KR101245135B1 - A rotor for compressor - Google Patents

Abstract

The present invention relates to a rotor for a compressor, and an object of the present invention is to provide a rotor for a compressor provided to effectively fix the magnet while simplifying the configuration.

To this end, the compressor rotor according to the present invention includes a rotor core provided to press the rotary shaft in a central portion, a plurality of magnets disposed along the circumferential direction on the outside of the rotor core to surround the rotor core, and the outside of the magnet. A cylindrical shatterproof can is provided to wrap, and an elastic member is provided between the rotor core and the magnet to elastically support the rotor core and the magnet while being fixed to the rotor core.

Description

Compressor rotor {A ROTOR FOR COMPRESSOR}

1 is a side cross-sectional view showing the structure of a conventional rotor for a compressor.

Figure 2 is a side cross-sectional view schematically showing the overall structure of a compressor according to a preferred embodiment of the present invention.

FIG. 3 is a cross-sectional plan view illustrating the structure of the driving motor in FIG. 2.

Figure 4 is an exploded perspective view showing the structure of a rotor for a compressor according to an embodiment of the present invention.

Figure 5 is a perspective view showing the structure of a rotor for a compressor according to an embodiment of the present invention, showing an assembled state.

6 to 8 are sectional views sequentially showing the assembly process of the rotor for a compressor according to an embodiment of the present invention.

Description of the Related Art [0002]

60: rotor core 63: locking groove

70: magnet 80: shatterproof can

90: elastic member 91: locking portion

92: elastic part

The present invention relates to a compressor rotor, and more particularly, to a compressor rotor provided to effectively fix the magnet while simplifying the configuration.

In general, a compressor is provided to compress a refrigerant in a refrigerating cycle of a refrigerator and an air conditioner, and includes a driving motor providing a compression driving force of the refrigerant, and a compression device receiving the driving force of the driving motor to perform a compression operation of the refrigerant. It is composed.

The drive motor is provided with a stator disposed on the outside of the coil is wound, the rotor is rotatably installed in the stator to rotate in electrical interaction with the stator, the inside of the rotor to drive the driving force of the drive motor The rotating shaft for delivery to the compression device is pressed in.

1 shows a structure of a rotor employed in a drive motor of a conventional compressor.

As shown in FIG. 1, the rotor 1 is disposed so as to have alternating polarity along the circumferential direction of the rotor core 1a and the outer side of the rotor core 1a provided with a rotor shaft press-fitted in the center thereof. A plurality of magnets 1b provided to surround the core 1a are provided.

Outside the magnet 1b, a scattering prevention can 1c is fitted to prevent the magnet 1b from flowing out in a radial direction and detached when the rotor 1 rotates, and the scattering prevention can 1c is made of a thin material. It is provided to have a cylindrical shape opened up and down through the metal plate to be press-fitted to the outside of the magnet (1b).

In addition, in order to prevent the magnet 1b from moving away in the axial direction due to the rotation of the rotor 1 or an impact applied from the outside, the rotor core 1a is provided at the upper and lower ends of the rotor core 1a. The upper and lower end rings 1e and 1f coupled to each other through the rivet 1d are provided, and the upper and lower end rings 1e.1f respectively extend toward the upper and lower ends of the magnet 1b, respectively. .

The rotor for a conventional compressor configured as described above couples upper and lower end rings 1e and 1f to upper and lower ends of the rotor core 1a through the rivet 1d, respectively, and the magnet 1b is the rotor core. The assembly is completed by inserting the scattering prevention can 1c to be press-fitted to the outside of the magnet 1b while the magnets 1b are positioned outside the rotor core 1a so as to surround the 1a.

However, such a conventional compressor rotor 1 has many kinds of parts such as the upper and lower end rings 1e and 1f and the plurality of rivets 1f as well as the scattering can 1c and the magnet 1b. Since it is used for the fixing of the overall configuration of the rotor (1) had a problem that becomes complicated.

In addition, as described above, the anti-scatter can 1c is fitted to be pressed into the outside of the magnet 1b during the assembly of the rotor to suppress the radial flow of the magnet 1b, for this purpose the anti-scatter can ( 1c has a small diameter so that a press-fitting tolerance is formed between the magnet 1b, and in this way, in the state where the press-fitting tolerance is formed between the anti-scattering can 1c and the magnet 1b, a thin metal anti-scattering can ( As 1c) is easily bent or broken in the process of being pressed into the magnet 1b, the magnet 1b cannot be effectively fixed.

