RU2538394C1 - Geared engine for mill drive - Google Patents

Abstract

FIELD: engines and pumps.

SUBSTANCE: geared motor comprises gearing 1 including planetary stage with vertical or horizontal shaft. Note here that the housing of gearing 1 incorporated motor connected to lubricant feed line for motor cooling by lubricant circulation. Motor rotor 21 and stator 22 feature axles arranged parallel about gearing shaft. Lubricant impermeable shell serves to isolate motor rotor 21 and/or stator 22 windings from circulating lubricant. Additionally, electric power converter 23 with matched adjustment device for motor rpm adjustment without play in engagement. Crown gear 14 of planetary stage is surrounded radially by both rotor and stator.

EFFECT: ruled out damages.

10 cl, 1 dwg

Description

Known drive systems comprise one or more gear stages for converting drive power of an electric motor. At the same time, the transmission steps and the electric motor form a transmission that is subjected to a significant reverse effect of the processing process, which is closely connected with the processing inside, for example, a disk mill, mixing drum, crusher, tube mill or rotary tube furnace. Bevel gear stages are commonly used to connect an electric motor to a transmission.

DE 3931116 A1 describes a drive device for a mill with a vertical structure, in which the upstream gear housing is stationary screwed to the mill. This requires accurate alignment of the axes of the drive gear and the gear ring lying far from each other. In addition, the input of the axial forces of the mill through the thrust bearing into the common gear housing causes significant gear loads in the upstream gear. Due to the general large internal transmission space and the mill support, there is a rapid contamination with lubricating oil for the drive unit. In addition, mechanical power splitting in an upstream gear is problematic given the lack of compensation for numerous coupling reactions.

From JP 2005052799 A, a drive device for a vertical crusher is known which is driven by a ring gear on a rotating bottom disk or by a bevel gear transmission. Due to the lack of adjusting mobility in the drive stage of the drive device, shock loads from the processing process are transferred to the drive device, in particular to its gears.

WO 2008/031694 A1 discloses a mill drive system with a gear located under a bowl of runners. The gear contains at least one planetary stage and has a vertical shaft position. An electric motor is integrated into the transmission housing, which is connected to the circulation circuit of the lubricant transmission means, the stator and rotor of which have vertically extending axes and whose cooling is carried out by means of a lubricant circulating through the transmission.

WO 2009/068484 A1 describes a cylindrical gear train with one or more gear stages for driving a working machine surrounded by a gear rim, which comprises a gear housing for accommodating the gear steps and a gear that is engaged on the output shaft of the output step for adjusting, which is engaged with gear ring. The transmission housing consists of a first rigid part of the housing itself and a second stationary part of the housing. The first part of the housing surrounds the output stage with the output shaft and is movable for the purpose of regulating the gear and has side walls protruding above the transmission, which are supported by the foundation. The second part of the casing is fixed on the front side of the first part of the casing without touching the foundation.

From WO 2010/20287 a mill drive system is known with an integrated motor and transmission unit, which has a common cooling circuit. The electric motor and transmission unit rests on the bottom plate containing the electric motor and transmission unit of the housing.

An earlier European patent application 09011589.0 describes a mill drive system comprising a gear located under at least one planetary and / or cylindrical gear stage and an electric motor integrated in the gear housing. In addition, the mill drive system includes an electric energy converter with a coordinated adjustment device for controlling the rotation speed of the electric motor without backlash in gearing.

Therefore, the basis of this invention is the task of creating a gear motor for the drive system of the mill, which provides the possibility, on the one hand, to prevent damage to the transmission due to short interruptions in the transmission and, on the other hand, to reduce bending forces from the grinding process.

This problem is solved according to the invention using a gear motor for the drive system of the mill with the characteristics specified in paragraph 1 of the claims. Preferred modifications of the invention are indicated in the dependent claims.

The gear motor according to the invention comprises a gear located below the runner bowl or to the side of the mill drum, comprising at least one planetary stage which has a vertical or horizontal shaft position. In addition, an electric motor is integrated into the transmission housing, which is connected to the circulation circuit of the lubricant supply. The rotor and stator of the electric motor have axles extending parallel to the position of the transmission shaft. The motor is cooled using a lubricant circulating through the transmission. In addition, a sheath is provided for the lubricating oil for the rotor windings, respectively, of the stator of the electric motor, for sealing against the lubricant circulating inside the housing. In addition, the mill drive system according to the invention comprises an electric energy converter with a coordinated adjustment device for controlling the rotation speed of the electric motor without a play in engagement. The planetary ring gear is radially surrounded by both the rotor and the stator. The rotor and stator are preferably arranged concentrically on the planetary gear ring gear. Due to the location of the electric motor around the ring gear of the planetary gear, a shortened structural length can be realized. This results in a minimized bending shoulder length for linkage forces from the grinding process. Based on the location of the electric motor around the ring gear of the planetary gear, it is also possible to refuse the cardan connection between the electric motor and the transmission, as well as from the external foundation for the electric motor.

