WO2019105633A1 - Permanent magnet synchronous electric motor for hermetic compressors - Google Patents

Abstract

The present invention relates to a rotor (1) suitable for use in a permanent magnet synchronous electric motor (19) of a hermetic compressor (20), rotating in a stator (15) about a rotary axis (E) formed by a shaft (17) mounted in a shaft hole (16) in its center, having an air gap (18) in between itself and the inner surface of the stator (15), comprising a core (2) made of ferromagnetic laminations or ferromagnetic metal powders, a plurality of magnets (3) placed circumferentially adjacent with equal space in between on the core (2), whose transversal section vertical to the rotary axis (E) is shaped as an arc segment curved in radial direction from the circumference of the core (2) towards its center, having a convex lower surface (4) contacting the core (2) and a concave upper surface (5) not contacting the core (2).

Description

PERMANENT MAGNET SYNCHRONOUS ELECTRIC MOTOR FOR HERMETIC COMPRESSORS

The present invention relates to a rotor suitable for use in a permanent magnet synchronous electric motor driving a hermetic compressor.

The permanent magnet synchronous electric motors used in hermetic compressors consist of a stator, and a rotor rotating in the stator. In the state of the art, the rotor comprises a cylindrical core comprising of ferromagnetic laminations arranged on top of each other and attached to each other by interlock tabs, in which full-length magnet seats are disposed, and magnets placed in the magnet seats, whose transversal section is shaped as an arc segment in some applications. The magnets are fixed in the core in axial direction by means of upper and lower rotor covers. The rotor cases are fixed by rivets to the core. In order to obtain a desired performance of the electric motor, the magnets should be placed in the core so as to be close to the cylindrical outer surface, and a rather small distance is left between the magnet seats and the outer surface of the core. A shaft through-hole is made in axial direction through the center of the core, enabling the core to be attached to a shaft, and rivet through-holes are made in axial direction around the shaft hole. Said holes, the magnet seats and the fine portions in the rotor stack cause temporary springing and deformations in the rotor rotating in high speeds in the stator. A narrow air gap is provided between the stator and the rotor. In order to obtain the expected performance in an electric motor and to enable silent operation, the dimensions of the air gap between the rotor and the stator should be circumferentially constant (homogeneous). The springing in radial direction of the rotor in high speeds lead to deterioration of the air gap dimensions and friction of the rotor with the stator, decreasing the performance of the electric motor and leading to a loud operation and causing heating problems.

The patent application no. WO2011108733 (A1) relates to production method of a rotor with surface mounted magnet, on which a cylindrical rotor case is mounted. In order to inhibit circumferential movement of the magnets, depressed portions are formed circumferentially on the cylindrical rotor case. In the present invention, the cylindrical rotor case has an even outer surface, the air gap between the rotor and the stator is homogeneous, and the circumferential movement of the magnets is inhibited by means of separator extensions which are part of the core, extending in radial direction from the core.

The patent application no. US2016065014 (A1) relates to permanent magnets used in an electric machine rotor.

The patent application no. WO2017119102 (A1) relates to an electric motor comprising permanent magnets embedded in a rotor.

The aim of the present invention is to realize a permanent magnet rotor suitable for use in an electric motor driving a hermetic compressor, with improved resistance against centrifugal forces in high speeds, enabling high torques and silent operation.

The rotor realized to achieve the aim of the present invention and disclosed in the first claim and the dependent claims, is of the surface mounted magnet type and comprises a ferromagnetic core, and an air gap is provided between the rotor and a stator, substantially effecting performance. The rotor of the invention comprises magnets placed circumferentially on the core with equal space in between, shaped as an arc segment curved in radial direction from the circumference of the core towards its center, having a convex lower surface resting on the core and a concave upper surface not contacting the core or any one of the ferromagnetic components. The magnets rest on the concave support surfaces around the core. The core and the magnets are mounted by being press fitted into a cylindrical rotor case. Since the circumference of the core is spacedly cut-out for the magnets, gaps are disposed between the upper surfaces of the magnets and the rotor case.

In an embodiment of the invention, the rotor comprises separator extensions disposed in between the support surfaces of the core, extending in radial direction from the core and outwards from in between the adjacent magnets, abutting on the inner surface of the rotor case, and enabling leaving in circumferential direction a predetermined gap between the magnets and inhibiting the magnets from contacting each other and preventing the circumferential movement of the magnets.

The rotor realized to achieve the aims of the present invention is illustrated in the accompanying drawings, wherein:

Figure 1 is a cross sectional view of a hermetic compressor and the electric motor driving the hermetic compressor.

Figure 2 is an exploded view of the rotor in an embodiment of the invention.

Figure 3 is a perspective view of a core and magnets placed in a rotor case.

