexhaustible energy in the generations of human beings. Mankind strives to innovate various energy-saving equipment of utility model for better energy saving, and insist on constantly to the energy-conserving environmental protection technological problem and send out new round of high-tech challenge again.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy-conserving transmission mechanical device.

To achieve the above object, the present invention adopts the following:

an energy efficient transmission mechanism comprising: the device comprises an outer shell, an inner gear ring, a planetary gear ring, a lever support general bearing, a central power general shaft, a first sliding shaft, an auxiliary lever arm, a pressure device and a pushing arm; an inner gear ring is arranged in the middle of the inner side of the outer shell; a sliding plate is arranged between the inner gear ring and the outer shell, and a track groove is formed between the inner gear ring and the outer shell; a planetary gear ring is arranged on the inner side of the inner gear ring; the planetary gear ring is connected with the track groove through a lever support assembly; an auxiliary lever arm is arranged on one side of the planetary gear ring and is in sliding connection with the planetary gear ring through a first sliding shaft; the auxiliary lever arm is connected with the lever support assembly through a loose pin; a central power main shaft is arranged in the planetary gear ring; a pushing arm and a pressure device are respectively arranged on the central power main shaft; the pushing arm and the lever support assembly are fixed through a loose pin; the front end of the pressure device is vertically propped against the center of the auxiliary lever arm.

Preferably, the lever support assembly comprises a first short shaft group, a second short shaft group and a connecting plate; the first short shaft group is arranged inside the planetary gear ring and is in sliding connection with the inner side wall of the planetary gear ring; the second short shaft group is arranged on the sliding plate and is in sliding connection with the inner side wall of the outer shell and the outer side wall of the inner gear ring; the connecting plates are respectively fixed on the first short shaft group and the second short shaft group.

Preferably, the number of the short shafts in the first short shaft group is not less than two; the number of the short shafts in the second short shaft group is not less than two.

Preferably, the pressure device is a hydraulic cylinder.

Preferably, the pressure means is a bolt.

Preferably, the device also comprises an outer tension plate and a second sliding shaft; the second sliding shaft is arranged in a track groove formed by the outer shell and the inner gear ring and is in sliding connection with the inner side wall of the outer shell and the outer side wall of the inner gear ring; an outer tension plate is arranged on the outer side of the second sliding shaft; the outer tension plate and the auxiliary lever arm are fixed through a tension bolt.

Preferably, the outer tension plate is fan-shaped and tangent to the inner side wall of the outer shell.

Preferably, the circle center of the inner gear ring and the circle center of the planetary gear ring are close to the same point.

Preferably, the center of the central power main shaft is close to the same point with the center of the planetary gear ring.

Preferably, the lateral width of the outer case is wider than the lateral width of the ring gear.

The utility model has the advantages of it is following:

the device has the advantages of reasonable design, novel form, simple structure and stable and reliable running performance, reduces the cost of materials, processing and transmission, saves the input force, improves the transmission efficiency and can be widely applied to the mechanical transmission of various power machines.

Drawings

The following describes embodiments of the present invention in further detail with reference to the accompanying drawings.

Fig. 1 is a first structural schematic diagram of an energy-saving transmission mechanical device of the present invention.

Fig. 2 is a second structural schematic diagram of the energy-saving transmission mechanism of the present invention.

In the figures, the various reference numbers are:

the device comprises a shell 1, an inner gear ring 2, a planetary gear ring 3, a lever support assembly 4, a short shaft group 41, a short shaft group 42, a short shaft group II, a connecting plate 43, a central power assembly shaft 5, a sliding shaft 6, an auxiliary lever arm 7, a sliding shaft 8, a bolt 9, a pressure device 10, a pushing arm 11, an outer tension plate 12 and a sliding plate 13.

Detailed Description

In order to illustrate the invention more clearly, the invention is further described below with reference to preferred embodiments. It is to be understood by persons skilled in the art that the following detailed description is illustrative and not restrictive, and is not to be taken as limiting the scope of the invention.

