CN110873126A

CN110873126A - Buffer coupling

Info

Publication number: CN110873126A
Application number: CN201911086606.0A
Authority: CN
Inventors: 钱雪松
Original assignee: Changzhou Campus of Hohai University
Current assignee: Changzhou Campus of Hohai University
Priority date: 2019-11-08
Filing date: 2019-11-08
Publication date: 2020-03-10

Abstract

The invention discloses a buffer coupling, which comprises a driving shaft, an intermediate shaft sleeve, a porous metal pipe fitting, a screw, a driven shaft spline sleeve and a driven shaft, wherein the intermediate shaft is fixedly connected with the intermediate shaft sleeve; the porous metal pipe fitting is precompressed at the original position and used for balancing the limit transmission torque of the mechanism, when the porous metal pipe fitting is subjected to the action of impact torque, the porous metal pipe fitting is further compressed to generate axial displacement, and corresponding to circumferential rotation motion, a rotation speed difference is generated between the driven shaft and the driving shaft, the transmission time of the impact torque is prolonged, the peak value of the impact torque is reduced, and the safety of the transmission shaft and each part in a transmission system is effectively protected.

Description

Buffer coupling

Technical Field

The invention relates to a buffering coupler, and belongs to the technical field of machinery.

Background

The coupling belongs to a mechanical universal part and is a mechanical part which is used for connecting a driving shaft and a driven shaft in different mechanisms and enabling the driving shaft and the driven shaft to rotate together to transmit torque. The existing coupling rigidly connects the driving shaft and the driven shaft, but when the driving shaft is started, the driving shaft can generate impact load due to the action of inertia load of the driven part connected with the driven shaft, so that a large impact moment is formed, and in addition, when the driven part connected with the driven shaft is subjected to the action of the impact load, the rigid connection between the driving shaft and the driven shaft can also form a large impact moment. Easily causing damage to the coupling or related transmission components.

Disclosure of Invention

In order to overcome the defects, the invention provides a buffer coupling, which adopts the technical scheme as follows:

a buffer coupling comprises a driving shaft, an intermediate shaft sleeve, a porous metal pipe fitting, a screw, a driven shaft spline sleeve and a driven shaft;

a spline is processed on the outer surface of the left end cylinder of the driving shaft to form a driving shaft spline shaft; the middle shaft comprises a middle shaft first shaft table, a middle shaft second shaft table, a middle shaft third shaft table and a porous metal pipe guide post; spline grooves are processed in the first shaft platform of the intermediate shaft to form an internal spline of the intermediate shaft, the spline shaft of the driving shaft is inserted into the internal spline of the intermediate shaft to form sliding fit, and the intermediate shaft moves axially relative to the driving shaft; the right end of the intermediate shaft second shaft platform is connected with the intermediate shaft first shaft platform, the left end of the intermediate shaft second shaft platform is connected with the right end of the intermediate shaft third shaft platform, and a multi-head spiral line is processed on the circumferential outer surface of the intermediate shaft second shaft platform to form an intermediate shaft spiral line; the left end of the third pillow block of the intermediate shaft is connected with the right end of the porous metal pipe guide post;

the inner side of the right side of the middle shaft sleeve is provided with a multi-start helical line to form a helical line in the middle shaft sleeve, the helical line in the middle shaft sleeve and the helical line of the middle shaft are mutually screwed to form thread transmission, and the helical line of the middle shaft realizes axial movement while forming rotation in the helical line in the middle shaft sleeve;

a spline is processed on the outer surface of a right-end cylinder of the driven shaft to form a driven shaft spline shaft; the driven shaft spline housing comprises a driven shaft spline housing first shaft platform, a driven shaft spline housing second shaft platform and a driven shaft spline housing third shaft platform; a cylindrical hole is processed in the right end of the spline housing first boss of the driven shaft to form a porous metal pipe fitting seat, and a porous metal pipe fitting guide pillar can be inserted into the porous metal pipe fitting seat; the driven shaft spline housing first boss is inserted into the inner hole at the left end of the middle shaft sleeve, and the circumferential outer surface of the driven shaft spline housing first boss is matched with the inner hole at the left end of the middle shaft sleeve; the driven shaft spline housing second shaft platform forms an installation flange of a driven shaft spline housing, the driven shaft spline housing second shaft platform and the middle shaft sleeve form reliable connection through screws, and a driven shaft spline housing internal spline is processed inside the driven shaft spline housing third shaft platform; the driven shaft spline shaft and the driven shaft spline sleeve internal spline are in tight and reliable connection;

