JP6210957B2 - Lubricating oil discharge mechanism - Google Patents

Description

  The present invention relates to a lubricating oil discharge mechanism for a bearing portion of a rotating electrical machine.

  The rotating electrical machine includes a rotor and a stator. The rotor usually has a rotor shaft that rotates about its axis and a rotor core that is provided on the outer side in the radial direction of the rotor shaft. The stator has a cylindrical stator core and a stator coil wound around a tooth portion formed on the stator core.

  In a horizontal rotary electric machine, the rotor shaft extends horizontally. The rotor shaft is rotatably supported by bearings provided on both axial sides of the rotor core.

  Lubricating oil for bearing lubrication is supplied to bearings (especially sliding bearings). The lubricating oil supplied to the bearing and lubricating the bearing passes through the bearing, and then drops and is stored in an oil receiver provided below the bearing.

  In order to prevent further leakage from the oil receiver in the axial direction, there is an example in which the lubricating oil leaked from the adjacent chamber of the oil receiver is guided to the outside (Patent Document 1).

Japanese Utility Model Laid-Open No. 4-121370

  FIG. 4 is an elevational sectional view around the bearing 15 in the conventional example. The bearing bracket 20 that supports the bearing 15 may be provided with a communication pipe 31 for equalizing the inside and outside of the bearing 15 so that the oil around the bearing 15 does not leak inside or outside due to a pressure difference with the outside air. . The communication pipe 31 extends from the inner portion of the bearing bracket 20 and is connected to the through hole 27 of the bearing bracket 20, and is open to the atmosphere through the through hole 27.

  Lubricating oil leaks through the communication line from the communication pipe 31 to the through hole 27 due to rotation of the rotor shaft 11 by the operation of the rotating electrical machine, and the surroundings are soiled by dripping at a portion opened to the atmosphere. There is a case.

  Therefore, an object of the present invention is to prevent the lubricating oil leaking from the bearing portion via the communication line from fouling the surroundings in the rotating electrical machine.

In order to achieve the above-mentioned object, the present invention provides a lubricating oil discharging mechanism for discharging lubricating oil leaking from a bearing of a rotating electrical machine that rotatably supports a rotor shaft around a main shaft extending in a horizontal direction. A communication pipe that is connected to a through-hole penetrating in the direction of the main shaft below the bearing of the bearing bracket that partitions the axially inner side and the axially outer side, and that communicates the inner part of the bearing and the outside air; One end portion is connected to the through hole of the bearing bracket from the outside, and the vicinity of the other end portion is connected to the outlet pipe extending horizontally and having a weir at the end, and the lower portion of the outlet pipe. A discharge pipe that extends downward and has a lower end open, and a valve that is provided on the discharge pipe and configured to store and discharge the lubricating oil in a portion of the discharge pipe from a branch portion with the outlet pipe. With Said end portion of said outlet pipe, characterized in that lubricating oil oil level of the derived tract of the inside of the dam can be confirmed visually from the outside through the upper opening of the weir.

  According to the present invention, in the rotating electrical machine, it is possible to prevent the lubricating oil leaking from the bearing portion via the communication line from fouling the surroundings.

It is an elevational sectional view around the bearing including the lubricating oil discharge mechanism according to the embodiment. It is an elevation sectional view of the lubricating oil discharge mechanism concerning an embodiment. It is a front view of the lubricating oil discharge mechanism which concerns on embodiment. It is a sectional elevation around a bearing in a conventional example.

  Hereinafter, a lubricating oil discharging mechanism according to an embodiment of the present invention will be described with reference to the drawings.

  FIG. 1 is a vertical sectional view around a bearing including a lubricating oil discharge mechanism according to the embodiment. At the place where the rotor shaft 11 is rotatably supported around the main axis, the diameter of the funnel shaft 11 is formed to be slightly thinner. A bearing 15 is provided on the radially outer side of this portion of the rotor shaft 11. The bearing 15 is, for example, a sliding bearing, and has two parts in a half crack, and supports the rotor shaft 11 as a bearing in which the two parts are joined and a through hole is formed in the center. The inner surface of the through hole formed in the bearing 15 faces the outer surface of the rotor shaft 11 with a minute clearance. Lubricating oil is supplied from the oil supply port 21, and when the rotor shaft 11 is rotated, a film of lubricating oil is formed on the clearance of the bearing surface.