Figure 4 is a cross sectional view of the rotor in axial direction.

Figure 5 is an exploded cross sectional view of the rotor core and magnets.

Figure 6 is a partial cross sectional view of an electric motor comprising a stator with the rotor of the invention.

Figure 7 is an exploded view of the rotor in another embodiment of the invention.

The elements in the figures are numbered individually and the correspondence of these numbers are given hereinafter.

1. Rotor
2. Core
3. Magnet
4. Lower surface
5. Upper surface
6. Support surface
7. Rotor case
8. Separator extension
9. Gap
10. Side wall
11. Bottom wall
12. Opening
13. Upper cover
14. Retainer
15. Stator
16. Shaft hole
17. Shaft
18. Air gap
19. Electric motor
20. Hermetic compressor
21. Rivet

E: Rotary axis

A surface mounted magnet type rotor (1) suitable for use in a permanent magnet synchronous electric motor (19) of a hermetic compressor (20), rotating in a stator (15) about a rotary axis (E) formed by a shaft (17) mounted in a shaft hole (16) in its center, having an air gap (18) in between itself and the inner surface of the stator (15), comprises a core (2), also called a rotor stack, made of ferromagnetic laminations or ferromagnetic metal powders (Figure 1).

The rotor (1) of the invention comprises

- a plurality of magnets (3) placed circumferentially adjacent and equal spaced on the core (2), interacting with the magnetic field generated by the current fed on the stator (15) coils and enabling the rotor (1) to rotate in the stator (15) by generating torque, whose transversal section vertical to the rotary axis (E) is shaped as an arc segment curved in radial direction from the circumference of the core towards its center, having a convex lower surface (4) contacting the core (2) and a concave upper surface (5) not contacting the core (2),

- a plurality of concave support surfaces (6) formed by cutting-out the core (2) inwards from its edge circumferentially and with equal spaces in between, each forming in radial direction from the circumference of the core (2) towards its center a curved groove on which the lower surface (4) of the magnet (3) rest,

- a cylindrical rotor case (7) made of ferromagnetic metal material, in which the core (2) and the magnets (3) are placed by being press fitted, or mounted by being press fitted on the core (2) and the magnets (3), and

- a plurality of gaps (9) provided between the rotor case (7) and the concave upper surfaces (5) of the magnets (3) arranged on the support surfaces (6) of the core (2) (Figures 2, 3, 5, and 6).

The rotor (1) further comprises a plurality of separator extensions (8) disposed in between the support surfaces (6) around the core (2), extending outwards in radial direction from in between the adjacent magnets (3), abutting to the inner surface of the rotor case (7), enabling leaving a predetermined gap in circumferential direction between the magnets (3), and inhibiting the magnets (3) from contacting each other and preventing the circumferential movement of the magnets (3) (Figures 2, 5, and 6).

The rotor case (7) comprises a cylindrical side wall (10) of even structure, a circular bottom wall (11) covering an end of the side wall (10), produced by way of deep drawing method preferably integrally with the side wall (10) or separately from the side wall (10) and joined later, and an opening (12) disposed at the other end of the side wall (10), enabling the core (2) and the magnets (3) to be placed into the rotor case (7) (Figures 2 and 3).

The rotor case (7) further comprises a circular upper cover (13) covered on the opening (12) after the core (2) and the magnets (3) are placed therein, and mounted circumferentially to the inner surface of the side wall (10) by being press fitted. The bottom wall (11) and the upper cover (13) inhibit the relative movement in axial direction of the core (2) and the magnets (3) inside the rotor case (7) (Figures 2, 3, 4, and 7)

The homogeneity of the air gap between the stator (15) and the rotor (1) is provided thanks to the outer surface of the cylindrical side wall being of “even” structure, decreasing the noise level of the electric motor (19) and enhancing its performance, contrary to the uneven structure of the state of the art disclosed in the document no. WO2011108733.

In an embodiment of the invention, the rotor case (7) comprises at least one retainer (14) provided on the inner surface of the bottom wall (11) and/or the upper cover (13), abutting on the separator extensions (8), preventing the core (2) from making rotary motion relatively inside the rotor case (7), and enabling substantial entirety of the rotor case (7), core (2) and the magnets (3) (Figure 2).

In another embodiment, the retainer (14) is shaped as an indentation opening to the inner surface of the bottom wall (11) and/or the upper cover (13), in which the separator extension (8) fits. In another embodiment of the invention, the retainer (14) is shaped as a double protrusion abutting on both sides of the separator extension (8), extending from the inner surface of the bottom wall (11) and/or the upper cover (13) towards the interior of the rotor case (7).