the porous metal pipe fitting is sleeved on the porous metal pipe fitting guide column, the left end of the porous metal pipe fitting is abutted against the porous metal pipe fitting seat, and the right end of the porous metal pipe fitting is abutted against the third pillow block of the intermediate shaft. The porous metal pipe fitting is formed by processing a plurality of through holes on the metal pipe fitting and adjusting the elastic coefficient of the metal pipe fitting.

The invention achieves the following beneficial effects:

the porous metal pipe fitting of the invention is pre-compressed in the original position for balancing the rated torque of the buffer coupling. In the starting process of the driving shaft, under the action of inertial load of a driven part connected with the driven shaft, the driving shaft can form starting torque far larger than rated torque of the buffer coupling, the driving shaft drives the intermediate shaft to rotate through the driving shaft spline shaft and the intermediate shaft internal spline, screwing transmission is generated between the internal spiral line of the intermediate shaft sleeve and the intermediate shaft spiral line to form axial compression force larger than precompression force of the porous metal pipe fitting, the intermediate shaft further compresses the porous metal pipe fitting through the left end step of the intermediate shaft third shaft platform, meanwhile, the intermediate shaft generates axial movement towards the left of the driving shaft through sliding fit formed between the internal spline of the intermediate shaft and the driving shaft spline shaft, at the moment, the compression force borne by the porous metal pipe fitting is balanced with the axial force formed by screwing between the internal spiral line of the intermediate shaft sleeve and the intermediate shaft spiral, the axial displacement is generated due to the screwing transmission generated between the inner spiral line of the intermediate shaft sleeve and the spiral line of the intermediate shaft, and the rotation speed difference is generated between the driven shaft and the driving shaft corresponding to the circumferential rotation motion, so that the transmission time of the impact torque is prolonged, the peak value of the starting torque is reduced, and the safety of the transmission shaft and each part in a transmission system is effectively protected; when the driven shaft and the driven part connected with the driven shaft are driven by the driving shaft, the rotating speed is gradually improved, the inertia moment is gradually reduced, the working torque of the buffer coupling is also gradually reduced, the middle shaft generates relative rotation between the spiral line in the middle shaft sleeve and the spiral line of the middle shaft under the action of the axial compression force of the porous metal pipe fitting, meanwhile, the middle shaft generates axial movement towards the right side relative to the driving shaft through the sliding fit formed between the internal spline of the middle shaft and the spline shaft of the driving shaft, the right end step of the third shaft platform of the middle shaft gradually approaches to the left side of the inner side of the right end of the middle shaft sleeve, and at the moment, the axial compression force applied to the porous metal pipe fitting and the axial force formed by the; when the working torque of the buffer coupling is equal to or smaller than the rated torque, the right end step of the third pillow block of the intermediate shaft gradually abuts against the left side of the inner side of the right end of the intermediate shaft sleeve, and at the moment, the axial compression force applied to the porous metal pipe fitting is equal to the original pre-compression force; when the driven part connected with the driven shaft is acted by impact torque and the impact torque is larger than the rated torque of the buffer coupling, the driven shaft and the driven part connected with the driven shaft drive the middle shaft sleeve to slow down the rotation speed through the driven shaft spline shaft and the driven shaft spline sleeve inner spline, the screwing transmission is generated between the middle shaft sleeve inner spiral line and the middle shaft spiral line to form axial compression force larger than the precompression force of the porous metal pipe fitting, the middle shaft further compresses the porous metal pipe fitting through the left end step of the middle shaft third shaft platform, meanwhile, the middle shaft generates axial movement leftwards relative to the driving shaft through the sliding fit formed between the middle shaft inner spline and the driving shaft spline shaft, at the moment, the compression force applied to the porous metal pipe fitting and the impact torque applied to the driven shaft are balanced through the axial force formed by the screwing between, in the process, due to the fact that the spiral line in the middle shaft sleeve and the spiral line of the middle shaft are in screwing transmission, axial displacement is generated, corresponding to circumferential rotation motion, rotation speed difference is generated between the driven shaft and the driving shaft, transmission time of impact torque is prolonged, peak value of the impact torque is reduced, and safety of parts in the transmission shaft and the transmission system is effectively protected.

