KR101658094B1 - Scroll compressor - Google Patents

Abstract

A scroll compressor according to the present invention includes: a casing; A driving motor provided in an inner space of the casing; A frame provided on one side of the driving motor; A fixed scroll fixed to the frame; A revolving scroll provided between the frame and the fixed scroll and forming a pair of two compression chambers between the fixed scroll and the fixed scroll; A rotary shaft coupled to the drive motor and the orbiting scroll to transmit the rotational force of the drive motor to the orbiting scroll; And an electromagnetic filter assembly (EMC filter assembly) detachably coupled to the outer surface of the casing. Thus, the EMC filter can be easily replaced without changing the related parts, and the second filter Vibration is suppressed, and only the filter module is replaced when the EMC filter is replaced, so that the replacement operation of the EMC filter can be facilitated.

Description

[0001] SCROLL COMPRESSOR [0002]

The present invention relates to a scroll compressor, and more particularly to a scroll compressor applied to a vehicle.

Generally, a compressor is a device for compressing a fluid such as a refrigerant gas. The compressor may be classified into a rotary compressor, a reciprocating compressor, a scroll compressor, and the like according to a method of compressing a fluid.

The scroll compressor is a high-efficiency low-noise compressor widely applied to a building air conditioner as well as a vehicle air conditioner. The scroll compressor has a pair of compression chambers formed by a suction chamber, an intermediate compression chamber, and a discharge chamber between the two scrolls while the two scrolls are rotating relative to each other. The compression chamber continuously moves in the center direction, So that the refrigerant is continuously sucked and compressed and discharged.

1 is a cross-sectional view showing the inside of a conventional scroll compressor.

As shown in the figure, the scroll compressor of the related art has a structure in which a frame 2 is fixedly coupled to an internal space of a casing 1, and a driving motor 3 for generating a rotating force is installed on one side of the frame 2, A rotating shaft 4 passing through the frame 2 and coupled to the orbiting scroll 6 and transmitting rotational force of the driving motor 3 is coupled to the center of the rotor 32 of the driving motor 3.

The casing 1 includes a main housing 11 provided with the drive motor 3 and forming a discharge space S3 and a main housing 11 connected to the rear side of the main housing 11 to cover the oil pump 45 A rear cap 12 and a front cap 13 covering the front side of the main housing 11 to form a suction space S1 and a front cover 13 coupled to the front surface of the front cap 13, S5 which form the top cover 14 of the first embodiment. A suction port 13a is formed in the front cap 13 and a discharge port 12a is formed in the rear cap 12.

A non-orbiting scroll (hereinafter referred to as a fixed scroll) 5 is fixedly provided on the front side of the frame 2 and a pair of two pairs of compression An orbiting scroll (6) is coupled to form a seal (P), and a rotation preventing member (7) is provided between the orbiting scroll (6) and the frame (2) to prevent rotation of the orbiting scroll Is installed. The anti-rotation member 7 is of a pin-ring type.

The frame 2 is formed in a disc shape with a hard plate portion 21 (hereinafter, referred to as a first hard plate portion) 21, and is protruded from the outer peripheral portion toward the fixed scroll 5 on the front surface of the first hard plate portion 21, A main side wall portion (hereinafter referred to as a first side wall portion) 22 to which the fixed scroll 5 is coupled is formed. A turning space 23 is formed at the center of the first hard plate 21 so that the boss 63 of the orbiting scroll will be pivotally moved, and the turning space 23 and the first side wall 22, A thrust surface 24 is formed so that the orbiting scroll 6 is axially supported. A sealing member 25 is inserted into the thrust surface 24 so as to form a sealing surface in contact with the back surface of the orbiting scroll 6 and a pin- A member 7 is provided. A main bearing 81 for supporting one side of the rotary shaft 4 is coupled to the frame 2.

The driving motor 3 includes a stator 31 coupled to the main housing 11 and a rotor 32 rotatably inserted into the stator 31.

The central portion of the rotary shaft 4 is coupled to the rotor 32 of the drive motor 3 and the front side of the rotary shaft 4 about the rotor 32 is supported by the main bearing 81 While the rear side is radially supported by the sub-bearing 82 provided in the main housing 11. The sub-

An eccentric portion 41 is formed at the front end of the rotary shaft 4 and the eccentric portion 41 is coupled to the boss portion 63 of the orbiting scroll 6 with an eccentric bearing 83 interposed therebetween have.

An oil passage 42 is formed in the rotary shaft 4 and an oil pump 45 for pumping the oil of the main housing 11 is coupled to a rear end of the rotary shaft 4.

The fixed scroll 5 is formed with a fixed lap 52 on one side of the fixed plate 51 and a suction port 53 formed on one side of the fixed plate 51, And a discharge port 54 is formed at the center. A discharge cover 55 is provided around the discharge port 54 to seal the discharge port 54 and form an intermediate space S2 to be communicated with the discharge space S3. The drive motor 3 is provided.

The orbiting scroll 6 is formed in a disc shape with a hard plate portion (hereinafter referred to as a third hard plate portion) 61, and on the front surface of the third hard plate portion 61, And a boss portion 63 is formed on a rear surface of the third hard plate portion 61 so as to be coupled to the rotation shaft 4 and to be supported by the thrust surface 24. [

Various devices (IGBTs) 91 for controlling the inverter are connected to the inverter board 92 and the support plate 93 and are provided on the outer surface of the front cap 13 in the inverter accommodating space S5.

In the figure, the reference symbol S4 is a storage space.

The conventional scroll compressor as described above operates as follows.

That is, when power is applied to the driving motor 3, the rotary shaft 4 rotates together with the rotor 32 of the driving motor 3, and the orbiting scroll 6 is rotated to the rotation preventing member 7 A pair of compression chambers composed of a suction chamber, an intermediate pressure chamber, and a discharge chamber are provided between the fixed lap 52 and the orbiting lap 62, P are continuously formed.

