KR101682250B1 - Electronic Compressor - Google Patents

Abstract

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric compressor, and more particularly, to an electric compressor for smoothly moving refrigerant introduced into a first front housing to a compression portion of an intermediate housing. According to the electric compressor of the present invention, since the spiral groove in the same direction as the rotation direction of the motor is formed on the bottom surface of the motor rotor, the flow of the refrigerant moving to the compression portion of the intermediate housing under the centrifugal force can be smoothly effected .

Description

Electronic Compressor

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to an electric compressor, and more particularly, to an electric compressor for smoothly moving refrigerant introduced into a first front housing to a compression portion of an intermediate housing.

Generally, the automobile is provided with an air conditioner for cooling and heating. The air conditioner includes a compressor that compresses low-temperature and low-pressure refrigerant introduced from an evaporator into high-temperature and high-pressure refrigerant and sends it to a condenser. Such compressors include a mechanical type using the power transmitted from the engine and an electric type using a separate motor as the driving source.

FIG. 1 is a sectional view of a general electric compressor, and FIG. 2 is a perspective view of a rotor of a conventional electric compressor.

1, an electric compressor 1 includes a first front housing 20 through which refrigerant flows from the outside, an intermediate housing 40 through which refrigerant is compressed, a first intermediate housing 40 intermediate the first and second front housings 20, A second front housing 30 provided between the housings 40, and a rear housing 60 having a discharge chamber 61.

A suction port (not shown) for sucking the refrigerant is formed in the first front housing 20, and a driving circuit for controlling the driving of the motor 70 is disposed on one side wall of the first front housing 20 Respectively. The interior of the first front housing 20 and the second front housing 30 cooperate to form a motor room 26. The motor chamber (26) is provided with a motor (70) for transmitting driving force for compressing the refrigerant.

The motor 70 is composed of a stator 71 and a rotor 80. The stator 71 is formed by stacking a plurality of core pieces in the form of a thin plate in the form of a cylinder passing through the center thereof. The stator 71 is wound with a coil. When a current flows through the coil wound around the stator 71, a magnetic field is generated in the stator 71 and the rotor 80 rotates.

The intermediate housing (40) is provided with a compression chamber (S) for compressing the refrigerant and a compression mechanism (50) for compressing the refrigerant. The compression mechanism 50 includes a fixed scroll 51 and an orbiting scroll 55. A relative rotation of the orbiting scroll 55 with respect to the fixed scroll 51 causes a compression chamber The refrigerant flowing into the refrigerant circuit S is compressed. The refrigerant compressed in the intermediate housing 40 is delivered to the discharge chamber 61 through a discharge port 45 formed at the center of the fixed scroll 51.

2, the rotor 80 is formed in a substantially cylindrical shape with one side opened. A protruding portion protruding upward is formed at the center of the bottom surface 87 of the opposite side of the rotor. The outer surface of the protruding portion is engaged with the second front housing 30 through the bearing B. A center hole 81 is formed at the center of the projection so as to press the rotation shaft 24 and a plurality of coupling holes 83 are formed in a circumferential direction around the center hole 81. In the bottom surface 87, a plurality of through holes 85 are formed along the circumferential direction.

According to the electric compressor 1 having such a configuration, a part of the refrigerant introduced through the suction port (not shown) of the first front housing 20 flows through the cooling passage 29 formed on the outer side of the rotor 80 And moves to the compression chamber S formed in the intermediate housing 40 through the space between the second front housing 30 and the bearing B2 coupled between the rotor 80 .

The remaining refrigerant exits through the communication hole 22 connected to the suction port and passes through the through hole 85 of the rotor 80 through the space between the first front housing 20 and the bearing BA1 coupled between the rotary shaft 24 And moves to a compression chamber S formed in the intermediate housing 40 through a space between the second front housing 30 and the bearing BA2 coupled between the rotor 80 .