Drawings

Fig. 1 is a schematic structural view of the present invention.

Detailed Description

The invention is further described below with reference to the accompanying drawings. The following examples are only for illustrating the technical solutions of the present invention more clearly, and the protection scope of the present invention is not limited thereby.

As shown in fig. 1, a buffer coupling comprises a driving shaft 1, an intermediate shaft 2, an intermediate shaft sleeve 3, a porous metal pipe fitting 4, a screw 5, a driven shaft spline housing 6 and a driven shaft 7;

a spline is processed on the outer surface of a cylinder at the left end of the driving shaft 1 to form a driving shaft spline shaft 1-1; the middle shaft 2 comprises a middle shaft first shaft table 2-1, a middle shaft second shaft table 2-3, a middle shaft third shaft table 2-5 and a porous metal pipe guide post 2-6; spline grooves are processed in the first pillow block 2-1 of the intermediate shaft to form an internal spline 2-2 of the intermediate shaft, the spline shaft 1-1 of the driving shaft is inserted into the internal spline 2-2 of the intermediate shaft and forms sliding fit, and the intermediate shaft 2 axially moves relative to the driving shaft 1; the right end of the intermediate shaft second shaft platform 2-3 is connected with the right end of an intermediate shaft first shaft platform 2-1, the left end of the intermediate shaft second shaft platform is connected with the right end of an intermediate shaft third shaft platform 2-5, and a multi-head spiral line is processed on the circumferential outer surface of the intermediate shaft second shaft platform 2-3 to form an intermediate shaft spiral line 2-4; the left end of the middle shaft third shaft platform 2-5 is connected with the right end of the porous metal pipe fitting guide post 2-6;

a multi-start spiral line is processed on the inner side of the right side of the middle shaft sleeve 3 to form a middle shaft sleeve inner spiral line 3-1, the middle shaft sleeve inner spiral line 3-1 and the middle shaft spiral line 2-4 are mutually screwed to form thread transmission, and the middle shaft spiral line 2-4 rotates in the middle shaft sleeve inner spiral line 3-1 and simultaneously realizes axial movement;

a spline is processed on the outer surface of a right-end cylinder of the driven shaft 7 to form a driven shaft spline shaft 7-1; the driven shaft spline housing 6 comprises a driven shaft spline housing first shaft platform 6-1, a driven shaft spline housing second shaft platform 6-3 and a driven shaft spline housing third shaft platform 6-4; a cylindrical hole is processed in the right end of the spline housing first boss 6-1 of the driven shaft to form a porous metal pipe fitting seat 6-2, and a guide pillar 2-6 of the porous metal pipe fitting can be inserted into the porous metal pipe fitting seat 6-2; the driven shaft spline housing first boss 6-1 is inserted into the inner hole at the left end of the middle shaft sleeve 3, and the circumferential outer surface of the driven shaft spline housing first boss 6-1 is matched with the inner hole at the left end of the middle shaft sleeve 3; the driven shaft spline housing second shaft platform 6-3 forms an installation flange of the driven shaft spline housing 6, the driven shaft spline housing second shaft platform 6-3 and the middle shaft sleeve 3 are reliably connected through a screw 5, and a driven shaft spline housing internal spline 6-5 is machined inside the driven shaft spline housing third shaft platform 6-4; the driven shaft spline shaft 7-1 and the driven shaft spline sleeve internal spline 6-5 are in tight and reliable connection;

the porous metal pipe fitting 4 is sleeved on the porous metal pipe fitting guide post 2-6, the left end of the porous metal pipe fitting 4 abuts against the porous metal pipe fitting seat 6-2, and the right end of the porous metal pipe fitting 4 abuts against the third pillow block 2-5 of the middle shaft. The porous metal pipe 4 is formed by processing a plurality of through holes on the metal pipe to adjust the elastic coefficient of the metal pipe.