As the volume of the compression chamber P is reduced as the compression chamber P is moved to the center by the continuous pivotal movement of the orbiting scroll 6, the refrigerant flows into the suction space S1 of the front cap 13 through the suction port 13a The refrigerant is sucked into the compression chamber P through the suction port 53 provided in the fixed scroll 5 and discharged to the intermediate space S2 through the discharge port 54. Then, Is discharged to the outside of the compressor through the discharge space (S3) of the compressor (11). The flow of such refrigerant is shown by the dotted arrow in Fig.

At this time, the refrigerant discharged through the discharge port 54 is mixed with oil to move to the discharge space S3, and the refrigerant and the oil are separated from the discharge space S3, and the refrigerant is discharged through the discharge port 12a, While the oil is collected in the discharge space S3 and supplied to the sliding section through the oil pump 45. [

However, when the conventional scroll compressor as described above is applied to an automobile, an EMC filter assembly (hereinafter referred to as an EMC filter) for removing electromagnetic noise should be provided in the casing and installed in the engine room. However, The engine room can not be easily changed due to the nature of the EMC filter. Therefore, when the specification of the EMC filter is changed, the components of the compressor must be newly designed in consideration of the interference between the EMC filter and other components.

Further, in the related art, there is a problem that the EMC filter is integrally coupled to the inverter substrate, and the inverter substrate is also replaced when the EMC filter is replaced.

An object of the present invention is to provide a scroll compressor capable of easily detaching and attaching an EMC filter.

It is another object of the present invention to provide a scroll compressor capable of reducing the cost loss by allowing the EMC filter to be replaced while maintaining the inverter substrate.

In order to achieve the object of the present invention, A driving motor provided in an inner space of the casing; A frame provided on one side of the driving motor; A fixed scroll fixed to the frame; A revolving scroll provided between the frame and the fixed scroll and forming a pair of two compression chambers between the fixed scroll and the fixed scroll; A rotary shaft coupled to the drive motor and the orbiting scroll to transmit the rotational force of the drive motor to the orbiting scroll; And an electromagnetic filter assembly (EMC filter assembly) detachably coupled to the outer surface of the casing.

Here, the casing is provided with a filter space having a predetermined space for accommodating the electromagnetic filter assembly, and the filter space includes an outer surface of the space for accommodating the filter module so that the electromagnetic filter assembly can be detached from the outside Can be opened.

The electromagnetic wave filter assembly includes: a filter substrate; A plurality of filter elements and input / output terminals mounted on the filter substrate; And a filter housing having a main body accommodating space for accommodating the filter substrate and the filter substrate mounted thereon, and a filter housing inserted into the filter module accommodating space of the filter space unit.

In addition, an inner side surface and an outer side surface of the main body accommodating space may be open, and a seating recess may be formed between the inner side surface and the outer side surface of the main body accommodating space to accommodate the filter substrate.

The electromagnetic wave filter assembly includes: a filter substrate; A plurality of filter elements and input / output terminals mounted on the filter substrate; And a molding material surrounding the filter element and the filter substrate to expose the input / output terminal.

The electromagnetic wave filter assembly may further include a filter housing into which the molding material is inserted and inserted into the filter space.

The input terminal and the output terminal are mounted on different surfaces of the filter substrate. The input terminal and the output terminal are spaced apart from each other at a predetermined interval. Respectively.

The plurality of filter elements may be mounted on the surface of the filter substrate on which the output terminal is mounted.

A filter cover for supporting the electromagnetic filter assembly may be coupled to the opening of the filter space.

The casing includes: a main housing having an internal space to accommodate the driving motor; A front housing coupled to one side of the main housing and defining a suction space between the main housing and the main housing; And an inverter cover which is coupled to one side of the front housing and forms an inverter accommodating space in which an inverter control unit is provided between the front housing and the front housing, wherein the front housing is provided with a filter space portion .

The scroll compressor according to the present invention is capable of easily replacing the EMC filter without changing the related parts such as the inverter board even if the specification of the EMC filter is required, It is possible to reduce the vibration noise of the compressor by suppressing the secondary vibration in the inverter substrate by the EMC filter.

In addition, since the EMC filter accommodates the filter substrate in the filter housing and is formed in a module shape, only the filter module needs to be replaced when the EMC filter is replaced, thereby facilitating the replacement operation of the EMC filter.

1 is a sectional view showing a conventional lateral scroll compressor,
2 is a vertical cross-sectional view of a lateral scroll compressor according to the present invention,
FIG. 3 is a perspective view of the main housing and the rear housing of the compressor shown in FIG. 2,
FIG. 4 is a plan view showing an inverter accommodating space for explaining the arrangement of inverter elements in the compressor according to FIG. 2,
FIG. 5 is a sectional view for explaining a fixed state of the fixed scroll with respect to the back surface in the compressor according to FIG. 2;
FIG. 6 is a sectional view showing a state in which a rear side of a rotary shaft is supported by sub-bearings in the compressor according to FIG. 2;
FIG. 7 is a sectional view for explaining the fixed state of the stator with respect to the rear end in the compressor according to FIG. 2;
FIG. 8 is a sectional view showing a state where a frame is fixed to a casing in the compressor according to FIG. 2;
Fig. 9 is a schematic view for explaining the point of action of the force according to the press-in length between the frame and the casing in Fig. 8,
FIG. 10 is a perspective view showing a front housing in which an electromagnetic wave filter assembly is mounted in the compressor according to FIG. 2,
FIG. 11 is a perspective view of the electromagnetic filter assembly shown in FIG. 10,
FIG. 12 is a longitudinal sectional view showing a state in which the electromagnetic wave filter assembly according to FIG. 10 is assembled;
13 and 14 are exploded perspective views of another embodiment of the electromagnetic wave filter assembly according to FIG.

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

3 is a perspective view showing a main housing and a rear housing in an exploded view of the compressor according to FIG. 2, FIG. 4 is a perspective view showing the arrangement of inverter elements in the compressor according to FIG. 2, Fig. 3 is a plan view showing an inverter accommodating space for explaining the inverter accommodating space.