Based on the integration of the electric motor into the circulation of the transmission lubricant, complex ventilation measures can be abandoned to sufficiently cool the electric motor. Due to the use of an electric energy converter to control the rotation speed of the electric motor, isolation between the power supply from the network and the torque of the electric motor is possible. In this way, damage to the gearing can be prevented during short interruptions due to a network failure, since due to a network failure based on the regulation according to the invention, the rotation speed of the electric motor does not cause a backlash in the gearing in the direction of rotation in the transmission. In addition, due to the fully vertical or horizontal arrangement of the runner bowl, gear and electric motor, the relatively expensive bevel gear can be rejected. In addition, due to the rejection of the bevel gear and air cooling of the electric motor, the noise of the transmission is significantly reduced.

Through the use of an electric energy converter, many application-specific gear ratios can be realized with a reduced number of types of gear structural elements. In addition, by controlling the speed of rotation, each processing process can be carried out using the drive system of the mill according to the invention at the optimum operating point. Due to this, the grinding process efficiency is improved. This, in turn, provides a reduction in energy consumption.

The electric motor can be made, for example, in the form of an electric motor with an external rotor. In this case, the ring gear of the planetary gear forms the stator support. According to another embodiment of the invention, the shaft of the central wheel of the at least one planetary stage is connected to the support of the rotor. At least one axially extending opening may be provided in the rotor support for the release of the lubricant from the transmission into the collector zone or the receiving reservoir for the lubricant. As an alternative to performing an electric motor with an external rotor, the electric motor can also be made with an internal rotor. In this case, the crown gear of the planetary gear is preferably connected without the possibility of rotation with the rotor.

According to a preferred embodiment of the invention, seals are only provided on the outlet cup, lubricant supply lines, electrical energy supplies and at least one supply for the measuring device. This provides a further reduction in the number of mechanical structural elements, which contributes to increased reliability.

According to one preferred modification of the present invention, the electric motor is a permanent magnet driven synchronous machine, the rotor magnetic system of which is welded into a stainless steel casing. Since there is thus no heat loss in the rotor, cooling of the rotor is not required. As an alternative to a synchronous machine with permanent magnet excitation, the electric motor can also be in the form of an asynchronous squirrel-cage electric motor.

The following is a more detailed explanation of the invention based on an exemplary embodiment with reference to the accompanying drawing, which shows a section of the drive system of a mill with a gear motor according to the invention.

The mill drive system shown in the drawing comprises a gear 1 with two planetary steps located under the runner bowl. Both the planetary stage located on the drive side and the planetary stage located on the output side have a vertical shaft position. Both planetary steps contain each ring gear, a carrier with planetary gears mounted on it and a central planetary gear wheel. The ring gears of the planetary stages are fixedly connected to the transmission housing 11. The carrier of the planetary stage located on the exit side is intended to be connected to the runner bowl and mounted using a thrust bearing 13. The central wheel of the planetary stage located on the drive side is connected to the rotor shaft 28 of the electric motor 2 integrated in the transmission housing 11, which has a rotor 21 and is radially surrounding its stator 22. The rotor 21 and stator 22 have axles extending vertically.

The ring gear 14 of the planetary stage located on the drive side is radially surrounded by both the rotor 21 and the stator 22. In this case, the rotor 21 and the stator 22 are concentric with the ring gear 14 located on the planetary stage of the drive side. In this embodiment, the electric motor 2 is made in the form of an electric motor with an external rotor. In this case, the ring gear 14 of the planetary stage located on the drive side forms a stator support. The rotor shaft 28, or the shaft of the central wheel located on the drive side of the planetary stage, is connected to the rotor support 27, on which the rotor 21 rests.

As an alternative to the embodiment with an external rotor shown in the drawing, the electric motor 2 can, in principle, also be made with an internal rotor. In this case, the ring gear 14 of the planetary stage located on the drive side can be connected without rotation with the rotor 21.

