RU2688929C1 - Electric machine - Google Patents

Abstract

FIELD: electrical engineering.SUBSTANCE: invention relates to the field of electrical engineering, namely to cooling systems of closed electric machines with a liquid-cooled stator. Electric machine comprises housing, stator with windings, rotor with magnetic conductor arranged on its hub and located outside the stator. In the housing on one end side of the stator there is an inlet annular cavity communicated with the cooling liquid source, and on the opposite side there is an outlet annular cavity communicated with the inlet cavity. Rotor hub surface and wall outer surface forming outlet cavity, form an annular centrifugal cavity located on the end side of the output cavity and around the latter with the possibility of communicating the centrifugal cavity with the outlet annular cavity by means of at least one radial hole made in its wall. A condensation annular cavity is formed in the housing outside the rotor. Radial through channels are made in rotor hub to feed cooling liquid from centrifugal cavity to condensation one.EFFECT: higher efficiency of machine operation.9 cl, 5 dwg

Description

The invention relates to the field of electrical engineering, in particular to cooling systems of closed electric machines with a cooled stator.

Known electric inductor machine comprising a housing inside which is placed a stator with teeth, on which electrical windings are wound, a rotor, on the hub of which a magnetic core is placed, located inside the housing on bearings, while the inlet and outlet cavities are made in the housing for the passage of cooling fluid past the stator windings (RU 2249898 C2, published. 10.23.2001).

The disadvantages of the known machine are the low efficiency of the machine as due to increased mechanical losses associated with the rotation of the rotor in a liquid medium, as well as due to insufficient cooling efficiency of the machine elements associated with the lack of directional organization of the movement of coolant past the heated parts of the machine.

The technical result of the invention is to increase the efficiency of the machine by reducing mechanical losses and reducing the uneven heating of the parts of the machine.

The task is achieved by the fact that the electric inductor machine includes a housing inside which is placed a stator with teeth, on which electrical windings are wound, a rotor with a hub, magnetic core and magnets located inside the housing on bearings and outside the stator, while in the housing with one end An annular inlet cavity is formed on the side of the stator. It communicates with a coolant source. With the inlet cavity with the possibility of coolant passing through the gaps between the windings from the inlet cavity, the surface of the rotor hub and the outer surface of the wall forming the outlet cavity form an annular centrifugal cavity located on the end side of the output cavity and around the latter with the possibility of communication of the centrifugal cavity with an output annular cavity using at least one radial hole made in its wall, condensation rings are formed in the housing outside the rotor I have a cavity, radial through channels are made in the hub of the rotor with the ability to supply coolant from the centrifugal cavity to the condensation and transfer heat of the coolant to the internal heat exchange surface of the housing by casting the cooling heat on it through the cooling rotor when the rotor rotates, and in the case there is an outlet for cooling fluid from the condensation cavity.

The task is also achieved by the fact that the internal heat exchange surface of the condensation cavity can be made cylindrical.

The task is also achieved by the fact that the condensation cavity can be used as a collector of coolant that has given off heat, from which the liquid is returned to the inlet annular cavity of the stator.

The task is also achieved by the fact that the hub of the rotor can be used as a centrifugal vane pump or no-blade pump with a continuous inseparable wall that prevents the passage of coolant through the hub.

The task is achieved by the fact that in the stator can be made axial channels for the passage of coolant from the inlet annular cavity in the output.

The task is also achieved by the fact that in the magnetic core and the rotor magnets can be performed additional radial channels for the passage of coolant into the condensation cavity.

The task is also achieved by the fact that all the radial holes in the wall of the output annular cavity can be located in its part opposite to the outlet of the condensation cavity relative to the axis of rotation of the rotor.

The task is also achieved by the fact that it may contain a heat exchanger through which coolant is pumped before it enters the inlet annular cavity.

The task is achieved by the fact that as a lubricating fluid of the rotor bearings can use a coolant.

The invention is illustrated using the drawings.

FIG. 1 shows a longitudinal section of a variant of a machine with an external coolant capacity;

FIG. 2 is a longitudinal section of a variant with an internal coolant capacity;

FIG. 3 is a cross-section of the machine;

FIG. 4 shows a partial view of the cross section of the rotor 5;

FIG. 5 - local view of the longitudinal section of the machine.

The described machine includes a housing 1, inside of which is placed a stator 2 with teeth, on which electrical windings 3 are wound. The rotor 5 is provided with a hub 4, a magnetic core 6 and magnets 7. The rotor 5 is located inside the housing 1 on the bearings 8 and outside the stator 2. In the housing 1 On one end side of the stator 2, an input annular cavity 9 is formed, communicated with a source of coolant, for example, with a capacity of 10, which can be installed outside the housing 1. Alternatively, the internal cavity of the housing 1 is used as the container 10. On the end side is a stat Pa 2, opposite the inlet cavity 9, is the output annular cavity 11 connected to the input cavity 9 with the possibility of coolant passing through the gaps between the windings 3 from the input cavity 9. The surface of the hub 4 and the outer surfaces of the wall 12 forming the output cavity 11, form an annular centrifugal cavity 13, located on the end side of the output cavity 11 and around the latter with the possibility of communication of the centrifugal cavity 13 with the output annular cavity 11 by means of at least at least one radial hole 14. In case 1, a condensation annular cavity 15 is formed outside the rotor 5, radial through channels 16 are made in the hub 4 of the rotor 5 with the ability to supply coolant from the centrifugal cavity 13 to the condensation cavity 15 and transfer heat during rotation of the rotor 5 coolant to the internal heat exchange surface of the housing 1 by throwing coolant on it, and in the housing 1 there is an outlet 17 for exiting the coolant from the condensation cavity 15.