However, since the refrigerant in the electric compressor 1 is subjected to the centrifugal force by the rotation of the rotor 80, the refrigerant moves while rotating in the outward direction, but the through hole 85 through which the refrigerant moves is formed in the axial direction There is a problem that the refrigerant can not smoothly move from the front housings 20 and 30 to the compression portion in the intermediate housing 40. [

It is an object of the present invention to provide a compressor for smoothly moving a refrigerant introduced into a front housing into an intermediate housing provided with a compression unit.

According to an aspect of the present invention, there is provided an electric compressor comprising: a first front housing in which a suction port through which refrigerant flows from the outside is formed and a motor for providing a driving force for compressing the introduced refrigerant is installed; A bearing support portion in which a bearing is coupled to a center portion of the intermediate housing so that the rotor of the motor is rotatable is provided between the first front housing and the intermediate housing; and an intermediate housing having a compression mechanism for compressing the refrigerant, And a plurality of helical grooves are formed along the circumferential direction of the rotor on the bottom surface of the rotor.

According to the embodiment of the helical groove, it is preferable that the helical groove is formed in the same direction as the rotational direction of the rotor.

The side wall of the helical groove is formed to be inclined from the inner side to the outer side of the bottom surface along the moving direction of the rotating refrigerant.

According to the electric compressor of the present invention as described above, since the helical groove in the same direction as the rotation direction of the motor is formed on the bottom surface of the motor rotor, the flow of the refrigerant moving to the compression portion of the intermediate housing under the centrifugal force is smoothly There is an effect that can be done.

Further, as the flow of the refrigerant smoothes, the flow rate of the refrigerant moving to the compression section increases, thereby improving the cooling capability of the electric compressor.

1 is a sectional view showing the construction of a conventional electric compressor,
FIG. 2 is a perspective view showing a rotor of a conventional electric compressor,
3 is a sectional view showing the construction of an electric compressor according to the present invention,
4 is a perspective view showing a rotor of an electric compressor according to the present invention,
5 is a partial perspective view showing a partial cross-sectional view of a rotor of an electric compressor according to the present invention.

Hereinafter, preferred embodiments of the electric compressor according to the present invention will be described in detail with reference to the drawings. 4 is a perspective view of a rotor of an electric compressor according to the present invention. FIG. 5 is a perspective view of a rotor of the electric compressor according to the present invention. Fig.

3, the electric compressor according to the present invention includes a first front housing 120 through which refrigerant flows from the outside, an intermediate housing 140 through which refrigerant is compressed, a first front housing 120, And a rear housing 160 having a second front housing 130 connecting the intermediate housing 140 and a discharge chamber 161 through which the compressed refrigerant is discharged.

The first front housing 120 and the second front housing 130 cooperate to form a motor chamber 126. The motor room (126) is provided with a motor (170) for driving the electric compressor (1). The motor 170 includes a stator 171 and a rotor 180.

The stator 171 is formed by stacking a plurality of core pieces in the form of a cylinder having a substantially central portion passing through the center thereof. A coil is wound around the stator 171. When a current flows through the coil wound around the stator 171, a magnetic field is formed in the stator 171.

The rotor 180 provided outside the stator 171 is formed in a substantially cylindrical shape. When a current flows through the coil of the stator 171, a magnetic field is generated and the rotor 180 rotates. The rotor 180 is rotatably supported by a bearing BB2 provided between the rotor 180 and the second front housing 130. [

And the rotating shaft 124 is press-fitted through the center of the rotor 180. Accordingly, when the rotor 180 is rotated by electromagnetic interaction with the stator 171, the rotating shaft 124 rotates together.

An inverter chamber 128 is formed in the first front housing 120. Referring to FIG. 3, the inverter chamber 128 is formed on the left side of the motor chamber 126. In the inverter chamber 128, an inverter assembly 110 for controlling the rotation of the electric compressor 100 is installed.

