CN215744457U - Gear terminal surface fat liquoring mechanism - Google Patents

Abstract

The utility model discloses an oil coating mechanism for the end face of a gear, which comprises a bracket, a support plate, a transverse sliding assembly, a vertical sliding assembly and an oil coating device, wherein the support plate is arranged on the bracket; the vertical sliding component is arranged on the transverse sliding seat and is provided with a vertical sliding seat; the oiling device comprises a main oiling component, an auxiliary oiling component and a transmission component, wherein the main oiling component comprises a motor and an oiling disc, the motor shaft is hollow, the upper end of the motor shaft is provided with an oil inlet, the lower end of the motor shaft is provided with an oil outlet, the oil outlet is connected with the oiling disc, and the oiling disc is provided with an oil outlet nozzle; the secondary oiling assembly comprises a base, a rotating shaft and an oiling disc. Consequently, form into oil pipe way through adopting motor shaft cavity design, avoid setting up the pipeline winding phenomenon that oil pipe led to in addition, overall structure is simple, and automatic fat liquoring operation has reduced a large amount of hand labor volume, has improved fat liquoring efficiency and fat liquoring effect.

Description

Gear terminal surface fat liquoring mechanism

Technical Field

The utility model relates to the technical field of gear assembly, in particular to a gear end face oiling mechanism.

Background

A gear motor (also referred to as a gear change motor) is a motor widely used on the market today, and includes a motor portion including a motor main body and an output shaft that is rotated at a high speed by a rotor of the motor main body, and a change gear portion having gear pairs of different meshing forms according to requirements of different gear ratios. Generally, each gear pair of the transmission gear part includes a driving gear mounted on the motor shaft and a driven gear engaged with the driving gear, and the driving gear is rotated by the motor shaft and rotates the driven gear engaged therewith, thereby rotating the other gears of the transmission gear part and finally outputting driving force and torque to the outside.

In the assembly process of the existing gear motor, an assembly method is adopted, wherein a driving gear is firstly installed on a motor shaft, other gears of a speed change gear part are installed at the same time, then the driving gear is butted with a driven gear to be meshed with the driving gear, and gear teeth of the driven gear can be just inserted into a tooth space of the driving gear to realize the meshing between the driving gear and the driven gear.

The existing assembly method and equipment are ubiquitous: the degree of automation is low, needs more artifical supplementary just can realize to, mechanism structures such as gear fat liquoring are complicated, difficult operation. Therefore, should current gear fat liquoring mechanism improve, improve equipment degree of automation to reduce the amount of hand labor, reduce cost improves production efficiency.

SUMMERY OF THE UTILITY MODEL

In view of the above, the present invention is directed to the defects in the prior art, and a primary object of the present invention is to provide a gear end face oiling mechanism, which avoids the phenomenon of pipeline winding caused by additionally arranging an oil inlet pipeline by adopting a hollow design of a motor shaft to form the oil inlet pipeline, has a simple overall structure, automatically oils, reduces a large amount of manual labor, and simultaneously improves oiling efficiency and oiling effect.

In order to achieve the purpose, the utility model adopts the following technical scheme:

a gear end face oiling mechanism comprises a support, a support plate arranged on the support, a transverse sliding assembly, a vertical sliding assembly and an oiling device, wherein the support plate is arranged on the support; the vertical sliding component is arranged on the transverse sliding seat and is provided with a vertical sliding seat; the oiling device is arranged on the vertical sliding seat and comprises a main oiling component, an auxiliary oiling component and a transmission component, wherein the main oiling component comprises a motor and an oiling disc arranged at the lower end of a motor shaft, the interior of the motor shaft is hollow, the upper end of the motor shaft is provided with an oil inlet, the lower end of the motor shaft is provided with an oil outlet, the oil outlet is connected with the oiling disc, and at least one oil outlet nozzle is arranged on the oiling disc; the auxiliary oiling assembly comprises a base, a rotating shaft and an oiling disc, wherein the rotating shaft is rotatably arranged on the base, the oiling disc is arranged at the lower end of the rotating shaft, the base is fixedly connected to a support plate, an oil duct is arranged in the rotating shaft, an oil inlet hole communicated with the oil duct is formed in the base, and at least one oil outlet nozzle is arranged on the oiling disc and communicated with the oil duct; the transmission assembly is connected between the motor shaft and the rotating shaft, and the rotating shaft is driven to rotate by the transmission assembly while the motor shaft rotates.

