RU13824U1 - ELECTRIC DRIVE - Google Patents

Abstract

An electric drive comprising an electric motor and a gearbox housed in a housing with a first differential gear made in the form of a planetary gear with a central gear wheel mounted on a central shaft, an external gear wheel, an output carrier shaft, satellites, spurious gears interacting with an external gear wheel and pinion mounted on a hollow shaft covering the Central shaft, while the shafts of spurious gears are fixed on a support freely mounted on the hollow shaft, characterized in that it is equipped with a second differential mechanism, made in the form of a central gear mounted on a hollow shaft, satellites kinematically connected by a gear pair with the motor shaft, and normally driven by a carrier brake, rigidly fixed to the central shaft, in addition, the first differential mechanism is equipped with a stopper, containing a latch spring-loaded relative to the housing, interacting with grooves made on the side surface of the outer wheel, and the bearing of the parasitic shafts Ester is provided with a spring-loaded against the housing stops from rotating about the central shaft and kinematically connected with a latch stopper outer wheel carrier termozom and second differential mechanism.

Description

ELECTRIC DRIVE

The utility model relates to reinforcing roasting, namely, to means for controlling shutoff valves of pipelines by means of an electric drive, and is intended for etching by flows of liquid, gas, and bulk solids.

A two-speed self-regulating reversible planetary gear train is known, comprising a drive shaft on which the sun wheel is mounted, a carrier with satellites, a crown wheel connected to a ratchet mechanism with a housing, leaf springs mounted on the carrier and acting on the levers of the ratchet wheel dogs, the worm of which is a worm pair, a worm with a splined connection connected to the carrier, a friction clutch, the drive discs of which are mounted in the worm on the birds of the drive shaft, and the driven discs are connected by means of a splined joint unity with the worm and elastically tightened on both sides (AS USSR No. 361338, IPC F16H 3/46, 1973).

In this transmission, with increasing torque on the output shaft, an axial force develops on the worm, under the action of which the clutch engages the planetary gear in operation. The disadvantages of this device include the fact that at a transitional moment, when the axial force of the worm is equal to the speed switching force, both speeds are disabled, or multiple coupling and disengagement of the clutch occur, i.e., an oscillatory process of transition from one speed to another occurs. Therefore, this two-speed transmission, due to the low reliability of speed switching, has not found practical application.

IPC6 F16H 37/08

Known electric shutoff valves containing an electric motor, a planetary gear and a differential mechanism. The planetary gearbox consists of a braked input drive shaft, a first central wheel with an external worm gear and an internal cylindrical gear, satellites and a second gear wheel rigidly connected to the drive shaft of the shut-off member. The differential mechanism of the electric drive is made in the form of a carrier with satellites and two central wheels, one of which is rigidly connected to the motor shaft, and the other wheel is mounted on a shaft carrying a self-braking worm, which is in worm gearing with the first central gear wheel, and the differential carrier is kinematically connected with input shaft carrier of the gearbox. The input carrier shaft is inhibited, for example, by a position lock made in the form of a wheel rigidly fixed to the input carrier shaft in which the recesses are made, and a spring-loaded ball placed in the housing. (RF patent No. 2076255, IPC6 F16H 37/08, 03/27/97).

Although this electric drive has proven itself in operation, it has a significant drawback due to the presence of two worm pairs. The presence of worm pairs not only reduces the efficiency of the drive, but also significantly increases its cost, since the wheels of the worm pairs are made of expensive copper alloys.

As a prototype for the largest number of matching essential features with s; 1, an electric drive according to A.S. USSR No. 565858, IPC2 B65G 23/26, 11/14/77. The electric drive contains an electric motor, a gearbox with a differential mechanism, made in the form of an external wheel, a carrier with satellites, the input shaft of which is connected to the gear wheel connected to it

electric drive, and the output shaft with the drive sprocket block. The electric drive also contains an electromagnetic slip clutch (EMC) mounted on a hollow shaft covering the input shaft of the gearbox and on which the gear is mounted. In the EMC housing, shafts of parasitic gears are fixed. They interact with the outer wheel and the planetary gear gear.In this drive, the planetary gear is connected to the hub after the motor has set the nominal speed of rotation by applying current to the EMC excitation winding, whose inductor brakes the outer central planetary gear wheel. In case of overload, the excitation current is turned off, and the EMC inductor is released, disabling the planetary gear. The disadvantages of this drive include the inability to implement two different transmission speeds required when controlling shutoff valves. In addition, the device contains such an element as a coupling, which complicates the design of the drive.