2, the scroll compressor according to the present embodiment includes a casing 110 formed to be long in the lateral direction, a driving motor 120 provided in the casing 110 to generate rotational force, A frame 140 installed on a front side of the driving motor 120 to support the rotation shaft 130 and a frame 140 disposed on a front side of the frame 140, The fixed scroll 150 includes a fixed scroll 150 and a frame 140. The fixed scroll 150 and the frame 140 are coupled to the rotating shaft 130 to rotate together with the fixed scroll 150, And an orbiting scroll (160) forming a seal (P).

2, the casing 110 includes a main housing 111 formed to be long in the lateral direction, a rear housing 112 coupled to the rear side of the main housing 111, A front housing 113 coupled with the front side of the front housing 113 and an inverter cover 114 coupled to the front side of the front housing 113. An inverter accommodating space S5 in which an inverter 191 for controlling the inverter and the inverter board 192 are mounted may be formed on the inside of the inverter cover 114.

As shown in FIG. 2, the main housing 111 may be formed in a cylindrical shape and open at the front side, while the rear side may be formed in a shape in which the blocking portion 115 is clogged.

A stator supporting surface (hereinafter referred to as a first supporting surface) 111a for supporting the stator 121 of the driving motor 120 to be described later in an axial direction is formed stepwise on the rear side of the inner circumferential surface of the main housing 111, A frame supporting surface (hereinafter referred to as a second supporting surface) 111b for axially supporting the rear surface of the frame 140 may be formed on the inner circumferential surface front side of the housing 111.

2 and 3, a shaft hole 115a is formed at the center of the cut-off portion 115 so that the rear end of the shaft 130 passes through the shaft hole 115a. (Hereinafter referred to as a second insertion groove) 115b on which the sub-bearing 182 is mounted, and the outer ring 136b of the oil pump 136, which will be described later, is formed on the rear surface around the shaft hole 115a. So that the pump insertion groove 115c can be formed.

The upper portion of the cut-off portion 115 is moved from the compression chamber P to the inner space of the main housing 111 which is the discharge space S3 and the refrigerant separated from the oil is discharged from the discharge port of the rear housing 112 The oil separated from the refrigerant in the discharge space S3 of the main housing 111 is supplied to the oil pump 136 through the oil pump 136, An oil passage hole 115d is formed so that the oil passage hole 115d is formed so as to be guided and the oil passage space S4 is formed between the rear face of the blocking portion 115 and the front face of the rear housing member 112, Can be formed.

In the rear surface of the blocking portion 115 and the front surface of the rear housing 112, a plurality of oil storage spaces S4 are formed on both sides of the oil supply guide protrusion 115f And a discharge guide groove 115j through which the discharge port 110b communicates is formed between the pressure equalization grooves 115g with a plurality of partition protrusions 115h interposed therebetween . Thus, the oil flowing into the oil storage space S4 together with the refrigerant can be minimized from flowing out to the discharge port 110b.

The communicating groove 115i for discharging the refrigerant flowing into the oil storage space S4 through the oil passage hole 115e toward the discharge port 110a may be formed very shallowly in the partition protrusion 115h. Although the communication groove 115i may be formed in the partitioning projection 112e of the rear housing 112 side, it is advantageous in terms of processability to be formed together with the member into which the first sealing member 116 is inserted have.

As shown in FIGS. 2 and 3, the rear housing 112 is formed in a circular plate shape, and an annular fastening protrusion 112a protruding forwardly from the outer circumferential portion and closely contacting the rear surface of the main housing 111 may be formed. have. An oil supply groove 112b is formed at the center of the front surface of the rear housing 112 to receive the discharge side of the oil pump 136 and to guide the pumped oil to the oil passage 135 of the rotary shaft 130, The oil supply groove 112b may be formed in a radial direction (up and down direction in the figure) by projecting a oil supply passage 112c communicating the oil storage space S4 with the suction side of the oil pump 136 by a predetermined height have. The oil supply passageway 112c may be formed by the oil supply guide protrusion 115f provided in the blocking portion 115 of the main housing 111. [ A plurality of partition protrusions 112e extending in the radial direction are formed on the outer peripheral surface of the oil supply groove 112b so as to form pressure balance grooves 112d on both sides of the oil supply passage 112c, A gas guide groove 112f communicating with the discharge port 110b may be formed between the pressure equalizing grooves 112d. The pressure equalizing groove 112d can form the oil storing space S4 together with the pressure equalizing groove 115g of the main housing 111 to be described later.

The pressure equalizing grooves 112d and the partitioning protrusions 112e and the discharge guiding grooves 112f of the rear housing 112 are respectively connected to the pressure equalizing grooves 115g provided in the blocking portions 115 of the main housing 111, The partition protrusion 115h, and the discharge guide groove 115j, respectively. The partitioning protrusion 115h formed in the blocking portion 115 of the main housing 111 may be shallower than the partitioning protrusion 112e of the rear housing 112. [

A sealing member for preventing leakage (hereinafter referred to as a first sealing member) 116 such as an o-ring in consideration of a manufacturing cost is provided between the rear housing 112 and the main housing 111 to prevent leakage of refrigerant, May be provided. The first sealing member 116 is inserted into the sealing groove 112 so that the first sealing member 116 is inserted into the front end surface of the fastening protrusion 112a of the rear housing 112 or the rear surface of the blocking portion 115 of the main housing 111, An example formed on the rear surface of the main housing is shown in the drawing) 115k. Since the sealing groove 115k is formed in the housing on which the communication groove 115i is formed, it is possible to process the sealing groove 115k and the communication groove 115i together while precisely processing only one housing, Lt; / RTI >

2, the front housing 113 is formed in a shape having a tubular outer wall portion 117 having front and rear both sides opened. In the middle of the inner peripheral surface of the outer wall portion 117, And a partition wall 118 separating the rear side from the rear side can be formed. Thus, the rear side can form the suction space S1 by the partition 118, while the front side can form the inverter accommodating space S5. In addition, an insulated gate bipolar transistor (IGBT) 191 and an inverter board 192 necessary for driving the compressor may be installed on the front surface of the partition 118. The element 191 generates high heat when the compressor is driven, so that a heat transfer member 193 such as a thermal sheet is attached to the front surface of the partition 118 to dissipate the heat, The heat dissipation effect can be enhanced by attaching the element 191 to the front surface of the heat dissipation plate 193.