As a preferred embodiment: the lower end of the oiling disc of the main oiling component is provided with two oil outlet nozzles in an inverted splayed interval manner; two oil outlet nozzles are vertically arranged at the lower end of the oiling disc of the auxiliary oiling component in an interval manner.

As a preferred embodiment: an annular oil storage groove is formed in the inner wall of the base, corresponding to the position of the oil inlet hole, around the rotating shaft, and the upper end of the oil duct is folded towards the oil inlet hole and is communicated with the annular oil storage groove.

As a preferred embodiment: and a transverse oil way communicated with the lower end of the oil way is transversely arranged in the oil coating disc of the auxiliary oil coating assembly, and the upper end of the oil outlet nozzle is communicated with the transverse oil way.

As a preferred embodiment: and a transverse oil way communicated with an oil outlet at the lower end of the motor shaft is transversely arranged in the oil coating disc of the main oil coating assembly, and the upper end of the oil outlet nozzle is communicated with the transverse oil way.

As a preferred embodiment: two oil ducts are vertically arranged in a rotating shaft of the auxiliary oiling component, oil inlet holes are respectively formed in the base corresponding to the two oil ducts, a transverse oil path is respectively formed in the oiling disc corresponding to the two oil ducts, and the two oil outlet nozzles are communicated with the two transverse oil paths in a one-to-one correspondence mode.

As a preferred embodiment: the transmission assembly comprises a driving belt wheel, a driven belt wheel and a transmission belt, the driving belt wheel is arranged at the upper end of the motor shaft, the driven belt wheel is arranged at the upper end of the rotating shaft, and the driving belt wheel and the driven belt wheel are sleeved with the transmission belt.

Compared with the prior art, the gear end face oiling mechanism has the advantages that the transverse sliding assembly, the vertical sliding assembly and the oiling device are integrally mounted on the support to form the gear end face oiling mechanism, the oiling mechanism adopts a hollow design of the motor shaft to form the oil inlet pipeline, the phenomenon of pipeline winding caused by the fact that the oil inlet pipeline is additionally arranged is avoided, the overall structure is simple, automatic oiling operation is achieved, a large amount of manual labor is reduced, and oiling efficiency and oiling effect are improved.

To more clearly illustrate the structural features and effects of the present invention, the following detailed description is given with reference to the accompanying drawings and specific embodiments.

Drawings

FIG. 1 is a perspective view of a first perspective of the oiling mechanism of the present invention;

FIG. 2 is a perspective view of the second perspective of the oiling mechanism of the present invention;

FIG. 3 is a third perspective view of the oiling mechanism of the present invention;

FIG. 4 is a schematic cross-sectional view of the oiling mechanism of the present invention.

The attached drawings indicate the following:

the device comprises a gear end face oiling mechanism 10, a support 11, a support plate 12, a transverse sliding assembly 13, a transverse sliding seat 131, a sliding table 142, a transverse driving cylinder 133, a vertical sliding assembly 14, a vertical sliding seat 141, a sliding table 142, a vertical driving cylinder 143, an oiling device 15, a main oiling assembly 151, a motor 1511, an oiling disc 1512, an oil inlet 1513, an oil outlet 1514, an oil outlet 1515, a transverse oil way 1516, an auxiliary oiling assembly 152, a base 1521, a rotating shaft 1522, an oiling disc 1523, an oil channel 1524, an oil inlet 1525, an annular oil storage tank 1526, an oil outlet 1527, a transverse oil way 1516, a transmission assembly 153, a driving pulley 1531, a driven pulley 1532 and a transmission belt 1533.