The present invention is to solve such a problem, an object of the present invention is to provide a rotor for a compressor provided to effectively fix the magnet while simplifying the configuration.

Compressor rotor according to the present invention for achieving this object and a plurality of magnets are arranged along the circumferential direction on the outer side of the rotor core to surround the rotor core, the rotor core is pressed in the center; A cylindrical shatterproof can is provided to surround the outside of the magnet, and an elastic member is provided between the rotor core and the magnet to elastically support the rotor core and the magnet in a state fixed to the rotor core. It is done.

When the magnet is pressed toward the rotor core, the elastic member is elastically deformed, and a sliding tolerance is formed between the magnet and the anti-scattering can, and the magnet has an inner diameter of the anti-scattering can due to the elastic restoring force of the elastic member. It is characterized in that the pressure is fixed to.

In addition, the elastic member includes a pair of springs each having a pair of engaging portions formed on each side end and the elastic portion provided between the engaging portion, the rotor core is provided with a locking groove to be fixed to the engaging portion It features.

In addition, the locking portion and the locking groove is characterized in that it is provided to be coupled to each other sliding along the longitudinal direction of the rotor core.

Hereinafter, with reference to the accompanying drawings, a preferred embodiment according to the present invention will be described in detail.

As shown in FIG. 2, the compressor according to the present embodiment forms an appearance through the sealed container 10. The inside of the sealed container 10 is provided with a drive motor 20 for providing the compression power of the refrigerant, and a compression device 30 for receiving the drive power of the drive motor to perform the compression action of the refrigerant, the sealed container 10 On one side and the other side of the suction pipe 11 for guiding the external refrigerant into the sealed container 10 and the discharge tube 12 for guiding the refrigerant compressed in the sealed container 10 to the outside of the sealed container 10, respectively Is installed.

The drive motor 20 and the compression device 30 are installed through the frame 40. First, the drive motor 20 is a stator 21 fixed to the upper outer side of the frame 40, and electromagnetic with the stator 21. It comprises a rotor 22 rotatably installed inside the stator 21 to rotate in a positive interaction.

And the center of the rotor 22 is rotated with the rotor 22 while rotating the rotation shaft 50 for transmitting the power of the drive motor 20 to the compression device is pressed, the eccentric rotation of the eccentric rotation on the lower end of the rotation shaft 50 The shaft 51 is provided.

The compression device 30 of the frame 40 to form a piston 32 connected through the eccentric shaft 51 and the connecting rod 31, and the compression chamber 33a through which the piston 32 is linearly reciprocated. The cylinder 33 integrally provided with the frame 40 on one side and the cylinder 33 are coupled to one end of the cylinder 33 to seal the compression chamber 33a, and the refrigerant suction chamber 34a and the refrigerant discharge chamber 34b are mutually divided. The cylinder 33 and the cylinder 33 so as to interrupt the flow of the refrigerant sucked into the compression chamber 33a from the refrigerant suction chamber 34a or discharged from the compression chamber 33a to the refrigerant discharge chamber 34b. And a valve device 35 provided between the cylinder heads 34. Here, the refrigerant suction chamber 34a is connected to the suction pipe 11 side, and the refrigerant discharge chamber 34b is connected to the discharge tube 12 side, and reference numeral 13 denotes the suction tube 11 and the refrigerant suction chamber 34a. It is a suction muffler provided between) to reduce the noise of the suction refrigerant.

When the rotor 22 rotates due to the electromagnetic interaction between the stator 21 and the rotor 22 through this structure, the rotating shaft 50 rotates and is connected to the eccentric shaft 51 of the rotating shaft 50. The piston 32 connected through the rod 31 is linear reciprocating movement in the compression chamber 33a, through which a pressure difference is formed between the inside and the outside of the compression chamber 33a.

The refrigerant guided into the sealed container 10 along the suction pipe 11 by this pressure difference is sucked into the compression chamber 33a through the refrigerant suction chamber 34a and compressed, and is compressed in the compression chamber 33a. The discharged coolant is discharged to the outside of the sealed container 10 through the coolant discharge chamber 34b and the discharge tube 12, and the compression operation of the coolant through the compressor is performed while this process is repeatedly performed.

3 shows the structure of the drive motor 20 in detail, and in this embodiment, the rotor 22 of the drive motor 20 can effectively fix the magnet 70 to be described later while simplifying the configuration. It is prepared in such a way that specific explanations are as follows.