In addition, it is preferable that the element 191 is disposed mainly on the suction path of the refrigerant sucked into the suction space S1, because the heat radiation effect can be further enhanced. 4, when the suction port 110a is formed on the right side of the drawing and the suction port 154 of the compression chamber P is located below the drawing, the refrigerant having passed through the suction port 110a has a centrifugal force So that it can be moved in a substantially curved shape toward the suction port 154 while being rolled to the left side of the drawing. Therefore, when the second imaginary line L2 is extended in the radial direction from the center of the suction port 154 so as to be perpendicular to the first imaginary line L1 extending in the traveling direction from the center of the inlet 110a The element 191 is arranged mainly in a region opposite to the region where the inlet 110a is formed with respect to the second imaginary line L2. The element 191 and the refrigerant sucked by the element 191 are arranged on the partition wall 118 So that it can be preferable.

2 and 5, a suction port 110a through which a suction pipe SP is connected is formed on a side surface of the front housing 113, and an inner circumferential surface of the fixed scroll 150 (Hereinafter, referred to as a third support surface) 113a that axially supports the back surface of the long plate portion 151 of the second guide plate 151. [ The frame 140 and the fixed scroll 150 are supported axially on both sides between the second support surface 111b and the third support surface 113a so that the frame 140 and the fixed scroll 150 It is possible to suppress the movement of the containing compression mechanism in the axial direction.

As shown in FIG. 2, the surface of the inverter cover 114 may be flat, but a plurality of heat dissipation fins (not shown) may be formed on the outer surface of the inverter cover 114 to enhance heat dissipation.

2, the driving motor 120 includes a stator 121 fixed to the inside of the main housing 111 and a stator 121 located inside the stator 121 and rotating As shown in FIG.

6, the stator 121 is fixed to the main housing 111 and is fixed to the first supporting surface 111a of the main housing 111, And can be supported. The rotor 122 may be rotatably inserted into the stator 121.

The rotary shaft 130 may include a shaft portion 131 coupled to the rotor 132 and an eccentric portion 132 coupled to the boss portion 163 of the orbiting scroll 160. The main bearing portion 133 and the sub bearing portion 134 are formed on the front and rear sides of the shaft portion 131 with respect to the rotor 122 so that the main bearing portion 181 and the sub bearing portion 182, And can be supported in the radial direction. The eccentric portion 132 may be inserted into an eccentric bearing 183 to be described later to transmit the rotational force to the orbiting scroll 160.

An oil passage 135 for supplying oil to the sliding portion is formed in the rotary shaft 130 and a rear end portion of the oil passage 135 is connected to the discharge space S3 of the main housing 110, An oil pump 136 for pumping oil to the oil passage 135 may be provided. The inner ring 136a is coupled to the sub bearing portion 134 of the rotary shaft 130 while the outer ring 136b is disposed on the rear side of the main housing 110. [ Inserted into the second insertion portion 115c.

As shown in FIGS. 2 and 7, the sub bearing portion 134 may have a smaller diameter than the shaft portion 131. A bearing support surface 134a may be formed between the sub bearing portion 134 and the shaft portion 131 so that the inner ring 182a of the sub bearing 182 can be axially supported. Both ends of the inner ring 182a of the sub bearing 182 are supported by the second inserting portion 115h and the bearing supporting surface 134a so that the rotation shaft 130 can be prevented from being pushed rearward do. Since the front side of the rotary shaft 130 is axially supported by the frame 140 and the orbiting scroll 150 as shown in FIG. 2, the rotary shaft 130 does not move in the axial direction, have.

2 and 8, the frame 140 may be inserted into the opening of the main housing 111 and fixedly coupled thereto. The frame 140 may be supported on the second support surface 111b provided on the inner circumferential surface of the front end of the main housing 111 to be axially supported.

The frame 140 is formed in a disk shape and has a hard plate portion 141 (hereafter referred to as a first hard plate portion) 141. The frame 140 protrudes from the front surface of the first hard plate portion 141, (Hereinafter referred to as a first sidewall portion) 142 may be formed. 7, the outer circumferential surface of the first side wall portion 142 may be formed to be in contact with the outer circumferential surface of the first fixed plate portion 141, The diameter D1 of the hypothetical line connecting the outer circumferential surface of the first side wall portion 142 to the inner circumferential surface of the first hard plate portion 141 including the first hard plate portion 141 is larger than the outer diameter of the first hard plate portion 141 D2). The outer circumferential portion of the first rigid plate 141 extends in the radial direction from the outer circumferential surface of the first side wall portion 142 and is press-fitted into the open end of the main housing 111, The outer circumferential surface of the first sidewall portion 142 may be spaced apart from the inner circumferential surface of the main housing 111 by a predetermined distance.

9, the thickness h3 of the fixing protrusions 143 may be set to be less than the thickness h2 of the fixing protrusions 143. However, when the thickness h3 of the fixing protrusions 143 is greater than the thickness h2 of the fixing protrusions 143, The center O 'of the fixing protrusion 143 is positioned more forward than the center O of the first rigid plate 141 by a predetermined distance? H, . The central portion of the first rigid plate 141 may be bent in the direction of the driving motor 120 when the fixed protrusion 143 is pressed into the main housing 111. [ Accordingly, as in the present embodiment, the axial center O 'of the fixing protrusion 143 is spaced apart from the axial center O of the first rigid plate 141 by zero The thickness h3 of the fixing protrusion 143 is formed to be equal to the thickness h1 of the first rigid plate 141 in the state where the center O and O ' And the force F1 and F2 applied to the other side in the frame 140 are canceled each other so that the load F3 toward the rear side can be minimized.

