RU2360351C1 - Electric motor - Google Patents

Abstract

FIELD: motors and pumps; electric engineering.

SUBSTANCE: invention relates to electric engineering and electric machine industry and may be used in machine and mechanisms drives. The technical result of the invention is achieved by including housing, stator, rotor, shaft inside rotor and spring-loaded bush in the electric motor. In the structure provided, the spring-loaded bush is installed on the shaft by means of spline keys. The proposed electric motor includes also balls placed in wedge-type grooves on rotor ends, spring-loaded bushing, two switches on the housing, holed disc mounted on the rotor by screwing and additional bushing with extensions rigidly mounted on the spring-loaded bushing. The disc is placed between switches and bushing extensions enter the disc holes.

EFFECT: wide functional possibilities of electric motor; electric motor can be rotated in reverse direction after motor tripping in case of overloading.

1 dwg

Description

The invention relates to electrical engineering and can be used in the drive of machines and mechanisms.

A known electric motor (AS USSR No. 729758, publication date 25.04.80), comprising a housing, a stator, a rotor, a shaft located inside the rotor, a sleeve mounted on the shaft using splines, balls located in the wedge grooves on the ends of the rotor and bushings. The disadvantage of this electric motor is that it does not turn off during mechanical overloads.

An electric motor is free from this drawback (AS USSR No. 936242, publication date 15.06.82), comprising a housing, a stator, a rotor, a shaft located inside the rotor, a spring-loaded sleeve mounted on the shaft using splines, balls located in wedges grooves on the ends of the rotor and the spring-loaded sleeve, and a switch located on the housing. The disadvantage of this electric motor is the inability to turn on the rotation of the electric motor in the opposite direction after switching off during overloads.

In this electric motor, which is closest to the proposed one, with mechanical overloads, the sleeve mounted on the shaft with the help of splines makes further axial movement along the shaft until the spring-loaded sleeve comes into contact with a switch that disconnects the motor power circuit. At the same time, it is not possible to turn on the electric motor in the opposite direction, which significantly reduces its use in automatic process control systems.

The technical result, the achievement of which the present invention is directed, is to expand the functionality of the electric motor, namely to provide the possibility of turning on the electric motor in the opposite direction after it is turned off during overloads.

To achieve this technical result, an electric motor comprising a housing, a stator, a rotor, a shaft located inside the rotor, a spring-loaded sleeve mounted on the shaft using splines, balls located in the wedge grooves on the ends of the rotor and the spring-loaded sleeve, and a switch located on the housing introduced a second switch, also located on the case, a disk with holes located between the switches mounted on the rotor by means of a threaded connection, an additional sleeve having protrusions included in the holes of the disc, firmly seated on a spring-loaded sleeve.

Distinctive features of this electric motor from the prototype is the presence of a second switch mounted on the housing, a disk with holes located between the switches and mounted on the rotor by means of a threaded connection, an additional sleeve having protrusions entering the holes of the disk and rigidly mounted on a spring-loaded sleeve.

Due to these signs, during overloads, when the rotor of the engine rotates and the shaft stops rotating, the spring loaded sleeve moves axially, the disk rotates and thanks to the threaded connection with the rotor, it simultaneously performs axial movement in one direction or another (depending on the direction of rotation rotor) until it comes into contact with one of the switches. The switch breaks the power supply circuit of the electric motor, the electric motor stops. In this case, it remains possible to turn on the motor in the opposite direction through the second switch.

The drawing shows the proposed motor.

The electric motor comprises a housing 1, a stator 2, a rotor 3, a shaft 4 located inside the rotor 3, a sleeve 5 mounted on the shaft 4 using splines, an additional sleeve 6 having two protrusions 7 included in the corresponding holes of the disk 8 mounted on the rotor 3 s using a threaded connection, the balls 9 located in the wedge grooves at the ends of the rotor 3 and the spring-loaded sleeve 5, the spring 10, the stop 11, the nut 12 and the switches 13 and 14.

The operation of the electric motor. From the rotor 3, the torque is transmitted through the balls 9 and the spring-loaded sleeve 5 to the shaft 4.

In the absence of overload on the shaft 4, the spring-loaded sleeve 5 rotates together with the rotor 3, because the axial component of the transmitted torque is less than the compression force of the spring 10.

When overloaded, the shaft 4 stops rotating, the rotor 3 continues to rotate, the spring loaded sleeve 5 moves axially without rotational movement. In this case, the disk 8 rotates and, thanks to the threaded connection with the rotor 3, simultaneously performs axial movement to one side or the other from the neutral position, depending on the direction of rotation of the rotor, until it contacts one of the switches that disconnects the power supply circuit of the electric motor. In this case, it remains possible to turn on the motor in the opposite direction through the second switch.

Maintaining the ability to turn on the motor in the opposite direction after shutdown during overloads significantly expands the functionality of its application.

Claims (1)

An electric motor comprising a housing, a stator, a rotor, a shaft located inside the rotor, a spring-loaded sleeve mounted on the shaft using splines, balls located in wedge grooves on the ends of the rotor and the spring sleeve, a switch located on the housing, characterized in that, with In order to expand the functionality, it is equipped with a second switch, also located on the case, a disk with holes located between these switches and mounted on the rotor by means of a threaded connection, additional Coy with protrusions that are part of the disk holes, planted firmly on the spring-loaded sleeve.