In the driving motor, the stator 21 includes a coil 21b and a stator core 21a having a plurality of teeth portions 21c protruding from the inner circumferential surface of the plurality of teeth 21c provided such that the coils 21b are alternately magnetized by the applied power. Is prepared through.

The double teeth portions 21c are formed to be spaced at equal intervals from each other along the circumferential direction, and the coil 21b wound around the teeth portions 21c is accommodated in the stator core 21a between adjacent teeth portions 21c. 21d) is formed.

In addition, referring to Figure 4 and 5 together, the rotor 22 is a rotor core 60 is provided with a press-hole 61 to press the rotary shaft 50 in the longitudinal direction in the inner center, A plurality of magnets 70 magnetized to have alternating polarity along the circumferential direction is provided on the outside of the electronic core 60, and the plurality of magnets 70 are disposed to surround the rotor core 60.

Here, the rotor core 60 has a cylindrical shape as a whole, and the magnet 70 is formed in a plate shape having a predetermined thickness having a curvature corresponding to the outer diameter of the rotor core 60 to form a substantially rotor core 60. It is provided to have a length equal to the length of), the support protrusion 62 for supporting both ends of the magnet 70 is formed on the outer surface of the rotor core 60 between and between the magnets (70).

In addition, when the current application circuit applies current to the coil 21b wound around each tooth portion 21c of the stator 21 according to the position of the rotor 22, each tooth portion ( 21c) has the alternating polarity of the N pole and the S pole sequentially, through which the attraction force and the repulsive force generated by the magnetic force between the teeth portion 21c of the stator 21 and the magnet 70 of the rotor 22 Magnetic force acts in the tangential direction of the rotor 22 to cause the rotor 22 to rotate.

On the other hand, in the rotor 22, the outer side of the magnet 70 through the thin metal material to prevent the magnet 70 flows in the radial direction during the rotation of the rotor 22 is separated Shatter-proof can 80 is formed is formed and provided in a cylindrical shape, the upper and lower openings are fitted, between the rotor core 60 and the magnet 70 is elastic between the rotor core 60 and the magnet 70 A support elastic member 90 is provided, and when the magnet 70 is urged toward the rotor core 60, the elastic member 90 is elastically deformed and between the magnet 70 and the shatterproof can 80. There is a sliding tolerance is formed, the magnet 70 is fixed to the inner diameter of the anti-scattering can 80 through the elastic restoring force of the elastic member 90.

Therefore, the rotor 22 configured as described above has the elastic member 90 interposed between the rotor core 60 and the magnet 70 before the scattering prevention can 80 is fitted to the outside of the magnet 70. Shatterproof cans outside the magnet 70 in a state in which the magnet 70 is pressed toward the rotor core 60 by using a pressure jig or the like such that a sliding tolerance is formed between the magnet 70 and the anti-scattering can 80. 80, but the sliding tolerance is formed between the magnet 70 and the anti-scattering can 80, the anti-scattering can 80 is fitted to the outside of the magnet 70, the anti-scattering can 80 ), The assembling work is facilitated, and deformation or damage of the scattering prevention can 80 is prevented in the process of fitting the scattering prevention can 80.

In addition, when the anti-scattering can 80 removes the external force applied to the magnet 70 by removing the pressing jig (not shown) in a state sandwiched outside the magnet 70, the magnet 70 is an elastic member. The pressure is fixed to the inner diameter of the anti-scattering can 80 through the elastic restoring force of the 90, the magnet 70 is pressed against the anti-scattering can 80 by the elastic restoring force of the elastic member 90 fixed state In The scattering prevention can 80 can be effectively prevented from being separated from the outside of the magnet 70 as well as the magnet 70 flowing in the axial direction. Therefore, this rotor 22 is simplified in the overall configuration by allowing the upper and lower end ring, which was conventionally used for preventing the axial flow of the magnet.

The elastic member 90 is provided to correspond to the number of magnets 70 is installed on the inside of each magnet 70, in this embodiment as the elastic member 90 in the longitudinal direction of the rotor core 60 A leaf spring provided to have a length approximately equal to is employed.