The utility model solves the problem of expanding the functionality of the electric drive due to the position of the second increased speed of rotation of the drive shaft of the locking member in the absence of limiting moments of sealing of the locking member, as well as improving the reliability of automatic switching from increased speed to speed with increased torque in the presence of an increased load on the drive shaft locking organ.

This problem is solved in that in an electric drive containing an electric motor and a gearbox located in the gearbox with a first differential gear made in the form of a planetary gear with a central gear wheel mounted on a central shaft, an external gear wheel, an output drive shaft, satellites, spurious gears interacting with

an external gear wheel and a gear mounted on a hollow shaft covering the central shaft, while the shafts of spurious gears are mounted on a support freely mounted on the hollow shaft, a second differential mechanism is introduced. The second differential mechanism is made in the form of a central gear mounted on a hollow shaft, satellites kinematically connected by a gear pair to the motor shaft, and a carrier normally braked relative to the housing by a brake, rigidly fixed to the central shaft. In addition, the first differential mechanism is equipped with a stopper containing a latch spring-loaded relative to the housing, interacting with grooves made on the side surface of the outer wheel, and the spindle gear shaft support is provided with spring-loaded stops relative to the housing from rotation around the central shaft and kinematically connected with the outer wheel stopper latch and a brake drove the second differential mechanism.

In FIG. 1 shows a kinematic diagram of an electric drive in general form; in FIG. 2 - kinematic diagram of an electric drive in operation with a load on the output shaft below the limit; in FIG. 3 the same, but in operation with a load higher than the limit; in FIG. 4 is a longitudinal section of an electric drive; in FIG. 5 is a section A-A of FIG. 4.

The electric drive comprises an electric motor 1, a gearbox with two different differential mechanisms located in the housing 2. The first differential mechanism is made in the form of a planetary gear containing a central gear 3 fixed on the central shaft 4, a normally disengaged external gear 5, an output driven carrier 6 with an output gear 7, satellites 8, spurious gears 9 interacting with an external gear a wheel 5 and a gear 10 mounted on a hollow shaft 11,

covering the Central shaft 4, the Shafts 12 spurious gears 9 are fixed in the support wheel 13 (support) freely mounted on the hollow shaft 11.

The second differential mechanism contains a central gear 14 mounted on the hollow shaft 11, satellites 15, 16 kinematically connected by gears 17, 18, 19 with the shaft of the electric motor 1, and the norm / braked in relation to the housing 2 drove 20 rigidly fixed to the Central shaft 4.

Moreover, the support 13 of the parasitic gears 9 is equipped with at least one spring 21 relative to the housing 2. The emphasis can be made, for example, in the form of a guide cylinder 22, rigidly mounted on the support wheel 13 and two spring-loaded 23 relative to each other nolungers 24, interacting with rotation limiters 25 mounted on the housing 2. The force of preload of the plungers 23 is regulated by nuts 26.

The brake 27 of the carrier 20 includes a housing 28 and a brake tape 29, covering the side surface of the carrier 20 and the device for adjusting the tension of the tape, located in the housing 28 of the brake 27. Moreover, one end of the tape 29 is fixed to the housing of the electric drive 2 by means of an adjustable coupling screw 30, and the second end the tape 29 is mounted on the plunger 31. The plunger 31 is spring-loaded with one end relative to the brake housing 28, providing a predetermined tension to the brake tape 29, and interacts with the eccentric 32 located in the brake housing 28 with a second end Stu rotation. The axis of rotation 33 of the eccentric 32 is installed in the support wheel 13.

The external (crown) gear 5 of the first differential mechanism is equipped with a stopper. The stopper is made in the form of a latch 34, the axis of rotation 35 of which is installed in the support wheel 13. The latch 34 on one side of the tension spring 36 is connected with

the housing 2 of the electric drive., and on the other hand has the ability to interact with the grooves 37 made on the side surface of the external gear 5.

The support wheel 13 together with the stops 21 spring-loaded relative to the housing 2 plays the role of a moment and is kinematically connected with the latch 34 of the stopper of the outer wheel 5 and the eccentric 32 of the brake 20.

An electric drive with a two-speed self-regulating transmission operates as follows.