As shown in fig. 1 and 2, an energy saving transmission mechanism includes: the device comprises an outer shell 1, an inner gear ring 2, a planetary gear ring 3, a lever support general bearing 4, a central power general shaft 5, a first sliding shaft 6, an auxiliary lever arm 7, a pressure device 10 and a thrust arm 11; an inner gear ring 2 is arranged in the middle of the inner side of the outer shell 1; a sliding plate 13 is arranged between the inner gear ring 2 and the outer shell 1, and a track groove is formed between the inner gear ring 2 and the outer shell 1; a planetary gear ring 3 is arranged on the inner side of the inner gear ring 2; the planetary gear ring 3 is connected with the track groove through a lever support assembly 4; a lever arm 7 is arranged on one side of the planetary gear ring 3, and the lever arm 7 is connected with the planetary gear ring 3 in a sliding mode through a first sliding shaft 6; the auxiliary lever arm 7 is connected with the lever support assembly 4 through a loose pin; a central power main shaft 5 is arranged inside the planetary gear ring 3; a pushing arm 11 and a pressure device 10 are respectively arranged on the central power main shaft 5; the pushing arm 11 and the lever support assembly 4 are fixed through a loose pin; the front end of the pressure device 10 vertically abuts against the center of the auxiliary lever arm 7.

Further, the lever support assembly 4 comprises a first short shaft group 41, a second short shaft group 42 and a connecting plate 43; the first short shaft group 41 is arranged inside the planetary gear ring 3 and is in sliding connection with the inner side wall of the planetary gear ring 3; the second short shaft group 42 is arranged on the sliding plate 13 and is in sliding connection with the inner side wall of the outer shell 1 and the outer side wall of the inner gear ring 2; the connecting plates 43 are respectively fixed on the first stub shaft group 41 and the second stub shaft group 42.

Further, the number of the short axes in the first short axis group 41 is not less than two; the number of the short shafts in the second short shaft group 42 is not less than two.

Further, the pressure device 10 is a hydraulic cylinder; the hydraulic cylinder is arranged on the central power main shaft 5, when in use, the front end of the hydraulic cylinder is propped against the center of the auxiliary lever arm 7 by adjusting the force of the hydraulic cylinder, and the propping force of the hydraulic cylinder is vertical to the center of the inner tooth surface of the planetary gear ring 3.

Further, the pressure device 10 is a bolt; the bolt is arranged on the central power main shaft 5 and is in threaded connection with the central power main shaft 5, when the device is used, the position of the bolt is adjusted at first, the front end of the bolt is enabled to be propped against the center of the auxiliary lever arm 7, the propping force of the bolt is perpendicular to the center of the inner tooth surface of the planetary gear ring 3, and after the bolt is adjusted, the device is started.

Further, the device also comprises an outer tension plate 12 and a second sliding shaft 8; the second sliding shaft 8 is arranged in a track groove formed by the outer shell 1 and the inner gear ring 2 and is in sliding connection with the inner side wall of the outer shell 1 and the outer side wall of the inner gear ring 2; an outer tension plate 12 is arranged on the outer side of the second sliding shaft 8; the outer tension plate 12 and the auxiliary lever arm 7 are fixed through a tension bolt 9; when the pressure device 10 is not arranged on the central power main shaft 5, the outer tension plate 12 is arranged, the outer tension plate 12 is connected with the auxiliary lever arm 7 through the tension bolt 9, and the outer tension plate 12 has outward tension on the auxiliary lever arm 7 by tightening the tension bolt 9, so that the resistance is reduced.

Further, the outer tension plate 12 is fan-shaped and tangent to the inner side wall of the outer shell 1, so that the outer tension plate 12 can slide on the inner side wall of the outer shell 1 conveniently.

Furthermore, the circle center of the inner gear ring 2 and the circle center of the planetary gear ring 3 are close to the same point.