The elastic member 90 composed of a leaf spring includes a pair of locking portions 91 that form both side ends, and an elastic portion 92 between the locking portions 91. The elastic portion 92 has a predetermined curvature The magnet 70 is elastically supported toward the inner diameter of the anti-scattering can 80 in a state spaced a predetermined distance from the outer circumference of the rotor core 60, the locking portion 91 is bent into the rotor core 60 A pair of locking grooves 63 are formed on the outer surface of the rotor core 60 inside the pair of support protrusions 62 so as to correspond to the pair of locking portions 91.

Therefore, the elastic member 90 is fixed to the rotor core 60 by being coupled to each other by sliding the pair of the engaging portion 91 and the engaging groove 63 along the longitudinal direction of the rotor core 60, In the state in which the elastic member 90 is fixed to the rotor core 60 as described above, before the emergency prevention can 80 is fitted to the outside of the magnet 70 or in the process of being fitted, the elastic member 90 is formed of the rotor core ( It is possible to prevent the departure from the 60) to facilitate the operation of fitting the scattering prevention can (80).

Next will be described in detail the assembling process of the rotor 22 for the compressor according to this embodiment configured as described above.

As shown in FIG. 6, in order to assemble the compressor rotor 22 according to the present embodiment, the engaging portion 91 is slidably coupled to the engaging groove 63 formed at the outer circumference of the rotor core 60. The magnets 70 are positioned outside the elastic members 90 in a state in which each elastic member 90 is fixed to the outer circumference of the rotor core 60. In this state, each magnet 70 is pressed toward the rotor core 60 (the arrow direction in FIG. 7) by using a pressure jig (not shown). Accordingly, the rotor core 60 and the magnet ( As the elastic member 90 provided between 70 is elastically deformed, the magnet 70 moves inside the rotor core 60 so that a sliding tolerance is formed between the scattering prevention can 80. Therefore, in this state, the anti-scatter can 80 is inserted to the outside of the magnet 70 to prevent deformation or breakage of the emergency anti-can can 80, and the fitting operation of the anti-scatter can 80 is completed while the magnet ( When the pressing jig (not shown) pressurized to 70 inside the rotor core 60 is removed, the magnet 70 is scattered by the elastic restoring force of the elastic member 80 (FIG. 8, the assembly of the rotor 22 is completed while being pressed and fixed in the direction of the arrow (8). In this state, the magnet 70 is pressed against the scattering prevention can 80 by the elastic restoring force of the elastic member 90 and fixed. By the restoring force of the elastic member 90 can prevent the scattering prevention can 80 is separated from the outside of the magnet 70, as well as effectively prevent the magnet 70 flow in the axial direction to prevent the axial flow of the conventional magnet The upper and lower end rings used for or the rivets used for fixing the end rings can be deleted.

As described above in detail, the rotor for the compressor according to the present invention, the magnet is pressed against the elastic member in the state that the anti-scattering can is fitted to the outside of the magnet due to the elastic member provided to elastically support the rotor core and the magnet. Since it can be moved to the inner side of the core, the anti-scatter can can be inserted to the outside of the magnet with ease, so assembling of the rotor is first improved. In addition, the compressor rotor has a structure in which the magnet is pressed against the inner diameter of the anti-scattering can through the elastic restoring force of the elastic member while the anti-scattering can is fitted to the outside of the magnet, thereby preventing the axial flow of the magnet. The upper and lower end rings used to prevent axial flow or the rivets for fixing the end rings can be eliminated, thereby simplifying the overall configuration.

Claims (4)

The rotor core is provided to press the rotary shaft in the center portion, a plurality of magnets disposed along the circumferential direction on the outer side of the rotor core to surround the rotor core, and a cylindrical scattering prevention can provided to surround the outside of the magnet In the rotor for the compressor, Between the rotor core and the magnet is provided with an elastic member for elastically supporting between the rotor core and the magnet in a state fixed to the rotor core, The elastic member includes a pair of springs each having a pair of engaging portions formed on each side end and an elastic portion provided between the engaging portions, Compressor rotor, characterized in that the locking groove is provided in the rotor core to be caught and fixed. The method of claim 1, When the magnet is pressed toward the rotor core, the elastic member is elastically deformed, and a sliding tolerance is formed between the magnet and the scattering prevention can, The magnet is a rotor for a compressor, characterized in that is pressed to the inner diameter of the anti-scattering can by the elastic restoring force of the elastic member. delete The method of claim 1, The locking portion and the locking groove is a compressor rotor, characterized in that provided to be coupled to each other sliding along the longitudinal direction of the rotor core.

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