KR20140137919A - Scroll compressor - Google Patents

Abstract

For a scroll compressor according to the present invention, an interference prevention portion is formed to be recessed to the outside of a rotation radius of a rotation lap with respect to a fixing lap or the rotation lap when the center of the rotation lap and the fixing lap is matched on one side wall surface of any one between the fixing lap and the rotation lap. It is possible to improve compression efficiency by preventing a gap from being generated between the fixing lap and the rotation lap since the end part of the fixing lap is inserted into the interference prevention portion and a lap interference is not generated in an arc pressure surface of the rotation lap.

Description

[0001] SCROLL COMPRESSOR [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a scroll compressor, and more particularly, to an axial through scroll compressor in which a rotary shaft overlaps a wrap of an orbiting scroll.

The scroll compressor forms a compression chamber in which the orbiting scroll of the fixed scroll and the orbiting scroll of the orbiting scroll are engaged with each other while the orbiting scroll pivots with respect to the fixed scroll and continuously moves between the fixed lap and the orbiting lap to suck and compress the refrigerant .

Such a scroll compressor has advantages over other types of compressors in terms of vibration and noise generated during operation because suction, compression, and discharge are continuously performed.

The behavior characteristics of the scroll compressor are determined by the shape of the fixed lap and the orbiting lap. The fixed lap and the orbiting lap may have any shape, but usually have the shape of an involute curve that is easy to process. The involute curve means a curve corresponding to the locus drawn by the end of the thread when the thread wound around the base circle having an arbitrary radius is released. When the involute curve is used, the thickness of the wrap is constant and the rate of volume change becomes constant. In order to obtain a high compression ratio, the winding number of the lap is increased, but the size of the compressor also increases.

On the other hand, the orbiting scroll is formed with a revolving wrap on one side of a hard plate portion in the form of a disk, and a boss portion is formed on the back surface of the hard plate portion on which the revolving wrap is not formed and is connected to a rotary shaft for swiveling orbiting scroll. This configuration can form the orbiting wrap over almost the whole area of the end plate portion, so that the diameter of the end plate portion for obtaining the same compression ratio can be reduced. On the other hand, the reaction point for applying the repulsive force of the coolant during compression and the reaction force for canceling the repulsive force are applied So that the behavior of the orbiting scroll becomes unstable in the course of operation, so that vibration and noise are increased.

As a method for solving such a problem, a so-called axial through scroll compressor in which the point where the rotary shaft 1 and the orbiting scroll 2 are coupled is formed on the same surface as the orbiting wrap 2a as shown in Fig. In such an axial through scroll scroll compressor, since the point of action of the repulsive force of the refrigerant and the point of action of the reaction force act on the same point, the problem of the inclination of the orbiting scroll (2) can be solved.

The orbiting scroll 4 is provided between the orbiting scroll 2 and the fixed scroll 3 to prevent the orbiting scroll 2 from rotating. The orbiting scroll 2 and the oval bearing 4 are coupled with the key groove 2b and the key 4a to induce the orbiting scroll 2 to perform the orbiting motion while performing relative motion. The key groove 2b of the orbiting scroll 2 and the key 4a of the oralling ring 4 are arranged in the order of a clearance gap of about 10 to 30 占 퐉 so as to allow the orbiting scroll 2 to slide with respect to the bearing 4, (? 1).

However, in the above-described conventional axial through scroll compressor, due to the clearance delta 1 formed between the key groove 2b of the orbiting scroll 2 and the key 4a of the alighting ring 4 as shown in Fig. 2 The revolving scroll 2 generates a rotating moment during the revolving motion and a specific portion between the revolving wraps 2a of the revolving scroll 2 and the fixed wraps 3a of the fixed scroll 2, When a tangent line is drawn on the arc compression surface at the center of the rotary shaft coupling portion provided in the scroll 2, an offset section occurs on both arc compression surfaces about the contact point of the arc compression surface where the tangent line meets. The wrap interference A between the orbiting wrap 2a and the fixed wrap 3a is generated due to the offset of the orbiting scroll 2 in the offset interval? There has been a problem that a leak gap B between the orbiting wrap 2a and the stationary wrap 3a is generated at another portion and a compression loss is caused.

