CN211579773U - Bevel gear bridge type flexible connection structure for connecting outer rotor motor and driven shaft - Google Patents

Abstract

The utility model relates to a connect bevel gear bridge type flexible connection structure of external rotor electric machine and driven shaft, including external rotor electric machine, driven shaft, take place axial displacement and radial displacement's flexible connection spare by the permission connection position between external rotor electric machine and the driven shaft and connect. The utility model has the advantages that: the outer rotor motor is connected with the driven shaft through a flexible connecting piece allowing the connecting part to generate axial displacement and radial displacement, and the engaged bevel gear type connecting structure is matched with the universal connecting bridge, so that the shaking of the outer rotor motor during working is prevented from being transmitted to the driven shaft, the abrasion of the driven shaft can be reduced, the driven shaft is prevented from being bent or broken, and the service life of the driven shaft is prolonged.

Description

Bevel gear bridge type flexible connection structure for connecting outer rotor motor and driven shaft

Technical Field

The utility model relates to a mechanical transmission field especially relates to an oxygen-increasing machine waterwheel connects bevel gear bridge type flexible connection structure of external rotor electric machine and driven shaft.

Background

In the existing aerator waterwheel, an outer rotor motor with a single-side output shaft is widely applied due to simple structure, large output torque, low manufacturing cost, thin axial thickness and light weight.

However, the outer rotor motor with a shaft protruding from one side is prone to shake during operation, and if one end of the outer rotor motor without the shaft is directly and rigidly connected with the driven shaft of the driven device through connecting pieces such as connecting flanges, the shaking during operation of the outer rotor motor can increase the abrasion speed of the driven shaft, and even bend or break the driven shaft. Therefore, a flexible connecting piece is needed to flexibly connect the outer rotor motor with the driven shaft.

SUMMERY OF THE UTILITY MODEL

An object of the utility model is to overcome the above problem that prior art exists, provide a bevel gear bridge type flexible connection structure who connects external rotor electric machine and driven shaft.

For realizing above-mentioned technical purpose, reach above-mentioned technological effect, the utility model discloses a following technical scheme realizes:

a bevel gear bridge type flexible connection structure for connecting an outer rotor motor and a driven shaft comprises the outer rotor motor and a cylindrical driven shaft, wherein the outer rotor motor and the driven shaft are connected through a flexible connecting piece which allows the connection part to generate axial displacement and radial displacement; the flexible connecting piece comprises a first universal connecting bridge and a second universal connecting bridge which are matched with each other, the centers of the first universal connecting bridge and the second universal connecting bridge are respectively provided with a circular shaft hole along the axial direction, one end of each of the first universal connecting bridge and the second universal connecting bridge is provided with at least two fan-shaped blocks which are arranged according to an annular array, a fan-shaped groove is formed between two adjacent fan-shaped blocks at the end part of each of the first universal connecting bridge and the second universal connecting bridge, the central angle corresponding to the sector-shaped groove is larger than the central angle corresponding to the sector-shaped block, the sector-shaped block at the end part of the first universal connecting bridge is inserted into the sector-shaped groove at the end part of the second universal connecting bridge, gaps for mutual displacement are formed between the fan-shaped blocks of the first universal connecting bridge and the second universal connecting bridge which are matched with each other, wherein the first universal connecting bridge is sleeved at the tail end of the driven shaft; the flexible connecting piece further comprises a first bevel gear and a second bevel gear which are meshed with each other, the first bevel gear is fixedly installed in the center of one end of the motor shaft of the outer rotor motor, a connecting round rod is fixedly sleeved in a shaft hole formed in the center of the second bevel gear, a second universal connecting bridge is assembled at one end or two ends of the connecting round rod in an interference fit mode, and the number of teeth of the first bevel gear is less than that of the second bevel gear.

The utility model has the advantages that: the outer rotor motor is connected with the driven shaft through a flexible connecting piece allowing the connecting part to generate axial displacement and radial displacement, and the engaged bevel gear type connecting structure is matched with the universal connecting bridge, so that the shaking of the outer rotor motor during working is prevented from being transmitted to the driven shaft, the abrasion of the driven shaft can be reduced, the driven shaft is prevented from being bent or broken, and the service life of the driven shaft is prolonged.

Drawings

The accompanying drawings, which are included to provide a further understanding of the invention and are incorporated in and constitute a part of this application, illustrate embodiment(s) of the invention and together with the description serve to explain the invention without undue limitation to the invention. In the drawings:

fig. 1 is a schematic structural view of an external rotor motor in the present invention;

fig. 2 is a schematic view of a matching structure of the first universal connecting bridge and the second universal connecting bridge in the present invention;

FIG. 3 is a schematic structural view of a second universal connecting bridge according to the present invention;

fig. 4 is a schematic structural diagram of a first embodiment of the present invention;

fig. 5 is a schematic structural diagram of a second embodiment of the present invention.

The reference numbers in the figures illustrate: the external rotor motor 110, a snap ring 111, a raised rib 112, a screw hole 113, a driven shaft 120, a motor platform 151, a bearing seat 170, a first universal connecting bridge 1901, a second universal connecting bridge 1902, a shaft hole 191, a sector block 192, a sector groove 193, a gap 194, a first bevel gear 810 and a second bevel gear 820.

Detailed Description

The present invention will be described in detail below with reference to the accompanying drawings in conjunction with embodiments.

