CN107893823B

CN107893823B - Anti-lock clutch mechanism

Info

Publication number: CN107893823B
Application number: CN201711213504.1A
Authority: CN
Inventors: 翟自勇; 潘凯凯; 梁剑浩
Original assignee: Zhejiang Rifa Textile Machinery Co Ltd
Current assignee: Zhejiang Rifa Textile Machinery Co Ltd
Priority date: 2017-11-28
Filing date: 2017-11-28
Publication date: 2024-04-30
Anticipated expiration: 2037-11-28
Also published as: CN107893823A

Abstract

The invention belongs to the field of agricultural machinery equipment, and particularly relates to an anti-lock clutch mechanism which comprises a transplanting power output shaft and a swing rod shaft with a swing rod; the transplanting power output shaft is sequentially provided with a spring retainer ring, a pressure spring and a cam shaft sleeve from top to bottom, wherein the pressure spring can be abutted against the spring retainer ring and the cam shaft sleeve and can be abutted against the cam shaft sleeve to move up and down along the transplanting power output shaft; the cam shaft sleeve end is connected with a driving gear in a matched manner; the cam shaft sleeve is provided with a chute with depth decreasing along the circumferential direction, and the swing rod can be positioned in the chute and is abutted against the cam shaft sleeve. The invention has the advantages of simple design, convenient manufacture, low cost and the like.

Description

Anti-lock clutch mechanism

Technical Field

The invention belongs to the field of agricultural machinery equipment, and particularly relates to an anti-lock clutch mechanism.

Background

The vegetable seedling transplanting machine is a common agricultural machine equipment and can promote the improvement of agricultural production efficiency. The existing vegetable seedling transplanting machine has the defects of relatively complex structure, higher cost price and the like, so that the vegetable seedling transplanting machine cannot be popularized among farmers, and is inconvenient to popularize in the agricultural machinery industry; particularly, the clutch mechanism in the vegetable seedling transplanting machine with a complex structure is used, and the complexity of the whole mechanical structure of the vegetable seedling transplanting machine is improved. In order to solve the problems, the inventor provides an anti-lock clutch mechanism which is simple in design, convenient to manufacture and low in cost.

Disclosure of Invention

The invention aims to provide an anti-lock clutch mechanism which is simple in design, convenient to manufacture and low in cost, reduces the manufacturing cost of a vegetable seedling transplanting machine, improves the service efficiency of the clutch mechanism and prolongs the service life of the clutch mechanism.

In order to achieve the above purpose, the technical scheme provided by the invention specifically comprises the following steps: an anti-lock clutch mechanism comprises a transplanting power output shaft and a swing rod shaft with a swing rod; the transplanting power output shaft is sequentially provided with a spring retainer ring, a pressure spring and a cam shaft sleeve from top to bottom, wherein the pressure spring can be abutted against the spring retainer ring and the cam shaft sleeve and can be abutted against the cam shaft sleeve to move up and down along the transplanting power output shaft; the cam shaft sleeve end is connected with a driving gear in a matched manner; the cam shaft sleeve is provided with a chute with depth decreasing along the circumferential direction, and the swing rod can be positioned in the chute and is abutted against the cam shaft sleeve; the driving gear is provided with a driving gear bulge, the cam shaft sleeve is provided with a cam shaft sleeve bulge, and the driving gear bulge and the cam shaft sleeve bulge are mutually matched and connected; the driving gear bulge and the cam shaft sleeve bulge are meshed in an oblique angle curve.

The anti-lock clutch mechanism is further arranged, and the deepest end and the shallowest end of the depth of the chute are provided with stop blocks.

The anti-lock clutch mechanism is further arranged, a spline is arranged on the outer peripheral surface of the transplanting power output shaft, and the cam shaft sleeve is meshed with the spline and can vertically displace along the spline.

The working principle of the invention is as follows: according to the invention, the cam shaft sleeve is provided with the chute with the depth gradually decreasing along the circumferential direction, the swing rod can be abutted against the bottom of the chute when the cam shaft sleeve rotates, and the upward displacement of the cam shaft sleeve is realized along with the depth of the bottom of the chute from deep to shallow.

And moreover, the mechanical engagement boss is designed into an oblique angle curve engagement mode, and the force of mutual engagement is decomposed into a normal force and a tangential force, so that the locking phenomenon when the mechanical engagement is switched into a separated state is avoided, and the clutch switching failure is caused.

The invention has the following effects: the cam shaft sleeve is provided with the inclined groove with the depth decreasing along the circumferential direction, the swing rod can be positioned in the inclined groove and is abutted against the cam shaft sleeve, the cam shaft sleeve and the driving gear can be engaged and disengaged, the design is simple, the manufacturing is convenient, the cost is low, and the service efficiency and the service life of the engaging and disengaging mechanism are improved.

Drawings

FIG. 1 is a schematic diagram of the structure of the present invention; FIG. 2 is a schematic view of a cam sleeve according to the present invention; FIG. 3 is a schematic diagram of the connection between a cam sleeve and a drive gear according to the present invention.

Description of the reference numerals: transplanting a power output shaft 1; a spring retainer ring 2; a compression spring 3; a cam sleeve 4; a drive gear 5; a swing lever shaft 6; a swing rod 7; a spline 11; a chute 41; a stopper 42; cam sleeve boss 43; the gear boss 51 is driven.