SUMMARY OF THE INVENTION An object of the present invention is to provide a scroll compressor capable of avoiding a lap interference between an orbiting scroll and a fixed scroll to prevent occurrence of a leak gap between laps.

In order to achieve the object of the present invention, there is provided a fixed scroll having a fixed lap formed therein; And a rotary wrapping portion formed at a central portion of the rotary wrapping portion, the circular wrapping portion being engaged with the stationary wrap to form first and second compression chambers on the outer side surface and the inner side surface, A revolving scroll having a surface formed thereon and pivotally moving with respect to the fixed scroll; An orbiting ring coupled with the orbiting scroll to prevent rotation of the orbiting scroll; And a rotary shaft having an eccentric portion at one end thereof and the eccentric portion being laterally overlapped with the orbiting wrap to be coupled to the rotary shaft coupling portion of the orbiting scroll, wherein the arc compression surface has a radius of gyration And a scroll compressor is provided in which the interference avoiding portion is formed on the arc compression surface by being recessed outside the turning radius of the orbiting wrap with respect to the stationary wrap in a state where the center of the stationary wrap and the orbiting wrap are aligned with each other .

A fixed scroll in which a fixed lap is formed; And a rotary wrapping portion formed at a central portion of the rotary wrapping portion, the circular wrapping portion being engaged with the stationary wrap to form first and second compression chambers on the outer side surface and the inner side surface, A revolving scroll having a surface formed thereon and pivotally moving with respect to the fixed scroll; An orbiting ring coupled with the orbiting scroll to prevent rotation of the orbiting scroll; And a rotary shaft having an eccentric portion at one end thereof and the eccentric portion being laterally overlapped with the orbiting wrap to be coupled to the rotary shaft coupling portion of the orbiting scroll, wherein the arc compression surface has a radius of gyration And the side wall surface of the fixed lap corresponding to the arc compression surface of the orbiting scroll is shortened out of the circular arc radius from the arc compression surface in a state where the centers of the fixed lap and the orbiting wrap are aligned with each other to form the interference avoiding portion A scroll compressor may be provided.

In the scroll compressor according to the present invention, at least one sidewall surface of the fixed lap and the orbiting lap is depressed outside the turning radius of the orbiting wrap with respect to the fixed lap or the revolving lap in the state where the center of the fixed lap and the orbiting lap are aligned with each other, By forming the avoiding portion, it is possible to prevent the gap between the fixed lap and the orbiting lap from being generated due to the insertion of the end portion of the fixed lap into the interference lobe without causing the lap interference on the arc compression surface of the orbiting wrap, .

1 is a vertical sectional view showing a conventional axial through scroll compressor,
FIG. 2 is a plan view showing the combined state of the orbiting scroll and the bearing in the axial through scroll compressor according to FIG. 1,
FIG. 3 is a plan view showing the relationship between the fixed scroll and the orbiting scroll in the axial through scroll compressor according to FIG. 2,
FIG. 4 is a longitudinal sectional view showing a shaft-through scroll compressor according to the present invention, FIG.
FIG. 5 is a perspective view of the compression unit in the axial through scroll compressor according to FIG. 4,
FIG. 6 is a plan view showing a combined state of the orbiting scroll and the axial bearing in the axial through scroll compressor according to FIG. 5,
FIG. 7 is a plan view of the compression section in the axial through scroll compressor according to FIG. 4,
FIG. 8 is a perspective view showing the orbiting scroll in the axial through scroll compressor according to FIG. 4,
FIG. 9 is an enlarged view showing the interference fringe skin in FIG. 8,
Fig. 10 is a plan view showing the relationship between the fixed scroll and the orbiting scroll in the axial through scroll compressor according to Fig. 4, Fig.
FIG. 11 is a plan view showing another embodiment of the interference fringe skin in the axial through scroll compressor according to FIG. 4; FIG.