A thrust surface 144 is formed on the inner side of the first side wall portion 142 and supported by the orbiting scroll 160 so that the orbiting scroll 160 is supported at the center of the thrust surface 144, (Hereinafter referred to as a first turning space) 145 may be formed so that a boss portion 163, which will be described later, coupled with the boss portion 130 can perform a turning motion. A second sealing member 146 for separating the first turning space 145 into an inner space and an outer space is installed on a thrust surface (or a sealing surface) 144 around the first turning space 145 . (Hereinafter referred to as a second turning space) 147 is formed on the outer side of the second sealing member 146 so that the hard plate portion 161 of the orbiting scroll 160 to be described later can pivot, A rotation preventing member 170 for preventing the rotation of the orbiting scroll 160 may be installed on the thrust surface 144 belonging to the second turning space 147.

7, the anti-rotation member 170 may be formed as a pin-ring type, but the anti-blocking may be applied in some cases. The rotation preventing member of the pin-ring type is configured such that a plurality of pins 171 are coupled to the orbiting scroll 160 and the pin 171 is connected to the thrust surface 144 of the corresponding frame 140, The ring 172 can be inserted into the pin groove 148 so as to be pivotally inserted.

On the other hand, a main bearing insertion portion (first insertion portion) 149 is formed on the other side surface of the first hard plate portion 141 so as to protrude rearward. The first insertion portion 149 is provided with the driving motor 120, A main bearing 181 for supporting one side of the rotation shaft 130 in a radial direction may be inserted. The main bearing 181 may be a ball bearing provided between the first inserting portion 149 and the main bearing portion 133 of the rotating shaft 130. Accordingly, the refrigerant of the discharge pressure filled in the discharge space of the casing can be moved to the first turning space 145 through the gap formed between the balls of the main bearing.

As shown in FIG. 2, the fixed scroll 150 is formed in a disk shape with a hard plate portion (hereinafter referred to as a second hard plate portion) 151, and on one side of the second hard plate portion 151, (Hereinafter referred to as a second sidewall portion) 152 protruding toward the first fixed plate portion 142 is formed at the center of the second fixed plate portion 151. The center portion of the second fixed plate portion 151 is engaged with the orbiting wrap 162, And a suction port 154 communicating with the suction space S1 is formed at an edge of the second longitudinal plate portion 151. The second longitudinal plate portion 151 is formed with a second longitudinal plate 151, A discharge port 155 communicating with the intermediate space S2 in the final compression chamber may be formed at the center of the discharge port 151. [

5, the front end of the second longitudinal plate 151 is seated on the third supporting surface 113a of the front housing 113 to support the front end of the second longitudinal plate 151, (Hereinafter referred to as a third sealing member) 156 provided between the outer circumferential surface of the front housing 113 and the inner circumferential surface of the front housing 113 for partitioning the suction space S1 into the discharge space S3, A sealing groove 151a may be formed. The sealing groove 151a may be formed on the front surface of the second longitudinal plate 151 or may be formed on the inner circumferential surface of the front housing 113 contacting the second longitudinal plate 151.

The orbiting scroll 160 is formed in a disc shape with a hard plate portion 161 and a protruding portion 162 protruding toward the second hard plate portion 151 on the front surface of the third hard plate portion 161. [ The swivel wrap 162 is formed on the rear surface of the third rigid plate 161 so as to be coupled with the rotation shaft 130 to form a first swivel space And a boss portion 163 for pivotally moving inside the boss portion 145 may be formed.

An eccentric bearing 183 of a ball bearing may be provided between the inner circumferential surface of the boss portion 73 and the outer circumferential surface of the eccentric portion of the rotating shaft (more precisely, between the balance weights coupled to the eccentric portion). Accordingly, the high-pressure refrigerant passing through the main bearing 181 flows into the inner space of the first turning space 145, thereby forming the back pressure chamber in the inner space of the first turning space 145.

Reference numeral 157 denotes a discharge cover, 164 denotes an inner space of the boss portion, 182b denotes an outer ring, and 182b denotes a ball.

The assembling process of the scroll compressor according to the present embodiment as described above is as follows.

That is, the stator 121 of the driving motor 120 is fitted and coupled to the main housing 111. At this time, the rear end of the stator 121 is seated on the first supporting surface 111a provided on the inner circumferential surface of the main housing 111, thereby preventing the stator 121 from flowing to the rear end.

Next, the rotor 122 to which the rotation shaft 130 is coupled is inserted into the stator 121. At this time, a sub bearing 182 is inserted and fixed to the sub bearing portion 134 of the rotating shaft 130. Bearing support surface 134a is stepped on sub-bearing portion 134 so that the rotation shaft 130 can be restrained from flowing in the axial direction toward the rear side.

Next, the fixing protrusion 143 of the frame 140 is press-fitted into the main housing 111. At this time, since the second supporting surface 111b is provided in the main housing 111, the rear surface of the frame 140 is seated on the second supporting surface 111b so that the frame 140 flows in the axial direction Can be suppressed. In the frame 140, since the centers O and O 'in the thickness direction of the rigid plate 141 and the fixing protrusion 143 are formed at the same height, in the process of press-fitting the frame into the main frame, Even if the portion 141 receives a radial repulsive force from the main housing 111, the force can be suppressed from being deformed by the first hard plate portion 141 being canceled.

Next, the anti-rotation member 170, the orbiting scroll 160, and the fixed scroll 150 are placed on the frame 140, and then the fixed scroll 150 is bolted to the frame 140. Then, the front housing 113 is placed on the front surface of the main housing 111, and the bolts are fastened. At this time, the third support surface 113a of the front housing 113 supports the front surface of the long plate 151 of the fixed scroll 150, It can be suppressed from being pushed toward the front housing 113. A third sealing member 156 is inserted into the outer circumferential surface of the fixed scroll 150 so that the inner space of the front housing 113 is connected to the suction space S1 and the inner space of the main housing 111 is connected to the discharge space (S3).