Further, the center of the central power main shaft 5 is close to the same point with the center of the planetary gear ring 3.

Further, the lateral width of the outer housing 1 is wider than the lateral width of the ring gear 2.

When the device is used, firstly, the device is in mechanical transmission connection with external equipment, then the pressure adjusting device 10 is pressed against the auxiliary lever arm 7, then the central power main shaft 5 is started to rotate, and simultaneously the pushing arm 11 is driven to rotate to drive the lever support general scale 4 to rotate, so that the external equipment is driven to rotate; through setting up the auxiliary lever arm 7, can reduce the running resistance of this device, through very little power, can drive the operation of this device.

Obviously, the above embodiments of the present invention are only examples for clearly illustrating the present invention, and are not intended to limit the embodiments of the present invention, and it is obvious for those skilled in the art to make other variations or changes based on the above descriptions, and all the embodiments cannot be exhausted here, and all the obvious variations or changes that belong to the technical solutions of the present invention are still in the protection scope of the present invention.

Claims (10)

1. An energy efficient transmission mechanism, comprising: the device comprises an outer shell, an inner gear ring, a planetary gear ring, a lever support general bearing, a central power general shaft, a first sliding shaft, an auxiliary lever arm, a pressure device and a pushing arm; an inner gear ring is arranged in the middle of the inner side of the outer shell; a sliding plate is arranged between the inner gear ring and the outer shell, and a track groove is formed between the inner gear ring and the outer shell; a planetary gear ring is arranged on the inner side of the inner gear ring; the planetary gear ring is connected with the track groove through a lever support assembly; an auxiliary lever arm is arranged on one side of the planetary gear ring and is in sliding connection with the planetary gear ring through a first sliding shaft; the auxiliary lever arm is connected with the lever support assembly through a loose pin; a central power main shaft is arranged in the planetary gear ring; a pushing arm and a pressure device are respectively arranged on the central power main shaft; the pushing arm and the lever support assembly are fixed through a loose pin; the front end of the pressure device is vertically propped against the center of the auxiliary lever arm.

2. The energy-saving transmission mechanical device is characterized in that the lever support assembly comprises a first short shaft group, a second short shaft group and a connecting plate; the first short shaft group is arranged inside the planetary gear ring and is in sliding connection with the inner side wall of the planetary gear ring; the second short shaft group is arranged on the sliding plate and is in sliding connection with the inner side wall of the outer shell and the outer side wall of the inner gear ring; the connecting plates are respectively fixed on the first short shaft group and the second short shaft group.

3. An energy saving transmission mechanism as claimed in claim 2 wherein the number of short shafts in said first set is not less than two; the number of the short shafts in the second short shaft group is not less than two.

4. An energy efficient transmission mechanism as claimed in claim 1 wherein said pressure means is a hydraulic cylinder.

5. An energy efficient transmission mechanism as claimed in claim 1 wherein said pressure means is a bolt.

6. The energy saving transmission mechanical device as claimed in claim 1, further comprising an outer tension plate and a second sliding shaft; the second sliding shaft is arranged in a track groove formed by the outer shell and the inner gear ring and is in sliding connection with the inner side wall of the outer shell and the outer side wall of the inner gear ring; an outer tension plate is arranged on the outer side of the second sliding shaft; the outer tension plate and the auxiliary lever arm are fixed through a tension bolt.

7. An energy saving drive mechanism as claimed in claim 6 wherein said outer tension plate is fan shaped and tangent to the inner side wall of the outer housing.

8. An energy saving drive mechanism as claimed in claim 1 wherein the centre of the annulus gear is close to the same point as the centre of the planet gear ring.

9. An energy efficient transmission mechanism as claimed in claim 1 wherein the centre of the central power shaft is located at the same point as the centre of the planet gear ring.

10. An energy saving transmission mechanism as claimed in claim 1 wherein the lateral width of the outer housing is wider than the lateral width of the inner gear ring.

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