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

4 to 9, in the scroll compressor according to the present embodiment, a drive motor 30 is installed inside the sealed container 10, and a fixed A scroll 30 is fixedly installed on the upper portion of the fixed scroll 30. The fixed scroll 30 is engaged with the fixed scroll 30 and coupled to the rotary shaft 23 of the drive motor 20 to rotate the orbiting scroll 40 may be installed.

The hermetic container 10 may include a cylindrical casing 11 and an upper shell 12 and a lower shell 13 welded to cover the upper and lower portions of the casing 11, respectively. A suction pipe 14 may be installed at a side of the casing 10 and a discharge pipe 15 may be installed at an upper portion of the upper shell 12. The lower shell 13 also functions as an oil chamber for storing the supplied oil so that the compressor can be smoothly operated.

The driving motor 20 may include a stator 22 fixed to the inner surface of the casing 10 and a rotor 22 disposed inside the stator 22 and rotated by the interaction of the stator 22 have. A rotating shaft (23) rotating together with the rotor (22) can be coupled to the center of the rotor (22).

An oil passage F is formed at the center of the rotary shaft 23 along the longitudinal direction of the rotary shaft 23 and an oil for supplying the oil stored in the lower shell 13 to the upper portion is formed at the lower end of the rotary shaft 23 A pump 24 may be installed. A pin portion 23c may be eccentrically formed at an upper end of the rotary shaft 23. [

The outer peripheral surface of the fixed scroll 30 can be press-fitted and fixed between the casing 11 and the upper shell 12 in a heat shrinking manner or can be welded together with the casing 11 and the upper shell 12. [

A boss portion 32 is formed at the center of the hard plate portion 31 of the fixed scroll 30. A bearing hole 33 may be formed in the boss portion 32 such that the rotary shaft 23 passes through the boss portion 32. A first compression chamber S1 is formed on the outer surface of the orbiting wrap 42 and a second compression chamber S1 is formed on the inner surface of the orifice S2 may be formed.

The orbiting scroll (40) can be supported on the upper surface of the fixed scroll (30). The orbiting scroll 40 is formed in a substantially circular shape and has a pair of compression chambers S1 and S2 (not shown) formed on the upper surface of the rigid plate 41, The orbiting wrap 42 may be formed. A substantially circular rotary shaft engaging portion 43 may be formed at the center of the long plate portion 41 so that the pin portion 23c of the rotary shaft 23 is rotatably inserted and engaged.

The pin portion 23c of the rotary shaft 23 is inserted into the rotary shaft coupling portion 43 through the hard plate portion 31 of the fixed scroll 30 and the rotary wrap 42 and the fixed lap 34 and the pin portion 23c are inserted, May be installed so as to overlap in the radial direction of the compressor. Here, during compression, the repulsive force of the refrigerant is applied to the fixed lap 34 and the orbiting wrap 42, and a compressive force is applied between the rotary shaft engaging portion 43 and the pin portion 23c as a reaction force thereto. As described above, when the pin portion 23c of the rotary shaft 23 passes through the hard plate portion 41 of the orbiting scroll 40 and overlaps with the lap in the radial direction, the repulsive force and the compressive force of the coolant are applied to the hard plate portion 41 So that they can be offset from each other.

On the upper side of the orbiting scroll (40), an orhering (50) for preventing the orbiting scroll (40) from rotating can be coupled. The oval ring 50 has a ring portion 51 having a substantially circular shape and fitted to the back surface of the long plate portion 41 of the orbiting scroll 40 and a pair of first keys 52 projecting to one side of the ring portion 51 And a second key 53. [0050]

The first key 52 protrudes longer than the thickness of the outer circumferential side of the long plate portion 41 of the orbiting scroll 40 and can be inserted into the first key groove 31a formed over the fixed scroll 30. [

The second key 53 may be engaged with the second key groove 41a formed in the outer circumferential portion of the long plate portion 41 of the orbiting scroll 40,

The first key groove 31a and the first key 52 or the second key groove 41a and the second key 53 are formed on both sides of the key grooves 31a and 41a, In this case, if the keys 52 and 53 are brought into close contact with the key grooves 31a and 41a, the orbiting scroll 40 may not be smoothly rotated. . 6, the orbiting scroll 40 is provided between the both side surfaces of the key grooves 31a and 41a and the corresponding side surfaces of the keys 52 and 53, Can be formed to have the clearance delta 1.