An intermediate housing 140 is installed on the opposite side of the first front housing 120 on which the inverter assembly 110 is installed. A compression mechanism 150 is installed inside the intermediate housing 140. The compression mechanism 150 compresses the refrigerant introduced into the first front housing 120 and receives the power from the motor 170 to compress the refrigerant.

The compression mechanism (150) includes a fixed scroll (151) and an orbiting scroll (155). The fixed scroll 151 is formed integrally with the rear housing 140. The fixed scroll 151 is formed by protruding a fixed wedge 143 in a spiral shape on one side of the disk-shaped fixed end plate 142. A discharge port 145 is formed through the center of the fixed scroll 151.

The orbiting scroll (155) is rotatably installed to receive the power of the motor (170) through the rotation shaft (124). The orbiting scroll 155 is installed to face the fixed scroll 151. The orbiting scroll 155 is formed on one surface of the circular plate turning end plate 156 so as to protrude in a spiral shape. That is, by the relative rotation of the fixed scroll 151 and the orbiting scroll 155, the refrigerant introduced into the compression chamber SB formed therebetween is compressed.

In more detail, the fixed scroll 151 is integrally formed with the intermediate housing 140. The stationary scroll 151 is formed in such a manner that the stationary scroll 143 protrudes in a spiral shape on one surface of the disk-shaped stationary end plate 142. A discharge port 145 is formed through the center of the fixed scroll 151 to transfer the refrigerant compressed in the compression chamber SB to the discharge chamber 161.

The orbiting scroll 155 is rotatably installed on the balance plate 117 provided between the rotary shaft 124 and the eccentric bush 115 by an Oldham coupling 119. The orbiting scroll 155 is installed to face the fixed scroll 151. The orbiting scroll 155 is formed in such a manner that the orbiting scroll 157 protrudes in a spiral shape on one surface of a disk-

A boss 159 protrudes from one side of the orbiting scroll 155 facing the intermediate housing 140. An eccentric bush 115 of the rotary shaft 124 is inserted into the boss 159 so that the orbiting scroll 155 is revolved by the rotary shaft 124.

The orbiting wrap (157) forms a compression chamber (S) in cooperation with the fixed lap (143). That is, as the orbiting scroll (155) revolves with respect to the fixed scroll (151), the volume of the compression chamber (S) formed by the fixed lap (143) and the orbiting lap (157) gradually decreases, And finally the discharge port 145 and the compression chamber SB are communicated with each other so that the refrigerant is discharged to the discharge chamber 161.

The rear housing 160 is coupled to the rear end of the intermediate housing 140. The rear housing 160 is provided with a discharge chamber 161 which is a space through which refrigerant compressed in the intermediate housing 140 is discharged. The refrigerant compressed in the compression chamber SB moves to the discharge chamber 161 through the discharge port 145.

A second front housing (130) is installed between the first front housing (120) and the middle housing (140). The second front housing 130 divides the motor chamber 126 and the compression chamber SB and forms a motor chamber 126 in cooperation with the first front housing 120.

4, the rotor 180 is formed in a substantially cylindrical shape with one side opened. A protruding portion 182 protruding upward is formed at the center of a bottom surface 187 of the opposite side of the rotor 180. The outer surface of the protruding portion 182 is connected to the second front housing 210 via a bearing BB2, (130). A central hole 181 is formed at the center of the protrusion 182 and a plurality of coupling holes 183 are formed around the center hole 181 in the circumferential direction. A plurality of helical grooves 185 are formed in the circumferential direction on the bottom surface 187 of the rotor 180.

The helical groove 185 is formed in the same direction as the rotational direction of the rotor 180. That is, when the rotor 180 rotates in the arrow direction (clockwise direction) as shown in the figure, the helical groove 185 is rounded in the inner circumferential direction from the outer circumference of the rotor 180.