In another embodiment of the invention, the rotor case (7) comprises an upper cover (13) and a bottom wall (11) fixed to each other by means of rivets (21) passed through the gaps (9) in axial direction. The rivets (21) are passed through the gaps (9) in the rotor (1), fixing the bottom wall (11) and the upper cover (13). This makes it unnecessary to make on the core (2) rivet (21) holes which decrease flux density (Figure 7).

In production of the rotor (1) of the invention, adhesive, welding or similar coupling methods are not used to fix the magnets (3) to the core (2). The obligation to embed the magnets (3) in the core (2) is eliminated thanks to the structure with gaps (9), and the magnets (3) rest only single-sided on the support surfaces (6) of the core (2). The upper surfaces (5) of the magnets (3) do not contact the core (2) and the rotor case (7), since they are on the side of the gaps (9). This makes it unnecessary to make holes in the core (2) in order to embed the magnets (3), decreasing magnetic flux losses by providing continuity on the core (2) body. The gaps (9) allow increasing the dimensions of the magnets (3). The ferromagnetic material loss on the core (2) due to concave support surfaces (6), are compensated by surface mounted magnets (3), achieving a higher flux density and a higher performance with the same rotor (1) volume. The skidding of the magnets (3) in radial direction due to the centrifugal force, is prevented by the rotor case (7) circumferentially surrounding the core (2) and the magnets (3). Since the upper surfaces (5) of the magnets (3) facing the rotor case (7) are of concave structure and there are gaps (9) in between, each one of the magnets (3) apply pressure due to centrifugal force to the rotor case (7) only from two points (from their end portions) and in a balanced manner. In high spin speeds, the rotor case (7) does not become deformed, the circularity of the side wall (10) does not deteriorate, thereby maintaining circumferentially equal dimensions of the air gaps (18). The gaps (9) inside the rotor (1) allow the upper cover (11) and the bottom wall (11) to be fixed to the core (2) by means of rivets (21) without making holes.

Claims (9)

1. A rotor (1) suitable for use in a permanent magnet synchronous electric motor (19) of a hermetic compressor (20), rotating in a stator (15) about a rotary axis (E), having an air gap (18) in between itself and the inner surface of the stator (15), and comprising a core (2) made of ferromagnetic laminations or ferromagnetic metal powders, characterized by

   - a plurality of magnets (3) placed circumferentially adjacent and equal spaced on the core (2), with the transversal section vertical to the rotary axis (E) shaped as an arc segment curved in radial direction from the circumference of the core towards its center, having a convex lower surface (4) contacting the core (2) and a concave upper surface (5) not contacting the core (2),

   - a plurality of concave support surfaces (6) formed by cutting-out the core (2) inwards from its edge circumferentially and with equal spaces in between, each forming in radial direction from the circumference of the core (2) towards its center a curved groove on which the lower surface (4) of the magnet (3) rests,

   - a cylindrical rotor case (7) in which the core (2) and the magnets (3) are placed by being press fitted, or mounted by being press fitted on the core (2) and the magnets (3), and

   - a plurality of gaps (9) provided between the rotor case (7) and the concave upper surfaces (5) of the magnets (3) arranged on the support surfaces (6) of the core (2).
2. A rotor (1) according to claim 1, characterized by a plurality of separator extensions (8) disposed between the support surfaces (6) around the core (2), abutting on the inner surface of the rotor case (7) by extending outwards in radial direction from in between the adjacent magnets (3).
3. A rotor (1) according to claim 1 or 2, characterized by the rotor case (7) comprising a cylindrical side wall (10), a circular bottom wall (11) covering an end of the side wall (10), an opening (12) provided on the other end of the side wall (10), enabling the core (2) and the magnets (3) to be placed in the rotor case (7), and a circular upper cover (13) covering the opening (12).
4. A rotor (1) according to claim 3, characterized by the rotor case (7) comprising at least one retainer (14) provided on the inner surface of the bottom wall (11) and/or the upper cover (13), and abutting on the separator extensions (8).
5. A rotor (1) according to claim 4, characterized by the rotor case (7) comprising an indentation shaped retainer (14) opening to the inner surface of the bottom wall (11) and/or the upper cover (13), and in which the separator extension (8) fits.
6. A rotor (1) according to claim 4, characterized by the rotor case (7) comprising a retainer (14) shaped as a double protrusion abutting on both sides of the separator extension (8), extending from the inner surface of the bottom wall (11) and/or the upper cover (13) towards the interior of the rotor case (7).
7. A rotor (1) according to any one of the preceding claims, characterized by the rotor case (7) comprising the bottom wall (11) and the upper cover (13) fixed to each other by means of rivets (21) passed through the gaps (9) in axial direction.
8. An electric motor (19) characterized by a rotor (1) according to any one of the preceding claims.
9. A hermetic compressor (20) characterized by an electric motor (19) according to claim 8.

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