This disclosure relates to rotors of electric machines.
Electric machines covert between electrical energy and mechanical energy. As one example, an electric machine may operate as a generator that converts mechanical energy into electrical energy. As another example, an electric machine may operate as an electrical motor that converts electrical energy into mechanical energy. Electric machines typically include a rotor that rotates within a stator. Energy flows through the stator to or from the rotor. In an electric motor, the stator provides a rotating magnetic field that drives the rotor. In a generator, the stator converts the rotating magnetic field to electric energy.
In one example, a rotor of an electric machine includes a main rotor body having a longitudinal axis, the main rotor body comprising: a hollow cylinder body with a first end and a second end; an integral end flange at the first end; a separate end flange disposed at the second end of the cylinder body; and laminations disposed on an outer surface of the cylinder body, the laminations comprising magnetic material.
The details of one or more examples are set forth in the accompanying drawings and the description below. Other features, objects, and advantages will be apparent from the description and drawings, and from the claims.
Electrical machines may be used to provide energy to, or extract energy from, rotating devices. As one example, an electrical generator may convert rotational mechanical energy extracted from a combustion motor into electrical energy. As another example, an electrical motor may provide rotational mechanical energy to assist with starting a combustion motor. As another example, an electrical motor may provide rotational mechanical energy to drive a propulsor (e.g., fan, propeller, etc.) of a vehicle. An electric machine may operate in various modes at different times. For instance, a particular electrical machine may operate as a starter to start a combustion motor at a first time and operate as a generator to convert rotational mechanical energy generated by the combustion motor into electrical energy at a second time. In this way, an electric machine may operate as an electrical starter-generator.
An electric machine may include a rotor that rotates within a stator. The rotor may include magnets disposed around a cylindrical body of the rotor that interact with windings included in the stator to transfer energy. The diameter of the cylindrical body may be related to the amount of energy than may be transferred. As such, in some cases, it may be desirable for the cylindrical body to have a relatively large diameter (e.g., relative to a shaft connected to the rotor). However, increasing the diameter of the cylindrical body may increase the mass of the rotor, which may undesirably increase the moment of inertia.
In accordance with one or more techniques of this disclosure, a rotor may include a hollow cylindrical body with an end flange on either side to reduce the diameter (e.g., to facilitate connection with a shaft). By using a hollow cylindrical body, the diameter of the cylindrical body may be increased without substantially increasing the moment of inertia.
Additionally, in some examples, it may be desirable to reduce the part count of a rotor. For instance, reducing the part count (e.g., the quantity of components included on a bill of materials (BOM)) for the rotor may reduce the cost, manufacturing time, and/or manufacturing difficulty of the rotor.
In accordance with one or more techniques of this disclosure, an end flange and a cylindrical body may be merged into a single component. For instance, a rotor may include a main rotor body including a hollow cylinder body with a first end and a second end, and an integral end flange at the first end of the main rotor body. A separate end flange (e.g., not included in the single component) may be disposed at the second end of the cylinder body. Merging an end flange and the cylindrical body into a single component may provide various advantages. As one example, reducing the part count by at least one may provide the benefits listed above. As another example, connective hardware between the cylindrical body and end flange that is now integrated may be omitted, thus reducing part count and/or reducing mass.
Rotor 2 may include several components disposed on an outer surface of main rotor body 4. For instance, as shown in the example of
Sleeve 12 may be configured to retain other components on main rotor body 4. For instance, sleeve 12 may retain laminations 8, magnetic material 10, and/or spacers 14 on main rotor body 4. In some examples, sleeve 12 may be formed of a metallic material. As such, in some examples, sleeve 12 may be referred to as a metallic sleeve. In other examples, sleeve 12 may be formed of a non-metallic material. For instance, sleeve 12 may be formed of a composite material.
To assemble rotor 2, end flange 6 may be press-fit into main rotor body 4. In some examples, end flange 6 may be affixed to main rotor body 4 with mounting hardware. Examples of mounting hardware include, but are not limited to, bolts, screws, rivets, or the like.
In some examples, main rotor body 4 may include retention flange 24 positioned proximal to first end 18. Retention flange 24 may retain and/or provide support for other components of rotor 2, such as laminations 8, magnetic material 10, sleeve 12, and spacers 14 (each of which is shown in more detail in the example of
Main rotor body 4 may include one or more shafts disposed at a distal end of end flange 22. For instance, as shown in
As shown in the example of
As discussed above, a resolver may be used to measure a speed and/or position of rotor 2. In some examples, the output of the resolver may be utilized (e.g., by a controller) to manage operation of an electric machine that includes rotor 2.
Main rotor body 4 may include features configured to facilitate attachment of other components of rotor 2 to main rotor body 4. For instance, as shown in the example of
Main rotor body 4 may be fabricated as a single piece of material. As such, no attachment hardware may be necessary to join the components of main rotor body 4.
End flange 6 may include features configured to facilitate attachment to a shaft (e.g., that couples rotor 2 to a motor or engine). For instance, as shown in the example of
As discussed above, rotor 2 may include sleeve 12. In some examples, an outer diameter of sleeve 12 may be greater than an outer diameter of end flange 6. As such and as can be seen in the example of
In some examples, end flange 22 may include features to reduce a hoop stiffness of rotor 2. For instance, as shown in the example of
As discussed above, rotor 2 may include sleeve 12. In some examples, an outer diameter of sleeve 12 may be greater than an outer diameter of end flange 22 and retention flange 24. As such and as can be seen in the example of
As discussed above, end flange 6 may be press-fit into main rotor body 4. When press-fit into main rotor body 4, at least a portion of end flange 6 may extend longitudinally into main rotor body 4. For instance, segments 42 and 44 of end flange 6 may extend into second end 20 of cylinder body 16 of main rotor body 4. In some examples, segments 42 and 44 may have equal outer diameters (e.g., OD42 may be equal to OD44). Segments 42 and 44 may, for example, have different outer diameters (e.g., OD42 may be different than OD44).