In the initial position, the carrier 20 of the second differential mechanism is inhibited, therefore, the central shaft 4 is also inhibited, and the outer wheel 5 of the first differential mechanism is unlocked. The satellites 15 and the central wheel 14 of the second differential mechanism form a conventional gear pair (Fig. 2). In this position, the rotation of the shaft of the electric motor 1 (in any direction) is transmitted through the gears 19, 18, 17, 16, 15, 14, 10 to the spurious gears 9. Next, the rotation from the spurious gears 9 is transmitted to the outer wheel 5, satellites 8, which, rolling around the stationary central wheel 3, transmit the rotation to the output drive shaft 6. In the first mode of operation of the electric drive, it has an increased output rotation speed at the output.

When the electric drive is operating in the movement of the locking element, both for opening and closing, at the time of its breaking off, a significant braking torque develops on the output drive shaft 6, which is transmitted via satellites 8 to the central wheel 5 of the first differential mechanism to brake it. In this case, if the braking torque on the wheel 5 is large enough, the spurious gears 9 will act as satellites, and the support wheel 13 will drive their shafts. Then the torque

is transmitted to spurious gears 9 (satellites) from the electric motor 1 through gears 19, 18, 17, 16, 15, 14, 10, turning the support wheel 13 by a certain angle a, which is limited by the spring-loaded stops 21. When the support wheel 13 is rotated, the axis also moves 35 of the latch 34. Since the latch at one end of the compression spring 36 is connected to the housing 2, it will take position 34, entering the groove 37 of the outer wheel 5, reliably fixing it against rotation. At the same time, due to the rotation of the support wheel 13, the eccentric 32 will also turn, which will move the spring-loaded plunger 31 of the brake of the carrier 20. The brake tape 29 will weaken and the carrier 20 will brake. In this mode, the carrier 2 (the second differential mechanism will be braked, and the top wheel 5 of the first differential gear will be braked. The spurious gears 9, gear 10, the hollow shaft 11 and the central wheel 14 of the second differential gear will also be braked (Fig. 3). In this In this case, the electric drive will switch to the second mode of operation.In this kinematic scheme, the rotation of the motor shaft 1 (in either direction) is transmitted through gears 19, 18, 17, satellites 16, 15, and the carrier 20 of the second differential mechanism, and together with it and the central shaft 4 with the central wheel 3. When the outer wheel 5 is braked, the torque, as in the first case, will be supplied to the carrier shaft 6, providing it with a reduced (second) speed of rotation with a large torque on the locking body. the locking body from the place of the torque on the output shaft of the carrier 6 drops sharply, When the load on the drive shaft of the locking body decreases to the point that when the elastic stops 21 provide reverse rotation of the support wheel 13, it will return to its original position. In this case, the latch 34 of the stopper will release the outer wheel, and the cam 32 will release the spring-loaded plunger 31,

providing braking of the carrier 20 by the brake tape 29. The drive will go to work in the initial mode with increased speed described above.

By appropriate selection of gears, you can change the range of the ratio of the speeds of the two modes of operation of the electric drive. Moreover, it is possible to provide even a reduced speed of rotation of the output shaft in the first mode of operation of the electric drive and an increased speed in the second mode.

In the claimed electric drive, the transition from one transmission speed to another and vice versa is carried out without dynamic loads, automatically, when the load torque on the output shaft changes. In addition, the absence of switching devices in the transmission of the electric drive increases the reliability of the electric drive. In addition, when using this electric actuator, reliable and quick opening and closing of shut-off valves is ensured.

Claims (1)

An electric drive comprising an electric motor and a gearbox housed in a housing with a first differential gear made in the form of a planetary gear with a central gear wheel mounted on a central shaft, an external gear wheel, an output carrier shaft, satellites, spurious gears interacting with an external gear wheel and pinion mounted on a hollow shaft covering the Central shaft, while the shafts of spurious gears are fixed on a support freely mounted on the hollow shaft, characterized in that it is equipped with a second differential mechanism, made in the form of a central gear mounted on a hollow shaft, satellites kinematically connected by a gear pair with the motor shaft, and normally driven by a carrier brake, rigidly fixed to the central shaft, in addition, the first differential mechanism is equipped with a stopper, containing a latch spring-loaded relative to the housing, interacting with grooves made on the side surface of the outer wheel, and the bearing of the parasitic shafts Ester is provided with a spring-loaded against the housing stops from rotating about the central shaft and kinematically connected with a latch stopper outer wheel carrier termozom and second differential mechanism.