Next, various elements 191 for controlling the inverter are attached to the partition 118 of the front housing 113, and the inverter cover 192, to which the elements 191 are coupled, is bolted, 114 to the front housing 113 to complete the assembly of the scroll compressor. However, it is also possible to fasten the front housing 113 to the main housing 111 after the inverter cover 114 is fastened to the front housing 113 first.

The operation and effect of the scroll compressor according to the present embodiment as described above are as follows.

That is, when power is applied to the driving motor 120, the rotation shaft 130 rotates together with the rotor 122 of the driving motor 120 to transmit rotational force to the orbiting scroll 160.

The orbiting scroll 160 is rotated by an eccentric distance by the eccentric portion 132 of the rotary shaft 130 and the rotation preventing member 170 so that the compression chamber P is continuously moved toward the center side The volume is reduced.

The refrigerant flows into the suction space S1 through the suction port 110a as shown by an arrow and the refrigerant flowing into the suction space S1 flows into the compression chamber P through the suction port 154 Inhaled.

The refrigerant sucked into the compression chamber P is compressed toward the center side along the movement path of the compression chamber P and is discharged to the intermediate space S2 through the discharge port 155. [

The refrigerant discharged to the intermediate space S2 is moved to the discharge space S3 through the fixed scroll 160 and an exhaust passage (not shown) of the frame 140, And then discharged to the outside of the compressor through the refrigerant hole 115d of the rear housing 112 and the discharge port 110b of the rear housing 112. [

At this time, the oil is separated from the refrigerant in the discharge space S3 and becomes high in the lower portion of the main housing 111. The oil is discharged from the oil hole (not shown) of the blocking portion 115 by the pressure of the discharge space S3 115e of the main housing 111 to the oil storage space S4 between the main housing 111 and the rear housing 112. [ The oil in the oil storage space S4 is pumped by the oil pump 136 and circulated to the sliding portion.

The oil flowing into the oil storage space S4 may be discharged to the discharge port together with the oil flowing into the oil storage space S4 through the cooling hole 115d. It is possible to minimize the leakage of the oil mixed with the refrigerant as the refrigerant is intercepted by the refrigerant pipes 112e and 115h.

The oil flowing into the oil storage space S4 is mixed with a part of the refrigerant. However, the refrigerant is separated from the oil storage space S4 and flows through the communication groove 115i provided in the blocking portion side partition protrusion 115h And can be discharged to the discharge port 110b. Accordingly, the oil in the oil storage space S4 can be separated from the refrigerant and smoothly guided to the oil pump 136 through the oil supply passage 112c provided in the rear housing 112. [

Also, since the refrigerant sucked into the compression chamber P is directly sucked through the suction space S1, the refrigerant can be prevented from being preheated before being sucked into the compression chamber P, thereby reducing the suction loss of the refrigerant.

The refrigerant flowing into the suction space S1 through the suction port 110a is sucked into the suction port 154 through the suction space S1 while the refrigerant circulates through the suction space S1 As the inverter control elements 191 are arranged to be close to the flow path, the heat generated in the elements can be effectively dissipated.

Meanwhile, when the scroll compressor is applied to an electric vehicle, the EMC filter must be installed inside the compressor. Recently, however, the size of the EMC filter has been increasing as the standards for the EMC filter have been strengthened. Therefore, when replacing the EMC filter installed inside the compressor, there may be a problem that the other parts inside the compressor must be newly designed.

In view of this, in the present embodiment, the EMC filter is detachably provided from the outside of the compressor by separating the EMC filter from the inverter substrate, so that the EMC filter that meets the standard can be easily replaced, if necessary, without changing other components in the compressor.

FIG. 10 is a perspective view showing a front housing equipped with an electromagnetic wave filter assembly in the compressor according to FIG. 2, FIG. 11 is a perspective view of the electromagnetic wave filter assembly according to FIG. 10, FIG. 13 and FIG. 14 are perspective views explaining another embodiment of the electromagnetic wave filter assembly according to FIG. 10 in a assembled state.

2 and 10, an outer circumferential surface of the front housing 113 is provided with a gap between the outer wall portion 117 of the front housing 113 and the partition wall portion 118 so that the EMC filter 200 is inserted into the outer circumferential surface of the outer housing surface. A filter space portion 119 may be formed.

The filter space portion 119 has a filter module accommodation space 119a in which a filter module 210 to be described later is accommodated. The outer surface of the filter module accommodation space 119a is connected to the filter module 210, The inner side surface of the terminal hole 216 is electrically connected to the inner terminal 196 extending from the inverter board 192. The inner terminal 196 is connected to the output terminal 216, The first electrode 119c may be formed. Thus, the outer surface of the filter module housing space 119a is formed to be opened by the outer opening surface 119b, while the inner surface of the filter module housing space 119a may be formed in a clogged shape except for the terminal hole 119c.

At least one coupling groove 119d may be formed around the outer opening surface 119b of the filter space 119 so as to be bolted together with a filter cover 250 to be described later. A sealing member (not shown) such as an O-ring or a gasket may be interposed between the periphery of the outer opening surface 119b of the filter space portion 119 and the filter cover 250.

The EMC filter 200 includes a filter module 210 inserted into the filter module accommodation space 119a of the filter space part 119 to perform filtering operation on electromagnetic waves, And a filter cover 250 that covers the outer opening surface 119b of the filter module 210 and supports the filter module 210.

The filter module 210 includes a filter housing 211 inserted into the filter module accommodation space 119a of the filter space 119 and a filter substrate 212 inserted and accommodated in the filter housing 211, A plurality of filter elements 213 and 214 mounted on the filter substrate 212 to filter electromagnetic waves, an input terminal 215 connected to the external terminal 195 to receive the high voltage, An output terminal 216 connected to the internal terminal 196 to output the filter substrate 212 to the filter housing 211 and a molding unit 217 for covering the outer surface of the filter substrate 212 and fixing the filter substrate 211 to the filter housing 211.