The perforated metal tube 4 of the invention is pre-compressed in the home position for balancing the nominal torque of the damping coupling. In the starting process of the driving shaft 1, due to the effect of inertia load of a driven part connected with a driven shaft 7, the driving shaft 1 can form starting torque far larger than the rated torque of the buffer coupling, the driving shaft 1 drives the intermediate shaft to rotate through the driving shaft spline shaft 1-1 and the intermediate shaft inner spline 2-2, screwing transmission is generated between the spiral line 3-1 in the intermediate shaft sleeve and the intermediate shaft spiral line 2-4 to form axial compression force larger than the precompression force of the porous metal pipe fitting 4, the intermediate shaft 2 further compresses the porous metal pipe fitting 4 through the left end step of the intermediate shaft third shaft platform 2-5, meanwhile, the intermediate shaft 2 generates axial movement leftwards relative to the driving shaft 1 through sliding fit formed between the intermediate shaft inner spline 2-2 and the driving shaft spline shaft 1-1, and at the moment, the compression force borne by the porous metal pipe fitting 4 and the starting torque of the driving shaft 1 The axial force formed by screwing the shaft spiral lines 2-4 is balanced, in the process, the axial displacement is generated due to the screwing transmission generated between the spiral line 3-1 in the middle shaft sleeve and the spiral line 2-4 of the middle shaft, and the rotation speed difference is generated between the driven shaft 7 and the driving shaft 1 corresponding to the circumferential rotation motion, so that the transmission time of the impact torque is prolonged, the peak value of the starting torque is reduced, and the safety of the transmission shaft and each part in a transmission system is effectively protected; when the driven shaft 7 and the driven part connected with the driven shaft are driven by the driving shaft 1, the rotating speed is gradually increased, the inertia moment is gradually reduced, the working moment of the buffer coupling is also gradually reduced, the middle shaft 2 generates relative rotation between the spiral line 3-1 in the middle shaft sleeve and the spiral line 2-4 of the middle shaft under the action of the axial compression force of the porous metal pipe fitting 4, meanwhile, the intermediate shaft 2 generates rightward axial movement relative to the driving shaft 1 through sliding fit formed between the intermediate shaft internal spline 2-2 and the driving shaft spline shaft 1-1, a right end step of an intermediate shaft third shaft platform 2-5 gradually approaches to the left side of the inner side of the right end of the intermediate shaft 2 sleeve, and at the moment, axial compression force borne by the porous metal pipe fitting 4 and axial force formed by screwing of the intermediate shaft sleeve inner spiral line 3-1 and the intermediate shaft spiral line 2-4 are balanced; when the working torque of the buffer coupling is equal to or less than the rated torque, the right end step of the middle shaft third platform 2-5 gradually abuts against the left side of the inner side of the right end of the middle shaft sleeve 3, and at the moment, the axial compression force applied to the porous metal pipe fitting 4 is equal to the original pre-compression force; when a driven part connected with a driven shaft 7 is subjected to the action of impact torque and the impact torque is larger than the rated torque of the buffer coupling, the driven shaft 7 and the driven part connected with the driven shaft drive the middle shaft sleeve 3 to reduce the rotating speed through the driven shaft spline shaft 7-1 and the driven shaft spline sleeve 6 inner spline, the spiral line 3-1 in the middle shaft sleeve and the middle shaft spiral line 2-4 are in screwing transmission to form axial compression force larger than the precompression force of the porous metal pipe fitting 4, the middle shaft 2 further compresses the porous metal pipe fitting 4 through the left end step of the middle shaft third shaft platform 2-5, meanwhile, the middle shaft 2 generates axial movement towards the left relative to the driving shaft 1 through the sliding fit formed between the middle shaft inner spline 2-2 and the driving shaft spline shaft 1-1, and at the moment, the compression force applied to the porous metal pipe fitting 4 and the impact torque applied to the driven shaft The axial force formed by screwing the spiral lines 2-4 is balanced, in the process, the spiral lines 3-1 in the middle shaft sleeve and the spiral lines 2-4 of the middle shaft sleeve are in screwing transmission to generate axial displacement, and the axial displacement corresponds to circumferential rotation motion, so that a rotation speed difference is generated between the driven shaft 7 and the driving shaft 1, the transmission time of impact torque is prolonged, the peak value of the impact torque is reduced, and the safety of each part in a transmission shaft and a transmission system is effectively protected.