On the other hand, the fixed lap 34 and the orbiting lap 42 may be formed of involute curves, but in some cases, they may be formed to have curves other than involute curves. 7, assuming that the center of the rotary shaft coupling portion 43 is O and the two contact points P1 and P2 are connected to each other, the two contact points P1 and P2 and the center O of the rotary shaft coupling portion are connected to each other It can be seen that the angle a defined by the two straight lines is smaller than 360 degrees and the distance l between the normal vectors at each contact point also has a value greater than zero. Accordingly, the compression ratio can be increased because the first compression chamber S1 just before discharge has a smaller volume than when the first compression chamber S1 has the fixed lap 34 and the orbiting wrap 42 formed of the involute curve. The orbiting wrap 42 and the stationary wrap 34 have a shape in which a plurality of arcs having different diameters and origin points are connected, and the outermost curve has a substantially elliptical shape having a major axis and a minor axis.

A projecting portion 35 projecting toward the rotary shaft engaging portion 43 is formed near the inner end of the fixed lap 34. The projecting portion 35 is provided with a contact portion 35a projected from the projecting portion 35 . Accordingly, the inner end of the fixed lap 34 can be formed to have a larger thickness than the other portions.

On the other hand, the thickness of the fixed lap 34 gradually decreases starting from the contact point P1 located on the inner side among the two contact points forming the first compression chamber S1 at the start of discharge from among the contact portions 35a . Specifically, the first decreasing portion 35b adjacent to the contact point P1 and the second decreasing portion 35c following the first decreasing portion are formed, and the thickness decreasing rate at the first decreasing portion is smaller than that at the second decreasing portion . After the second decreasing portion, the thickness of the fixed lap increases during a predetermined period.

A recess 45 may be formed on the outer circumferential surface of the rotary shaft engaging portion 43 to engage with the protrusion 35 of the fixed scroll 30. One side wall of the concave portion 45 is in contact with the contact portion 35a of the projection 35 to form one side contact point of the first compression chamber.

One side wall of the concave portion 45 has a first increasing portion 45a having a relatively increased thickness and a second increasing portion 45b having a relatively increased thickness and connected to the first increasing portion. . This corresponds to the first reduced portion 35b and the second reduced portion 35c of the fixed lap 34. [ The first increasing portion 45a, the first decreasing portion 35b, the second increasing portion 45b, and the second decreasing portion 35c are obtained as a result of folding the envelope to the rotating shaft connecting portion side. As a result, the inner contact point P1 forming the first compression chamber S1 is located in the first increase portion and the second increase portion, and the length of the first compression chamber immediately before discharge is shortened, .

The other side wall of the concave portion 45 is formed with an arcuate arc compression face 46 formed by connecting a line that contacts the end of the fixed lap 34 while the orbiting scroll 40 is swinging, As shown in FIG. The diameter of the arc of the arc compression surface 46 is determined by the wrap thickness of the fixed lap end and the turning radius of the orbiting wrap. Increasing the wrap thickness of the end of the fixed lap increases the diameter of the arc. As a result, the thickness of the orbiting wrap around the arc can be increased to ensure durability, and the compression path becomes longer, thereby increasing the compression ratio of the second compression chamber.

In the above-described axial through scroll compressor according to the present embodiment, when the rotary shaft 23 rotates by applying power to the driving motor 20, the orbiting scroll 40 eccentrically connected to the rotary shaft 23 has a constant trajectory And the compression chambers S1 and S2 formed between the orbiting scroll 40 and the fixed scroll 30 continuously move to the center of the orbiting motion and the volume is reduced to continuously suck and compress the refrigerant And repeats a series of discharging processes.