The filter housing 211 may be formed of an insulating material such as resin. A main housing space 211a is formed in the filter housing 211 to receive the filter main body including the filter substrate 212. A filter housing 211 is formed on one side of the main housing housing space 211a. The inner side surface 211b is formed while the outer side surface is opened to form the outer side opening surface 211b, while the inner side surface forming the other side surface is mostly clogged or partially opened to form the inner side through hole 211c. The inner through hole 211c may be formed corresponding to the terminal hole 119c of the filter space portion 119. [

The outer opening 211b of the filter housing 211 is formed at least wider than the filter substrate 212 and the inner through hole 211c of the filter housing 211 is larger than the width of the filter substrate 212 It can be formed small. Accordingly, the filter substrate 212 can be inserted inward from the outside of the filter housing 211.

The inner surface of the filter housing 211 may have a seating protrusion 211d on which the filter substrate 212 is placed. The filter substrate 212 is inserted into the main body accommodating space 211a from the outer opening surface 211b and then is seated on the seating protrusion 211d so that the filter substrate 212 is moved in the molding process for the outer opening surface 21b. The deformation of the filter substrate 212 can be suppressed.

A sealing protrusion 211e for enlarging the sealing area of the filter cover 250 with respect to the filter cover 250 when the filter cover 250 is mounted is formed around the opening surface 211b of the filter housing 211, And an expansion portion 211f is formed on the outer side of the outer space 119b of the filter space portion 119. The expansion portion 211f is formed with an opening At least one through hole 211g may be formed so as to communicate with the coupling groove 119d formed in the vicinity of the through hole 119b and penetrate the bolt.

The plurality of filter elements may comprise a CM filter 213 and a DM filter 214, respectively. The CM filter 213 and the DM filter 214 may be mounted on the output terminal 216 of the filter substrate 212. The CM filter 213 may be mounted on the output terminal 216 of the filter substrate 212, And the DM filter 214 may be arranged at right angles to each other.

The input terminal 215 is mounted on the inner surface of the filter substrate 212 while the output terminal 216 is mounted on the outer surface of the filter substrate 212. The input terminal 215 and the output terminal 216 may be installed at both ends of the filter substrate 212 in the longitudinal direction. Thus, when connecting the input terminal 215 and the external terminal 195, and connecting the output terminal 216 and the internal terminal 196, it is possible to secure a connection space to minimize the required space.

The molding part 217 is provided on the filter substrate 212 so as to cover the outer surface of the filter substrate 212 on which the plurality of filter terminals 213 and 214 and the input and output terminals 215 and 216 are mounted. May be formed by injecting a molding liquid from the outer opening surface 211b of the filter housing 211 while the filter housing 211 is inserted into the filter housing 211. [

However, in the molding process, a part of the molding liquid may move toward the inner through hole 211c so that the inner through hole 211c may also be covered. When the inner through hole 211c and the outer opening surface 211b are covered with each other, the input terminal 215 and the output terminal 216 are connected to each molding portion (only the outer molding portion in the drawing) And can be exposed through.

Here, the outer opening surface 211b may be covered with the outer opening surface 211b of the filter housing 211 by a filter cover 250, which will be described later. In this case, the filter cover 250 can support the filter substrate 212.

The filter cover 250 may be formed of an aluminum material such as the casing 110. However, in some cases, it may be formed of an insulating material such as plastic.

The filter cover 250 is formed in a box shape having a terminal accommodating space 251 to receive an external terminal 195 electrically connected to the output terminal 216, The outer opening surface 119b of the filter space portion 119 is formed to support the outer opening surface 211b of the filter housing 211 so that the outer opening surface 119b of the filter space portion 119 can be covered. May be formed to be wider than or equal to the width.

A coupling part 252 which is in close contact with an extension part 211f of the filter housing 211 is extended to the outer side surface of the filter cover 250 around the opening face, At least one fastening hole 252a may be formed so as to correspond to the through hole 211g of the fastening member 240.

The operation and effect of the scroll compressor according to the present embodiment as described above are as follows.

That is, when the EMC filter 200 needs to be replaced as needed, the bolts fastened to the casing 110 are loosened to separate the filter cover 250 from the casing 110, (215) and the output terminal (216) from the respective external terminal (195) and the internal terminal (196).

In the process of unfastening the bolts fastened to the casing 110, the filter housing 211 is also disengaged so that the filter module 210 is separated from the filter module accommodating space 119a of the filter space 119.

The other filter module 210 is inserted into the filter module accommodation space 119a of the filter space part 119 and then the input terminal 215 and the output terminal 216 of the filter module 210 are connected to the respective external terminals The filter cover 250 is connected to the internal terminal 196 and then the filter cover 250 is tightened with bolts to complete the filter replacement operation.

Since the inverter substrate and the EMC filter are separated from each other and the EMC filter can be attached to and detached from the filter accommodating portion from the outside of the compressor, even if the specification of the EMC filter of the vehicle to which the scroll compressor is applied is required, It is possible to easily replace the EMC filter without changing the related components such as the substrate and to suppress the secondary vibration in the inverter substrate by the EMC filter as the filter module of the relatively heavy EMC filter is separated from the inverter substrate It may be desirable to reduce vibration noise of the compressor.

In addition, since the EMC filter accommodates the filter substrate in the filter housing and is formed in a module shape, only the filter module needs to be replaced when the EMC filter is replaced, thereby facilitating the replacement operation of the EMC filter.

Meanwhile, another embodiment of the scroll compressor according to the present invention is as follows.

13, the filter module 220 includes a filter housing 221 having a body accommodating space 221a, and the filter housing 220 includes a filter accommodating space 221a, And a filter main body 228 detachably detachable from the main body accommodating space 221a of the filter housing 221. [

The filter housing 221 may be formed similarly to the above-described embodiment. That is, the outer side surface of the filter housing 221 may have an area where the filter body 228 can be attached and detached, while an inner side surface of the filter body 228 may be formed to have a width such that the filter body 228 is not detached .