  The bearing 15 is supported by a bearing support portion 26 of the bearing bracket 20. The outer surface of the bearing 15 has a shape in which a cross section passing through the main shaft has an arc. The outer surface of the bearing 15 and the bearing support portion 26 are in contact with each other on the surface of the arcuate rotating body, thereby restraining the rotor shaft 11 not only in the radial direction but also in the main axis direction.

  The bearing bracket 20 is formed with an outer air chamber 22, an outer oil sump 23, an inner oil sump 24, and an inner air chamber 25 in order from the outer side, that is, the side opposite to the rotor core (not shown) in the main shaft direction. The outer oil sump 23 and the inner oil sump 24 are respectively adjacent to the bearing support portion 26 and arranged on opposite sides of the bearing support portion 26. A labyrinth packing is provided on a surface of the partition between the outer oil reservoir 23 and the outer air chamber 22 facing the rotor shaft 11 to form a labyrinth portion. Similarly, a labyrinth packing is provided on the surface of the partition between the inner oil sump 24 and the inner air chamber 25 facing the rotor shaft 11 to form a labyrinth portion.

  A through hole 27 is formed in the bearing bracket 20. A communication pipe 31 is provided so as to connect the inner air chamber 25 and the through hole 27. The connection between the communication pipe 31 and the through hole 27 of the bearing bracket 20 may be a screw connection or welding. A lead-out pipe 51 is provided outside the through hole 27. The connection between the outlet pipe 51 and the through hole 27 of the bearing bracket 20 may be a screw connection or welding. Alternatively, a sleeve (not shown) that seals between the outer bearing brackets 20 may be passed through the through-hole 27, and the sleeve and the communication pipe 31 and the sleeve and the outlet pipe 51 may be joined.

  Alternatively, a female thread is formed on the inner surface of the through hole 27, a screw is formed on the outer side of the outlet pipe 51, and the outer portion excluding the communication pipe 31 of the lubricating oil discharge mechanism 50 described later is integrated to form the outlet pipe 51. A method of screwing into the through hole 27 may be adopted.

  FIG. 2 is an elevational sectional view of the lubricating oil discharge mechanism 50 according to the embodiment. FIG. 3 is a front view. The lubricating oil discharge mechanism 50 includes a communication pipe 31, a lead-out pipe 51, a discharge pipe 53, and a valve 54 provided in the discharge pipe 53.

  The lead-out pipe 51 extends to the outside of the bearing bracket 20 by coupling the first end to the through hole 27 of the bearing bracket 20. The outlet pipe 51 is routed horizontally. Here, the term “horizontal” includes a so-called drain gradient, that is, a case where there is a slight inclination for determining the liquid flow direction. A weir 52 is provided at the second end of the lead-out pipe 51, that is, at the end different from the first end coupled to the through hole 27 of the bearing bracket 20. That is, the end plate 52a is provided in the lower half of the open portion of the second end portion. As a result, a dam opening 52b is formed in the upper half.

  A discharge pipe 53 branches off from the lower surface of the outlet pipe 51 in the middle of the outlet pipe 51 and extends vertically downward. The inside of the discharge pipe 53 communicates with the inside of the outlet pipe 51. The lower end of the discharge pipe 53 is open. A valve 54 is provided in the middle of the discharge pipe 53. The valve 54 is provided with a handle 54a, and the valve 54 can be opened and closed by the handle 54a.

  In the present embodiment formed as described above, when the lubricating oil leaks through the communication line from the communication pipe 31 to the through hole 27 due to the rotation of the rotor shaft 11 by the operation of the rotating electrical machine, the leakage has occurred. The lubricating oil is further guided to the outlet pipe 51.