The rotor shaft 28 is installed by means of a radial bearing 24 located between the electric motor 2 and gear 1, located under the electric motor 2 in the crankcase 12 for the lubricant of the radial bearing 25, and also located under the electric motor 2 of the thrust bearing 26. Thus, with a relatively short shaft 28 the rotor is provided with very good centering of the rotor 21. The rotor shaft 28 and the central wheel of the planetary stage located on the drive side are preferably connected via clutch above or below electric motor 2. In addition, in this embodiment, the planetary gears of the planetary stage located on the drive side and the central wheel of the planetary stage located on the output side are connected to each other.

The electric motor 2 is connected to the circulation circuit of the lubricant supply gear 1, in which the lubricant is pumped from the crankcase 12 of the lubricant to the lubrication points in the gear 1 and from there through the electric motor 2 flows into the crankcase 12 of the lubricant. Thereby, the motor 2 is cooled by means of a lubricant circulating through gear 1. At the same time, at least one lubricant supply channel not shown in the figure leads to stator cooling fins along which the lubricant circulating through transmission 1 passes. In addition, lubricating oil can be purposefully sprayed to cool the stator 22, which passes through the cooling devices of the stator 22.

A rotor shell 21 impervious to lubricating oil is provided on the rotor support 27 for sealing against a lubricant circulating inside the housing. A significant increase in the air gap of the electric motor 2 is not required, since due to the envelope impermeable to lubricating oil, it increases only slightly. The electric motor 2 in this embodiment is a synchronous machine with permanent magnet excitation, while the rotor magnetic system is welded in a stainless steel casing. This provides an especially small electrical loss.

In addition, the mill drive system shown in the drawing has an electric energy converter 23 with a corresponding adjustment device for controlling the rotation speed of the electric motor 2 without backlash in the gearing, so that there is no gap between the side surfaces of the gear teeth 1 in the direction of rotation. The mechanical eigenfrequencies of the mill gear motor system are not critical when using the electric power converter 23 due to the isolation of the system components. In this case, the lateral surfaces of the teeth of the transmission 1 are kept in constant power circuit due to the application of minimum torque. Due to this, the loads of the tooth flanks are eliminated as much as possible due to a change in the direction of rotation.

The application of the present invention is not limited to this embodiment.

Claims (10)

1. The gear motor for the drive system of the mill, containing
- located under the bowl for runners or on the side of the mill drum transmission containing at least one planetary stage, which has a vertical or horizontal shaft position,
- an electric motor integrated in the transmission housing, which is connected to the circulation path of the lubricant transmission means, the rotor and stator of which have axles parallel to the position of the transmission shaft and which are cooled by means of a lubricant circulating through the transmission, characterized in that
- impermeable to lubricating oil sheath for the windings of the rotor and / or stator of the electric motor for sealing relative to the circulating lubricant inside the housing,
- an electric energy converter with an adjustment device coordinated with it for regulating an electric motor rotation speed without a play in engagement,
- a ring gear of at least one planetary stage, which is surrounded in the radial direction by both the rotor and the stator. 2. The gear motor according to claim 1, in which the rotor and stator are concentric with the planetary gear ring gear. 3. The gear motor according to any one of claims 1 or 2, in which the electric motor is made in the form of an electric motor with an external rotor and in which the ring gear forms a stator support. 4. The gear motor according to claim 3, in which the Central wheel of at least one planetary stage connected to the support of the rotor. 5. The gear motor according to any one of claims 1 or 2, in which the electric motor is made in the form of an electric motor with an internal rotor and in which the ring gear is connected without rotation with the rotor. 6. The gear motor according to any one of claims 1 or 2, in which the channel for supplying lubricant passes to at least one cooling rib of the stator, through which the flow of lubricant circulating through the transmission passes. 7. The gear motor according to any one of claims 1 or 2, in which the electric motor is located under the transmission and in which a collector zone or reservoir for the lubricant is provided under the electric motor. 8. The gear motor according to claim 7, in which at least one axially extending hole is provided in the rotor support for the release of the lubricant from the transmission into the manifold zone or the receiving reservoir for the lubricant. 9. The gear motor according to any one of claims 1 or 2, in which the seals are provided only on the output cup, lubricant supply pipelines, electrical energy supplies and at least one supply for the measuring device. 10. The gear motor according to any one of claims 1 or 2, in which the electric motor is a synchronous machine with permanent magnets, the magnetic system of the rotor of which is welded into a stainless steel casing.