In order to allow the orbiting scroll 40 and the orhering ring 50 to slide with respect to each other, the orbiting scroll 40 is rotated by the keyhole 50 of the orbiting scroll 40, A tolerance gap delta 1 of about 10 to 30 mu m is required between the key 44 and the keys 52 and 53 of the otal bearing 50. [ However, the orbiting scroll 40 generates the rotating moment by the clearance delta 1, and during the actual operation, the lap interference A is generated between the fixed lap 34 and the orbiting lap 42 as shown in Fig. 3 .

6 to 9, in the present embodiment, a predetermined depth in the thickness direction of the orbiting wrap 42 is formed on the arc compression surface 46 formed in the concave portion 45 of the orbiting scroll 40 The interference fringe skin 46a having the same shape as that of Fig. The portion where the interference fringe skin 46a is formed is different from the other portion having the gap r of the turning radius in the state where the center of the fixed lap 34 and the orbiting wrap 42 are aligned with each other, And the depth (r + [delta] 2).

For example, as shown in FIG. 9, when the rotation angle of the rotary shaft 23 is interfered with the first curved surface P11-P12 between the first point P11 and the arbitrary second point P12, The first curved surface P12-P13 constituting the skin 46a is positioned so as to position the starting point of the second curved surface P12-P13, and the third curved surface P12- And the end point of the second curved surface constituting the interference fringe skin 46a is positioned on the third curved surface between the four points P14. The depth of the interference fringe skin 46a may be formed to be smaller than or equal to the tolerance gap del. If the depth of the interference fringe skin 46a is larger than the tolerance gap delta 1, a gap is generated between the fixed lap 34 and the orbiting wrap 42, and the compression performance may be significantly reduced.

6, it is assumed that a rotation angle (radian) of the rotation shaft 23 is?, A tolerance gap is? 1, a shortest distance between the center of the second keyway and the rotation axis coupling portion is L1, When the shortest distance is L2 and the depth of the interference skin is δ2, the equation for obtaining δ2 is as follows.

α × L1 = δ1 --------- Equation 1.

α × L2 = δ2 --------- Equation 2.

Substituting equation (1) into equation (2), we obtain δ2 = δ1 × (L2 / L1).

For example, the tolerance gap delta 1 is 30 mu m, the shortest distance L1 between the second keyway 41a and the center of the rotation shaft engagement portion 43 is 53 mm, the shortest distance between the center line between the orbiting wraps and the center of the rotation axis engagement portion When the distance L2 is 23 mm, the depth (offset amount,? 2) of the interference fringe skin is? 2 = 30 x 23/53 = 13.0 m. Therefore, it is preferable that the depth of the interference fringe skin is formed to have a value calculated by? 2 = (? 1 x (L2 / L1)) 占 5 占 퐉.

10, the end of the fixed lap 34 is inserted into the interference lap skin 46a without causing the lap interference at the circular compression surface 46 of the orbiting wrap 42, And the gap between the orbiting wrap (42) is prevented from being generated, so that the compression efficiency can be improved.

In the embodiment described above, the interference fringe skin 46a is formed on the arc compression surface 46 of the orbiting scroll 42. However, in this embodiment, the circular arc compression surface 46a of the orbiting scroll 40 (34) of the fixed scroll (30) corresponding to the fixed scroll (46).

In this case, the interference fringe skin 32a is fixed to the outer circumferential surface of the fixed lap 34, which is in contact with the arcuate compression surface 46, within the range of the range in which the arc compression advances with reference to the orbiting scroll 40, In the thickness direction of the substrate.

Here, the depth of the interference fringe skin 32a is smaller than the tolerance gap delta 1 formed between the key groove 41a of the orbiting scroll 40 and the key 53 of the orhering ring 50 as in the above embodiment It may be preferable to form the same. The operation and effect of the present invention are substantially similar to those of the above-described embodiment, and a description thereof will be omitted.