The above description is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, several modifications and variations can be made without departing from the technical principle of the present invention, and these modifications and variations should also be regarded as the protection scope of the present invention.

Claims

1. A buffer coupling is characterized by comprising a driving shaft (1), an intermediate shaft (2), an intermediate shaft sleeve (3), a porous metal pipe fitting (4), a screw (5), a driven shaft spline sleeve (6) and a driven shaft (7);

a spline is processed on the outer surface of a cylinder at the left end of the driving shaft (1) to form a driving shaft spline shaft (1-1); the middle shaft (2) comprises a first middle shaft platform (2-1), a second middle shaft platform (2-3), a third middle shaft platform (2-5) and a porous metal pipe guide post (2-6); spline grooves are processed in the first pillow block (2-1) of the intermediate shaft to form an intermediate shaft internal spline (2-2), the driving shaft spline shaft (1-1) is inserted into the intermediate shaft internal spline (2-2) and forms sliding fit, and the intermediate shaft (2) axially moves relative to the driving shaft (1); the right end of the intermediate shaft second shaft platform (2-3) is connected with the intermediate shaft first shaft platform (2-1), the left end of the intermediate shaft second shaft platform is connected with the right end of the intermediate shaft third shaft platform (2-5), and a multi-head spiral line is processed on the circumferential outer surface of the intermediate shaft second shaft platform (2-3) to form an intermediate shaft spiral line (2-4); the left end of the third pillow block (2-5) of the middle shaft is connected with the right end of the porous metal pipe guide post (2-6);

the inner side of the right side of the middle shaft sleeve (3) is processed with a multi-start helical line to form a helical line (3-1) in the middle shaft sleeve, the helical line (3-1) in the middle shaft sleeve and the helical line (2-4) of the middle shaft sleeve are mutually screwed to form thread transmission, and the helical line (2-4) of the middle shaft realizes axial movement while forming rotation in the helical line (3-1) in the middle shaft sleeve;

a spline is processed on the outer surface of a right-end cylinder of the driven shaft (7) to form a driven shaft spline shaft (7-1);

the driven shaft spline housing (6) comprises a driven shaft spline housing first shaft platform (6-1), a driven shaft spline housing second shaft platform (6-3) and a driven shaft spline housing third shaft platform (6-4); a cylindrical hole is processed in the right end of the spline housing first boss (6-1) of the driven shaft to form a porous metal pipe fitting seat (6-2), and a porous metal pipe fitting guide pillar (2-6) can be inserted into the porous metal pipe fitting seat (6-2); the driven shaft spline housing first boss (6-1) is inserted into the inner hole at the left end of the middle shaft sleeve (3), and the circumferential outer surface of the driven shaft spline housing first boss (6-1) is matched with the inner hole at the left end of the middle shaft sleeve (3); the driven shaft spline housing second shaft platform (6-3) forms an installation flange of the driven shaft spline housing (6), the driven shaft spline housing second shaft platform (6-3) and the middle shaft sleeve (3) are reliably connected through a screw (5), and a driven shaft spline housing internal spline (6-5) is machined inside the driven shaft spline housing third shaft platform (6-4); the driven shaft spline shaft (7-1) and the driven shaft spline sleeve internal spline (6-5) are tightly and reliably connected;

the porous metal pipe fitting (4) is sleeved on the porous metal pipe fitting guide post (2-6), the left end of the porous metal pipe fitting is abutted against the porous metal pipe fitting seat (6-2), and the right end of the porous metal pipe fitting is abutted against the third pillow block (2-5) of the intermediate shaft.