The filter body 228 includes a filter substrate 222 and various filter elements 223 and 224 and input and output terminals 225 and 226 to be mounted on the filter substrate 222. The filter substrate 222, The filter elements 223 and 224 and the input and output terminals 225 and 226 are molded in a separate space so that the filter substrate 222 and the filter elements 223 and 224 and the input and output terminals 225 and 226 And a molding housing 227 which surrounds the molding housing 227. The filter substrate 228 may be formed of the filter substrate 222, various filter elements 223 and 224, input / output terminals 225 and 226, and a molding housing 227.

The filter housing 228 can be detachably inserted into the filter housing 221 and the filter housing 221 can be coupled to the filter module housing space 119a of the filter space portion 119 of the casing 110 So that it can be detachably coupled. The filter module 220 is coupled to the outer opening surface 119b of the filter space 119 by the filter cover 250 covering the filter module 220 of the EMC filter, . The effect of this is very similar to the above-described embodiment. However, since the filter main body 228 of the EMC filter is modularized and attached to and detached from the filter housing 221, the filter housing 221 is not required to be replaced when the filter is replaced, Can be saved.

In another embodiment of the scroll compressor according to the present invention, the following will be described.

That is, in the above-described embodiments, when the filter housing is provided, in this embodiment, the filter body 228 is directly connected to the filter module accommodating space 119a of the filter space portion 119 without the filter housing 221 of FIG. Detachably. Accordingly, in this embodiment, the filter body itself forms a filter module.

14, the filter cover 250 supporting the filter module 230 of the EMC filter is coupled to the outer opening surface 119b of the filter space portion 119 to be modularized into the molding material So as to support the filter module 230. The effect of this is very similar to the above-described embodiment. However, in this embodiment, the filter housing is removed and the filter housing is replaced by the molding material as compared with the above-described embodiment, thereby further reducing the manufacturing cost.

110: casing 111: main housing
112: rear housing 113: front housing
114: inverter cover 115:
117: outer wall portion 118: partition wall portion
120: drive motor 130:
131: shaft portion 135: oil channel
136: Oil pump 140: Frame
150: fixed scroll 151: second hard plate
152: second side wall portion 153: stationary wrap
154: Suction port 155: Discharge port
156: third sealing member 160: orbiting scroll
162: orbiting wrap 163: boss portion
170: anti-rotation member 119: filter space part
119a: Filter module accommodating space 119b: Outside opening face
119c: terminal hole 195: external terminal
196: Internal terminal 200: EMC filter
210, 220, 230: filter module 211, 221: filter housing
211a: Body accommodating space 211b: Outside opening face of the filter housing
211c: inner through hole 211d:
211e: sealing projection 211f:
211g: through hole 212, 222: filter substrate
213, 214, 223, 224: filter elements 215, 216, 225, 226: input /
217: molding part 228: filter body
250: Filter cover

Claims (10)

Casing;
A driving motor provided in an inner space of the casing;
A frame provided on one side of the driving motor;
A fixed scroll fixed to the frame;
A revolving scroll provided between the frame and the fixed scroll and forming a pair of two compression chambers between the fixed scroll and the fixed scroll;
A rotary shaft coupled to the drive motor and the orbiting scroll to transmit the rotational force of the drive motor to the orbiting scroll; And
And an electromagnetic filter assembly (EMC filter assembly) detachably coupled to the outer surface of the casing,
A filter space portion having a predetermined space for receiving the filter module is formed in the casing so that the electromagnetic wave filter assembly is inserted into the filter space portion, the outer surface of the space for accommodating the filter module is opened so that the electromagnetic wave filter assembly can be detached from the outside ,
The electromagnetic filter assembly includes:
A filter substrate;
A plurality of filter elements and input / output terminals mounted on the filter substrate; And
And a filter housing having a body accommodating space for accommodating the filter substrate and the filter substrate mounted thereon, and a filter housing inserted into the filter module accommodating space of the filter space unit. delete delete The method according to claim 1,
Wherein an inner side surface and an outer side surface of the main body accommodating space are open, and a seating recess is formed between the inner side surface and the outer side surface of the main body accommodating space to accommodate the filter substrate. Casing;
A driving motor provided in an inner space of the casing;
A frame provided on one side of the driving motor;
A fixed scroll fixed to the frame;
A revolving scroll provided between the frame and the fixed scroll and forming a pair of two compression chambers between the fixed scroll and the fixed scroll;
A rotary shaft coupled to the drive motor and the orbiting scroll to transmit the rotational force of the drive motor to the orbiting scroll; And
And an electromagnetic filter assembly (EMC filter assembly) detachably coupled to the outer surface of the casing,
A filter space portion having a predetermined space for receiving the filter module is formed in the casing so that the electromagnetic wave filter assembly is inserted into the filter space portion, the outer surface of the space for accommodating the filter module is opened so that the electromagnetic wave filter assembly can be detached from the outside ,
The electromagnetic filter assembly includes:
A filter substrate;
A plurality of filter elements and input / output terminals mounted on the filter substrate; And
And a molding material surrounding the filter element and the filter substrate to expose the input / output terminal. 6. The method of claim 5,
Wherein the electromagnetic wave filter assembly further comprises a filter housing into which the molding material is inserted and inserted into the filter space portion. The method according to any one of claims 1 to 5,
Wherein the input / output terminals comprise an input terminal and an output terminal separated from each other,
Wherein the input terminal and the output terminal are mounted on different surfaces of the filter substrate, and the input terminal and the output terminal are mounted on both ends of the filter substrate at regular intervals. 8. The method of claim 7,
And the plurality of filter elements are mounted so as to be positioned on a surface of a filter substrate on which the output terminal is mounted. 6. The method according to claim 1 or 5,
And a filter cover for supporting the electromagnetic filter assembly is coupled to the opening surface of the filter space part. 6. The apparatus according to claim 1 or 5,
A main housing having an inner space such that the driving motor is provided;
A front housing coupled to one side of the main housing and defining a suction space between the main housing and the main housing; And
And an inverter cover coupled to one side of the front housing and defining an inverter accommodating space in which an inverter control unit is provided between the inverter housing and the front housing,
And a filter space is formed in the front housing to accommodate the electromagnetic filter assembly.

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