The internal heat exchange surface of the condensation cavity 15 is cylindrical.

The hub 4 of the rotor 5 can be used as a centrifugal vane or bezlopochatnogo pump. In this case, the wall can be made with through holes or with a continuous unbreakable wall that prevents the passage of coolant through the hub 4.

In the stator 2 can be made axial channels 18 for the passage of coolant from the input annular cavity 9 into the output cavity 11.

In the magnetic circuit 6 can be made additional radial channels 19 for the passage of coolant into the condensation cavity 15.

All radial holes 14 (or a single hole 14) in the wall 12 of the output annular cavity 11 can be located in its part opposite to the outlet 17 of the condensation cavity 15 relative to the axis of rotation of the rotor 5. That is, when its orientation is coordinated with the consumer of the machine 14 are performed in the upper part of the annular cavity 11, and the outlet 17 in the lower part of the condensation cavity 15.

The machine may additionally contain a heat exchanger (not shown in the drawings) through which coolant is pumped before it enters the inlet annular cavity 9.

For lubrication of bearings 8 of the rotor 5 use the coolant of the machine.

The described invention works as follows. The magnetic circuit 6 with the magnets 7 of the rotor 5 rotates outside the stationary windings 3 of the stator 2. Coolant is supplied into the input annular cavity 9 located on the end side of the stator 2 and fills the annular cavity 9. Then, through the gaps between the windings 3, the liquid flows in the axial direction along the stator 2 to its opposite end side and is collected in the output annular cavity 11. At the same time, along the stator 2, the liquid can also flow along the axial channels 18. In the teeth of the stator 2 to increase the heat exchange surface Additional through channels are also made (not shown in the drawings).

From the output annular cavity 11, the liquid enters the annular centrifugal cavity 13 through one or more radial holes 14, which are performed in the wall 12, mainly the upper part of the output annular cavity 11. Centrifugal forces during the rotation of the rotor 5 contribute to the movement of coolant from the centrifugal cavity 13 into the condensation cavity 15 through the radial through channels 16 in the hub 4. The liquid spreading through the gap between the stator 2 and the magnets 7 also enters the condensation cavity 15 through additional radial channels 19 in the magnetic circuit 6. The liquid falling on the internal heat exchange surface of the housing 1 in the condensation cavity 15 transfers heat from the internal parts of the machine to the external heat exchange circuit located outside the housing 1. The external heat exchange circuits can be the external cooling fins 20 of the housing 1 blown by air, or liquid cooling jacket with additional liquid circuit (not shown). Inside the condensation cavity 15, the coolant is collected in its lower part. When executing the variant with a “dry” case (see FIG. 1), the liquid is pumped out into the external tank 10, from which it is again supplied to the inlet annular cavity 9, for example, after its additional cooling in a heat exchanger (not shown).

Since the cooling cavities of the stator 2 are separated from the total volume of the housing, the required volume of liquid is minimal, which significantly reduces the weight and dimensions of the machine. In addition, the absence of a constantly filled fluid cavity in the region swept by the rotor significantly reduces mechanical losses.

Strict organization of the movement of fluid with an accentuated contact with the most heated parts of the machine increases the efficiency of its cooling and reduces the uneven heating of its parts.

Claims (9)

1. An electric induction machine comprising a housing inside which a stator is mounted with teeth, on which electrical windings are wound, a rotor with a hub, magnetic circuit and magnets located inside the housing on the bearings and outside the stator, while the input is formed in the housing on one end side of the stator an annular cavity communicated with a source of coolant, on the other end side of the stator opposite the inlet cavity, there is an outlet annular cavity communicated with the inlet cavity with the possibility When the coolant passes through the gaps between the windings from the inlet cavity, the surface of the rotor hub and the outer surface of the wall forming the outlet cavity form an annular centrifugal cavity located on the front side of the output cavity and around the latter with the possibility of centrifugal cavity communication with the output annular cavity when assistance made in its wall at least one radial hole in the housing outside the rotor is formed of a condensation annular cavity, in the rotor hub made radial through channels with the possibility of supplying coolant from the centrifugal cavity to the condensation and transferring the coolant heat to the internal heat exchange surface of the housing by throwing coolant thereto, and an outlet for cooling fluid from the condensation cavity. 2. Electrical machine under item 1, characterized in that the internal heat exchange surface of the condensation cavity is cylindrical. 3. The electric machine according to claim 1, characterized in that the condensation cavity is used as a collector of coolant that has given off heat, from which the liquid is returned to the inlet annular cavity of the stator. 4. Electric machine under item 1, characterized in that the hub of the rotor is used as a centrifugal vane or bezlopochatnogo pump with a continuous unbroken wall, preventing the passage of coolant through the hub. 5. Electrical machine under item 1, characterized in that the stator is made of axial channels for the passage of coolant from the inlet annular cavity to the output. 6. The electric machine according to claim 1, characterized in that additional radial channels are made in the magnetic core and the rotor magnets for the passage of coolant into the condensation cavity. 7. The electric machine according to claim 1, characterized in that all the radial holes in the wall of the outlet annular cavity are located in its part opposite to the outlet of the condensation cavity relative to the axis of rotation of the rotor. 8. The electric machine according to claim 1, characterized in that it contains a heat exchanger through which coolant is pumped before it is fed into the inlet annular cavity. 9. Electrical machine under item 1, characterized in that as the lubricant fluid of the rotor bearings use coolant.

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