For instance, as shown in the example of
In some examples, at least some of the portion of end flange 6 that extends into main rotor body 4 may reside under at least a portion of magnetic material 8. For instance, as can be seen in the example of
As can be seen in the examples of
In some examples, second end 20 of cylinder body 16 may include a pilot configured to receive at least a portion of end flange 6. For instance, as shown in the examples of
As discussed above, rotor 2 may include spacers 14, which may magnetically isolate the flux from the shaft (e.g., spacers 14 may act like air). By including spacers 14, main rotor body 4 may be formed of a material (e.g., magnetic steel) that provides desirable mechanical properties in terms of strength and wear resistance. Spacers 14 may be formed of stainless steel. As shown in the examples of
As shown in the example of
In accordance with one or more techniques of this disclosure, ESG 908 may include a rotor as described in this disclosure. For instance, ESG 908 may include a rotor comprising a main rotor body having a longitudinal axis, the main rotor body comprising: a hollow cylinder body with a first end and a second end; an integral end flange at the first end; a separate end flange disposed at the second end of the cylinder body; and laminations disposed on an outer surface of the cylinder body, the laminations comprising magnetic material. As one example, the separate end flange may be end flange 6 described above. In such examples, end flange 6 may be connected to shaft 914 (or an intermediate shaft) via spline interface 34.
The following examples may illustrate one or more aspects of the disclosure:
Example 1. A rotor of an electric machine, the rotor comprising: a main rotor body having a longitudinal axis, the main rotor body comprising: a hollow cylinder body with a first end and a second end; an integral end flange at the first end; a separate end flange disposed at the second end of the cylinder body; and laminations disposed on an outer surface of the cylinder body, the laminations comprising magnetic material.
Example 2. The rotor of example 1, wherein an outer diameter of the separate end flange is greater than an outer diameter of the second end of the cylinder.
Example 3. The rotor of example 2, further comprising: a spacer disposed between the laminations and the separate end flange such that the laminations does not directly contact the separate end flange.
Example 4. The rotor of example 2, wherein the main rotor body further comprises a retention flange on the first end, wherein a diameter of the retention flange is greater than the diameter of the second end of the cylinder.
Example 5. The rotor of example 4, further comprising: a first spacer disposed between the laminations and the separate end flange such that the laminations do not directly contact the separate end flange; and a second spacer disposed between the laminations and the retention flange such that the laminations do not directly contact the retention flange.
Example 6. The rotor of any of examples 1-5, wherein the separate end flange is configured to be press-fit into the second end of the cylinder.
Example 7. The rotor of example 6, wherein at least a portion of the separate end flange extends longitudinally into the second end of the cylinder.
Example 8. The rotor of example 7, wherein the portion of the separate end flange that extends into the second end of the cylinder includes at least two longitudinally displaced segments having different outer diameters.
Example 9. The rotor of example 8, wherein, when press-fit into the second end of the cylinder, an outer surface of a first segment of the at least two segments does not contact the cylinder and an outer surface of a second segment of the at least two segments does contact the cylinder.
Example 10. The rotor of example 9, wherein the second segment extends further into the cylinder than the first segment.
Example 11. The rotor of any of examples 1-10, wherein at least a portion of the separate end flange extends longitudinally under at least a portion of the magnetic material.
Example 12. The rotor of any of examples 1-11, wherein the separate end flange is configured to be attached to the second end of the cylinder via a plurality of bolts.
Example 13. The rotor of example 12, wherein the second end of the cylinder includes a plurality of receptacles configured to receive the plurality of bolts, and wherein an inner diameter of the second end of the cylinder is defined by the plurality of receptacles.
Example 14. The rotor of any of examples 1-13, wherein the integral end flange comprises a plurality of radially disposed slots.
Example 15. The rotor of any of examples 1-14, wherein the separate end flange comprises a hollow shaft disposed along the longitudinal axis, and wherein the integral end flange comprises a hollow shaft disposed along the longitudinal axis having a same outer diameter as the hollow shaft of the separate end flange.
Example 16. The rotor of example 15, wherein the integral end flange further comprises a solid shaft disposed along the longitudinal axis, wherein the solid shaft of the integral end flange is located distal from the cylinder jacket relative to the hollow shaft of the integral end flange.
Example 17. The rotor of example 16, wherein an outer diameter of the solid shaft of the integral end flange is less than the outer diameter of the hollow shaft of the integral end flange.
Example 18. The rotor of claim 17, wherein the main rotor body is monolithic.
Example 19. The rotor of any of examples 1-18, further comprising a sleeve disposed radially over the laminations.
Example 20. An airframe comprising: a combustion engine; an electric starter generator comprising a rotor that includes: a main rotor body having a longitudinal axis, the main rotor body comprising: a hollow cylinder body with a first end and a second end; an integral end flange at the first end; a separate end flange disposed at the second end of the cylinder body; and laminations disposed on an outer surface of the cylinder body, the laminations comprising magnetic material; and a shaft connected to the separate end flange and the combustion engine.
Various examples have been described. These and other examples are within the scope of the following claims.