Detailed Description

As shown in fig. 1 to 4, the utility model provides a gear end face oiling mechanism 10, which comprises a bracket 11, a support plate 12 mounted on the bracket 11, a transverse sliding assembly 13, a vertical sliding assembly 14 and an oiling device 15, wherein:

the support plate 12 is mounted on the bracket 11, the transverse sliding assembly 13 is transversely arranged on the support plate 12, and the transverse sliding assembly 13 is provided with a transverse sliding seat 131; the vertical sliding assembly 14 is mounted on the transverse sliding seat 131, and the vertical sliding assembly 14 is provided with a vertical sliding seat 141; the oiling device 15 is mounted on the vertical sliding seat 141 and comprises a main oiling component 151, an auxiliary oiling component 152 and a transmission component 153, wherein the main oiling component 151 comprises a motor 1511 and an oiling disc 1512 mounted at the lower end of the shaft of the motor 1511, the shaft of the motor 1511 is hollow, the upper end of the shaft of the motor 1511 is an oil inlet 1513, the lower end of the shaft of the motor 1511 is an oil outlet 1514 (the hollow arrangement of the motor shaft can omit an additional oil inlet pipeline), the oil outlet 1514 is connected with the oiling disc 1512, and at least one oil outlet 1515 is arranged on the oiling disc 1512; the auxiliary oiling assembly 152 comprises a base 1521, a rotating shaft 1522 rotatably mounted on the base 1521 and an oiling disc 1523 mounted at the lower end of the rotating shaft 1522 (a sensor 154 used for monitoring the rotating position of the oiling disc 1523 is arranged on the base 1521, and whether the oiling disc 1523 rotates in place or not is monitored in real time), the base 1521 is fixedly connected to the support plate 12, an oil passage 1524 is arranged inside the rotating shaft 1522, an oil inlet hole 1525 communicated with the oil passage 1524 is formed in the base 1521, an annular oil storage groove 1526 is arranged on the inner wall of the base 1521 around the rotating shaft 1522 corresponding to the oil inlet hole 1525, the upper end of the oil passage 1524 is folded towards the oil inlet hole 1525 and communicated with the annular oil storage groove 1526, in the rotating process of the rotating shaft 1522, oil in the annular oil storage groove 6 continuously enters the oil passage 1524, and the rotating shaft 1522 swings the oil and the oil inlet is not affected; the oiling disc 1523 is provided with at least one oil outlet nozzle 1527, and the oil outlet nozzle 1527 is communicated with the oil passage 1524; the transmission assembly 153 is connected between the shaft of the motor 1511 and the rotating shaft 1522, and the shaft of the motor 1511 rotates while driving the rotating shaft 1522 to rotate through the transmission assembly 153.

The lower end of an oiling disc 1512 of the main oiling component 151 is provided with two oil outlet nozzles 1515 in an inverted-splayed interval manner (an inverted-splayed large oiling area is arranged); two oil outlet nozzles 1515 are vertically arranged at the lower end of the oiling disc 1512 of the auxiliary oiling component 152 at intervals. A transverse oil path 1516 communicated with the lower end of the oil channel 1524 is transversely arranged in the oiling disc 1512 of the auxiliary oiling component 152, and the upper end of the oil outlet 1515 is communicated with the transverse oil path 1516. A transverse oil path 1516 communicated with the lower end of the shaft of the motor 1511 is transversely arranged in an oil coating disc 1512 of the main oil coating assembly 151, and the upper end of an oil outlet 1515 is communicated with the transverse oil path 1516. Two oil passages 1524 are vertically arranged in a rotating shaft 1522 of the auxiliary oiling component 152, oil inlet holes 1525 are respectively formed in the base 1521 corresponding to the two oil passages 1524, transverse oil passages 1528 are respectively formed in the oiling disc 1523 corresponding to the two oil passages 1524, and the two oil outlet nozzles 1527 are communicated with the two transverse oil passages 1528 in a one-to-one correspondence mode. The driving assembly 153 includes a driving pulley 1531, a driven pulley 1532 and a driving belt 1533, the driving pulley 1531 is mounted on the upper end of the shaft of the motor 1511, the driven pulley 1532 is mounted on the upper end of the rotating shaft 1522, and the driving belt 1531 and the driven pulley 1532 are sleeved with the driving belt 1533. The transverse sliding assembly 13 further comprises a sliding table 132 and a transverse driving cylinder 133, the sliding table 132 is mounted on the support plate 12, the transverse sliding seat 131 is slidably mounted on the sliding table 132, and the axial end of the transverse driving cylinder 133 is connected with the transverse sliding seat 131. The vertical sliding assembly 14 further comprises a sliding table 142 and a vertical driving cylinder 143, the sliding table 142 is mounted on the horizontal sliding base 131, the vertical sliding base 141 is slidably mounted on the sliding table 142, and the axial end of the vertical driving cylinder 143 is connected with the horizontal sliding base 131.