5, the sidewall 189 of the helical groove 185 is formed to be inclined at a predetermined angle? Inward of the center of rotation of the rotor 180. As shown in FIG. That is, it is formed to be inclined inward from the inside of the bottom surface 187 of the rotor 180 along the moving direction of the rotating refrigerant. The side wall 189 is inclined so that the side wall 189 pushes the rotating refrigerant to the outside of the rotor 180, so that the refrigerant moves more smoothly.

Hereinafter, the operation of the electric compressor according to the present invention will be described in detail.

First, when power is applied to the electric compressor 100 from the outside, the motor 170 operates and the rotation shaft 124 rotates. A part of the refrigerant introduced through the suction port (not shown) formed in the first front housing 120 flows along the cooling passage 129 formed in the first front housing 120 in the direction of the arrow shown in FIG. And moves to a compression chamber S formed in the intermediate housing 140 through a space between the second front housing 130 and the bearing B2 coupled between the rotor 180 .

And the remaining refrigerant moves through the communication hole 122 connected to the suction port and flows through the space formed in the bearing BB1 coupled between the first front housing 120 and the rotary shaft 124, As shown in FIG. The refrigerant thus moved passes through the spiral groove 185 formed on the bottom surface 187 of the rotor 180 and flows through the second front housing 130 and the rotor 180, And moves to the compression chamber SB formed in the intermediate housing 140 through the space between the bearings B2.

At this time, when electric current flows through the coil wound around the stator 171, a magnetic field is generated and the rotor 180 rotates. The refrigerant flowing into the communication hole 122 is centrifugally rotated to rotate to the outside of the rotor 180 and the spiral groove 185 formed on the bottom surface 187 of the rotor 180 is rotated The refrigerant flows smoothly toward the bearing BB2 which is coupled between the second front housing 130 and the rotor 180. As a result, The side wall 189 of the helical groove 185 is inclined toward the center of rotation of the rotor 180 so that the side wall 189 pushes the rotating refrigerant toward the bearing BB2, Movement becomes more active.

The orbiting scroll 155 is moved relative to the fixed scroll 151 by the power transmitted from the motor 170 to the refrigerant moved from the first front housing 120 to the intermediate housing 140, The refrigerant is compressed in the compression chamber (SB). The compressed refrigerant is transferred to the discharge chamber 161 through the discharge port 145 formed in the intermediate housing 140.

It is to be understood that the present invention is not limited to the above-described embodiment, but is defined by the scope of the claims, and that those skilled in the art can make various changes and modifications within the scope of the claims It is obvious.

100: electric compressor 110: inverter assembly
120: first front housing 170: motor
171: stator 180: rotor
124: rotational shaft 126: motor chamber
129: cooling channel 130: second front housing
134: bearing support 136: beveled bead
138: EURO 140: Middle housing
145: discharge port 150: compression mechanism
151: fixed scroll 155: orbiting scroll
160: rear housing BB1: bearing
SB: compression chamber

Claims (3)

A first front housing 120 in which a suction port through which refrigerant flows from the outside is formed and a motor 170 for providing a driving force for compressing the introduced refrigerant is installed,
An intermediate housing 140 installed with a compression mechanism 150 for compressing the refrigerant received by receiving power from the motor 170,
A bearing support portion is formed between the first front housing 120 and the intermediate housing 140 so that the rotor 180 of the motor 170 is rotatable. And a second front housing (130)
A plurality of helical grooves 185 are formed on the bottom surface 187 of the rotor 180 along the circumferential direction of the rotor 180,
The helical groove 185 is formed in the same direction as the rotational direction of the rotor 180 and is formed to be round in the inner circumferential direction from the outer circumference of the rotor 180,
The side wall 189 of the helical groove 185 formed on the edge side of the rotor 180 is formed to be inclined from the inside to the outside of the bottom surface 187 along the moving direction of the rotating refrigerant,
And the refrigerant rotating by the helical groove (185) pushes toward the bearing coupled between the second front housing (130) and the rotor (180). delete delete

Images