30: fixed scroll 31a: first key groove
32: Fixed lap 32a: Interfering skin
40: orbiting scroll 41a: second keyway
42: orbiting wrap 46: circular compression surface
46a: Interference skin 50:
52,53: Key

Claims (7)

A fixed scroll in which a fixed lap is formed;
And a rotary wrapping portion formed at a central portion of the rotary wrapping portion, the circular wrapping portion being engaged with the stationary wrap to form first and second compression chambers on the outer side surface and the inner side surface, A revolving scroll having a surface formed thereon and pivotally moving with respect to the fixed scroll; And
And a rotating shaft having an eccentric portion at one end thereof and the eccentric portion being laterally overlapped with the orbiting wrap to be coupled to the rotating shaft engaging portion of the orbiting scroll,
Wherein the arc compression surface is spaced apart from the side wall surface of the stationary wrap by a turning radius,
Wherein the arc compression surface is spaced apart by a turning radius from a first point to an arbitrary second point at which the arc compression surface starts, and a second curve from the second point to a third point Wherein the curved surface is spaced a greater distance than the turning radius and the third curved surface from the third point to the fourth point where arc compression ends is spaced apart by a turning radius. The method according to claim 1,
Further comprising an articulation coupled to the orbiting scroll to prevent rotation of the orbiting scroll,
Wherein a clearance gap is formed between the orbiting scroll and the billet, and a maximum depth of the second curved surface is formed to be equal to or smaller than the clearance gap. 3. The method of claim 2,
A plurality of keyways are radially formed in the orbiting scroll so as to engage the key of the bearing,
The shortest distance between the center of the key groove and the center of the rotary shaft is L1,
The shortest distance between the center line between the orbiting wraps and the center of the rotation axis coupling portion is L2,
The clearance gap between the abovementioned bearing and the keyway is? 1,
The depth of the second curved surface is? 2,
If the rotation angle (radian) of the rotation shaft is?
? 2 = (? 1 × (L2 / L1)) ± 5 μm. A fixed scroll in which a fixed lap is formed;
And a rotary wrapping portion formed at a central portion of the rotary wrapping portion, the circular wrapping portion being engaged with the stationary wrap to form first and second compression chambers on the outer side surface and the inner side surface, A revolving scroll having a surface formed thereon and pivotally moving with respect to the fixed scroll; And
And a rotating shaft having an eccentric portion at one end thereof and the eccentric portion being laterally overlapped with the orbiting wrap to be coupled to the rotating shaft engaging portion of the orbiting scroll,
Wherein the arc compression surface is spaced apart from the side wall surface of the stationary wrap by a turning radius,
The side wall surface of the fixed lap corresponding to the arc compression surface of the orbiting scroll or the circular compression surface of the orbiting scroll is shortened from the fixed lap or the arc compression surface to the outside of the orbiting radius in the state where the center of the orbiting wrap And the relief portion is formed. In the fourth aspect,
Wherein the interference fringe skin is formed within a range from a rotation angle at which arc compression starts to a rotation angle at which arc compression ends. The method according to claim 4 or 5,
Further comprising an articulation coupled to the orbiting scroll to prevent rotation of the orbiting scroll,
Wherein a clearance gap is formed between the orbiting scroll and the art wheel, and a maximum depth of the interference skin is formed to be equal to or smaller than the clearance gap. The method according to claim 6,
A plurality of keyways are radially formed in the orbiting scroll so as to engage the key of the bearing,
The shortest distance between the center of the key groove and the center of the rotary shaft is L1,
The shortest distance between the center line between the orbiting wraps and the center of the rotation axis coupling portion is L2,
The clearance gap between the abovementioned bearing and the keyway is? 1,
The depth of the interfering skin is? 2,
If the rotation angle (radian) of the rotation shaft is?
? 2 = (? 1 × (L2 / L1)) ± 5 μm.

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