  The lubricating oil guided to the outlet pipe 51 is stored in the weir 52. The state in which the lubricating oil is accumulated in the weir 52 can be easily confirmed by looking inside the outlet pipe 51 from the weir opening 52b.

  Since the amount of lubricating oil that leaks through the labyrinth portion of the partition between the inner oil reservoir 24 and the inner air chamber 25 is small, the increasing speed of the lubricating oil that accumulates in the weir 52 is small. For this reason, the lubricating oil does not overflow the weir 52 at regular inspection intervals. When the increase rate is large, the diameter of the outlet pipe 51 is increased, the length is increased, the height of the end plate 52a of the weir 52 is increased, or the diameter of the discharge pipe 53 is increased. As a result, the capacity for storing the lubricating oil can be increased.

  However, if the discharge pipe 53 has a storage capacity, after the discharge pipe 53 becomes full, the level of the stored lubricating oil exceeds the height of the end plate 52a of the weir 52, and the lubricating oil does not flow. Care must be taken because the time to overflow is shortened.

  The accumulated lubricating oil can be easily discharged by operating the handle 54a of the valve 54.

  As described above, according to the present invention, it is possible to prevent the lubricating oil leaked through the communication line from fouling the surroundings.

  As mentioned above, although embodiment of this invention was described, embodiment is shown as an example and is not intending limiting the range of invention. Furthermore, the embodiments can be implemented in various other forms, and various omissions, replacements, and changes can be made without departing from the spirit of the invention. The embodiments and the modifications thereof are included in the scope of the invention and the scope of the invention, and are also included in the invention described in the claims and the equivalents thereof.

  DESCRIPTION OF SYMBOLS 11 ... Rotor shaft, 15 ... Bearing, 20 ... Bearing bracket, 21 ... Oil supply port, 22 ... Outer air chamber, 23 ... Outer oil sump, 24 ... Inner oil sump, 25 ... Inner air chamber, 26 ... Bearing support part, 27 DESCRIPTION OF SYMBOLS ... Through-hole, 31 ... Communication pipe, 50 ... Lubricating oil discharge mechanism, 51 ... Outlet pipe, 52 ... Weir, 52a ... End plate, 52b ... Weir opening, 53 ... Discharge pipe, 54 ... Valve, 54a ... Handle

Claims (3)

In a lubricating oil discharge mechanism that discharges lubricating oil leaking from a bearing of a rotating electrical machine that rotatably supports a rotor shaft about a main shaft extending in a horizontal direction,
A communication pipe for connecting the inner part of the bearing and the outside air connected to a through-hole penetrating in the direction of the main shaft below the bearing of the bearing bracket that supports the bearing and partitions the inner side in the axial direction and the outer side in the axial direction;
A lead-out pipe provided outside the bearing bracket, having one end connected to the through-hole of the bearing bracket from the outside, the vicinity of the other end extending horizontally, and having a weir at the end;
A discharge pipe connected to the lower part of the outlet pipe and extending downward and having a lower end opened;
A valve provided on the discharge pipe and configured to store and discharge the lubricating oil in a portion of the discharge pipe from a branch portion with the outlet pipe ;
With
The lubricating oil discharging mechanism according to claim 1, wherein the end portion of the outlet pipe can be visually confirmed from the outside through the opening above the weir with the oil level of the lubricating oil in the outlet pipe inside the weir. The internal thread of the inner surface of the through-hole of the bearing bracket is formed, a male thread is formed at the end of the outlet pipe, and the outlet pipe can be screwed into the bearing bracket. The lubricating oil discharge mechanism described in 1. The bearing is a sliding bearing having an outer oil sump and an inner oil sump that are adjacent to each other in the axial direction for receiving the lubricating oil, and an inner air chamber provided on the inner side in the axial direction of the inner oil sump.
The lubricating oil discharging mechanism according to claim 1 , wherein the inner portion is the inner air chamber .

Images