Detailed Description

Embodiment one: referring to fig. 1-3, the invention discloses an anti-lock clutch mechanism, which comprises a transplanting power output shaft 1 and a swing rod shaft 6 with a swing rod 7; the transplanting power output shaft 1 is sequentially provided with a spring retainer ring 2, a pressure spring 3 and a cam shaft sleeve 4 from top to bottom, wherein the pressure spring 3 can be abutted against the spring retainer ring 2 and the cam shaft sleeve 4 and abutted against the cam shaft sleeve 4 to move up and down along the transplanting power output shaft 1; the end of the cam shaft sleeve 4 is connected with a driving gear 5 in a matched manner; the cam sleeve 4 is provided with a chute 41 with depth decreasing along the circumferential direction, and the swing rod 7 can be positioned in the chute 41 and is abutted against the cam sleeve 4.

The driving gear 5 is provided with a driving gear bulge 51, the cam shaft sleeve 4 is provided with a cam shaft sleeve bulge 43, and the driving gear bulge 51 and the cam shaft sleeve bulge 43 are mutually matched and connected for rapid and accurate occlusion of the driving gear 5 and the cam shaft sleeve 4. The drive gear boss 51 engages the cam sleeve boss 43 at an oblique angle.

The deepest end and the shallowest end of the depth of the chute 41 are provided with a stop block 42, the stop block 42 can block the swinging rod 7, and the swinging rod 7 is prevented from being separated from the chute 41 due to the rotation inertia of the cam shaft sleeve 4 when the swinging rod 7 moves along the chute 41.

Embodiment two: see fig. 1-3: an anti-lock clutch mechanism comprises a transplanting power output shaft 1 and a swing rod shaft 6 with a swing rod 7; the transplanting power output shaft 1 is sequentially provided with a spring retainer ring 2, a pressure spring 3 and a cam shaft sleeve 4 from top to bottom, wherein the pressure spring 3 can be abutted against the spring retainer ring 2 and the cam shaft sleeve 4 and abutted against the cam shaft sleeve 4 to move up and down along the transplanting power output shaft 1; the end of the cam shaft sleeve 4 is connected with a driving gear 5 in a matched manner; the cam sleeve 4 is provided with a chute 41 with depth decreasing along the circumferential direction, and the swing rod 7 can be positioned in the chute 41 and is abutted against the cam sleeve 4.

The outer peripheral surface of the transplanting power output shaft 1 is provided with a spline 11, and the cam shaft sleeve 4 is meshed with the spline 11 and can move up and down along the spline 11.

Referring to fig. 1-3, the working process of the invention is as follows: when the cam sleeve 4 and the driving gear 5 are in a meshed state, and an external force acts on the swing rod shaft 6, the swing rod 7 swings to be attached in the chute 41 of the cam sleeve 4, and the cam sleeve 4 and the driving gear 5 rotate together in a counterclockwise direction; at this time, the chute 41 is turned from deep to shallow, the swing rod 7 gradually separates the cam sleeve 4 from the driving gear 5, and the separation state of the clutch is completed, at this time, the transplanting power of the gearbox is stopped by the separation of the driving gear 5 and the cam sleeve 4, and the power output for completing the transplanting operation is stopped.

When an external force acts on the swing link shaft 6 so that the swing link 7 swings to be separated from the cam sleeve 4. The upper end of the pressure spring 3 is limited on the spring baffle plate 2, the other end of the pressure spring outputs pressure to enable the cam shaft sleeve to downwards until the cam shaft sleeve is completely meshed with the driving gear 5, so that the clutch is in a meshed state, at the moment, the transplanting power of the gearbox is transmitted to the cam shaft sleeve 4 through the driving gear 5, and then the transplanting power is transmitted to a transplanting power output shaft through spline connection by the cam shaft sleeve 4, so that the power output of the transplanting operation is completed.

The above-described embodiments are provided for illustrating the present application and not for limiting the scope of the present application, and various modifications of the equivalent forms of the present application, which are included in the scope of the appended claims, will occur to those skilled in the art after reading the present application.

Claims

1. An anti-lock clutch mechanism, which is characterized in that: comprises a transplanting power output shaft and a swing rod shaft with a swing rod; the transplanting power output shaft is sequentially provided with a spring retainer ring, a pressure spring and a cam shaft sleeve from top to bottom, wherein the pressure spring can be abutted against the spring retainer ring and the cam shaft sleeve and can be abutted against the cam shaft sleeve to move up and down along the transplanting power output shaft; the cam shaft sleeve end is connected with a driving gear in a matched manner; the cam shaft sleeve is provided with a chute with depth decreasing along the circumferential direction, and the swing rod can be positioned in the chute and is abutted against the cam shaft sleeve; the driving gear is provided with a driving gear bulge, the cam shaft sleeve is provided with a cam shaft sleeve bulge, and the driving gear bulge and the cam shaft sleeve bulge are mutually matched and connected; the driving gear bulge and the cam shaft sleeve bulge are engaged in an oblique angle curve; the deepest end and the shallowest end of the depth of the chute are provided with stop blocks; the outer peripheral surface of the transplanting power output shaft is provided with a spline, and the cam shaft sleeve is meshed with the spline and can move up and down along the spline.