The gear end face oiling mechanism is characterized in that the transverse sliding assembly, the vertical sliding assembly and the oiling device are integrally mounted on the support to form the gear end face oiling mechanism, the oiling mechanism adopts a hollow design of a motor shaft to form an oil inlet pipeline, the phenomenon of pipeline winding caused by additionally arranging the oil inlet pipeline is avoided, the whole structure is simple, the oiling operation is automated, a large amount of manual labor is reduced, and the oiling efficiency and the oiling effect are improved.

The above description is only a preferred embodiment of the present invention, and is not intended to limit the technical scope of the present invention, so that any minor modifications, equivalent changes and modifications made to the above embodiments according to the technical spirit of the present invention are within the technical scope of the present invention.

Claims (7)

1. The utility model provides a gear terminal surface fat liquoring mechanism which characterized in that: the oiling device comprises a bracket, a support plate arranged on the bracket, a transverse sliding assembly, a vertical sliding assembly and an oiling device, wherein the support plate is arranged on the bracket; the vertical sliding component is arranged on the transverse sliding seat and is provided with a vertical sliding seat; the oiling device is arranged on the vertical sliding seat and comprises a main oiling component, an auxiliary oiling component and a transmission component, wherein the main oiling component comprises a motor and an oiling disc arranged at the lower end of a motor shaft, the interior of the motor shaft is hollow, the upper end of the motor shaft is provided with an oil inlet, the lower end of the motor shaft is provided with an oil outlet, the oil outlet is connected with the oiling disc, and at least one oil outlet nozzle is arranged on the oiling disc; the auxiliary oiling assembly comprises a base, a rotating shaft and an oiling disc, wherein the rotating shaft is rotatably arranged on the base, the oiling disc is arranged at the lower end of the rotating shaft, the base is fixedly connected to a support plate, an oil duct is arranged in the rotating shaft, an oil inlet hole communicated with the oil duct is formed in the base, and at least one oil outlet nozzle is arranged on the oiling disc and communicated with the oil duct; the transmission assembly is connected between the motor shaft and the rotating shaft, and the rotating shaft is driven to rotate by the transmission assembly while the motor shaft rotates.

2. The gear face oiling mechanism of claim 1, wherein: the lower end of the oiling disc of the main oiling component is provided with two oil outlet nozzles in an inverted splayed interval manner; two oil outlet nozzles are vertically arranged at the lower end of the oiling disc of the auxiliary oiling component in an interval manner.

3. The gear face oiling mechanism of claim 1, wherein: an annular oil storage groove is formed in the inner wall of the base, corresponding to the position of the oil inlet hole, around the rotating shaft, and the upper end of the oil duct is folded towards the oil inlet hole and is communicated with the annular oil storage groove.

4. The gear face oiling mechanism of claim 1, wherein: and a transverse oil way communicated with the lower end of the oil way is transversely arranged in the oil coating disc of the auxiliary oil coating assembly, and the upper end of the oil outlet nozzle is communicated with the transverse oil way.

5. The gear face oiling mechanism of claim 1, wherein: and a transverse oil way communicated with an oil outlet at the lower end of the motor shaft is transversely arranged in the oil coating disc of the main oil coating assembly, and the upper end of the oil outlet nozzle is communicated with the transverse oil way.

6. The gear face oiling mechanism of claim 1, wherein: two oil ducts are vertically arranged in a rotating shaft of the auxiliary oiling component, oil inlet holes are respectively formed in the base corresponding to the two oil ducts, a transverse oil path is respectively formed in the oiling disc corresponding to the two oil ducts, and the two oil outlet nozzles are communicated with the two transverse oil paths in a one-to-one correspondence mode.

7. The gear face oiling mechanism of claim 1, wherein: the transmission assembly comprises a driving belt wheel, a driven belt wheel and a transmission belt, the driving belt wheel is arranged at the upper end of the motor shaft, the driven belt wheel is arranged at the upper end of the rotating shaft, and the driving belt wheel and the driven belt wheel are sleeved with the transmission belt.

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