As shown in fig. 1, fig. 2, fig. 3, and fig. 4, in a first embodiment: a bevel gear bridge type flexible connection structure for connecting an outer rotor motor and a driven shaft comprises the outer rotor motor 110 and a cylindrical driven shaft 120, wherein the outer rotor motor 110 and the driven shaft 120 are connected through a flexible connecting piece which allows the axial displacement and the radial displacement of a connection part.

The flexible connector comprises a first universal connecting bridge 1901, a second universal connecting bridge 1902, two first bevel gears 810 and a second bevel gear 820 which are mutually matched, wherein the centers of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 are respectively provided with a circular shaft hole 191 along the axial direction, one end of each of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 is provided with two fan-shaped blocks 192 which are arranged according to an annular array, a fan-shaped groove 193 is formed between two adjacent fan-shaped blocks 192 at the end of each of the first universal connecting bridge 1901 and the second universal connecting bridge 1902, the central angle corresponding to the fan-shaped groove 193 is larger than that corresponding to the fan-shaped block 192, the fan-shaped block 192 at the end of the first universal connecting bridge 1901 is inserted into the fan-shaped groove 193 at the end of the second universal connecting bridge 1902, a gap 194 for mutual displacement is formed between the fan-shaped blocks 192 of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 which are mutually matched, wherein the first universal connecting bridge 1901 is sleeved at the end of the driven shaft 120, the first bevel gear 810 is fixedly installed at the center of one end of the motor shaft of the outer rotor motor 110, the shaft hole arranged at the center of the second bevel gear 820 is fixedly sleeved with a connecting round rod 1100, one end of the connecting round rod 1100 is assembled with the second universal connecting bridge 1902 in an interference manner, and the number of teeth of the first bevel gear 810 is less than that of the second bevel gear 820.

As shown in fig. 1, 2, 3 and 5, the second embodiment: a bevel gear bridge type flexible connection structure for connecting an outer rotor motor and a driven shaft comprises the outer rotor motor 110 and a cylindrical driven shaft 120, wherein the outer rotor motor 110 and the driven shaft 120 are connected through a flexible connecting piece which allows the axial displacement and the radial displacement of a connection part.

The flexible connector comprises a first universal connecting bridge 1901, a second universal connecting bridge 1902, two first bevel gears 810 and a second bevel gear 820 which are mutually matched, wherein the centers of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 are respectively provided with a circular shaft hole 191 along the axial direction, one end of each of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 is provided with two fan-shaped blocks 192 which are arranged according to an annular array, a fan-shaped groove 193 is formed between two adjacent fan-shaped blocks 192 at the end of each of the first universal connecting bridge 1901 and the second universal connecting bridge 1902, the central angle corresponding to the fan-shaped groove 193 is larger than that corresponding to the fan-shaped block 192, the fan-shaped block 192 at the end of the first universal connecting bridge 1901 is inserted into the fan-shaped groove 193 at the end of the second universal connecting bridge 1902, a gap 194 for mutual displacement is formed between the fan-shaped blocks 192 of the first universal connecting bridge 1901 and the second universal connecting bridge 1902 which are mutually matched, wherein the first universal connecting bridge 1901 is sleeved at the end of the driven shaft 120, the first bevel gear 810 is fixedly installed at the center of one end of the motor shaft of the outer rotor motor 110, the shaft hole arranged at the center of the second bevel gear 820 is fixedly sleeved with a connecting round rod 1100, the two ends of the connecting round rod 1100 are respectively assembled with the second universal connecting bridge 1902 in an interference manner, and the number of teeth of the first bevel gear 810 is less than that of the second bevel gear 820.

The utility model discloses be the tight fit between axis and shaft hole, connection round bar and shaft hole, motor shaft and the axle support seat.

The foregoing shows and describes the general principles, essential features, and advantages of the invention. It will be understood by those skilled in the art that the present invention is not limited to the above embodiments, and that the foregoing embodiments and descriptions are provided only to illustrate the principles of the present invention without departing from the spirit and scope of the present invention.

Claims (1)

1. The utility model provides a connect bevel gear bridge type flexible connection structure of external rotor electric machine and driven shaft which characterized in that: the flexible connection device comprises an outer rotor motor and a cylindrical driven shaft, wherein the outer rotor motor is connected with the driven shaft through a flexible connection piece which allows the connection part to generate axial displacement and radial displacement; the flexible connecting piece comprises a first universal connecting bridge and a second universal connecting bridge which are matched with each other, the centers of the first universal connecting bridge and the second universal connecting bridge are respectively provided with a circular shaft hole along the axial direction, one end of each of the first universal connecting bridge and the second universal connecting bridge is provided with at least two fan-shaped blocks which are arranged according to an annular array, a fan-shaped groove is formed between two adjacent fan-shaped blocks at the end part of each of the first universal connecting bridge and the second universal connecting bridge, the central angle corresponding to the sector-shaped groove is larger than the central angle corresponding to the sector-shaped block, the sector-shaped block at the end part of the first universal connecting bridge is inserted into the sector-shaped groove at the end part of the second universal connecting bridge, gaps for mutual displacement are formed between the fan-shaped blocks of the first universal connecting bridge and the second universal connecting bridge which are matched with each other, wherein the first universal connecting bridge is sleeved at the tail end of the driven shaft; the flexible connecting piece further comprises a first bevel gear and a second bevel gear which are meshed with each other, the first bevel gear is fixedly installed in the center of one end of the motor shaft of the outer rotor motor, a connecting round rod is fixedly sleeved in a shaft hole formed in the center of the second bevel gear, a second universal connecting bridge is assembled at one end or two ends of the connecting round rod in an interference fit mode, and the number of teeth of the first bevel gear is less than that of the second bevel gear.

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