阅读说明：本技术 涡旋式压缩机 (Scroll compressor having a discharge port ) 是由 稻叶弘展 佐藤泰造 今井哲也 于 2020-03-16 设计创作，主要内容包括：提供一种涡旋式压缩机,有效地抑制由使定涡盘及动涡盘在压缩反作用力或热膨胀的影响下变形并由此产生的局部碰撞的发生,并缩短了习惯时间。定涡盘(21)和动涡盘(22)的环绕件(24、32)构成为,在最外周的卷绕结束部与最内周的卷绕开始部之间具有多个层差部,高度随着从卷绕结束部向卷绕开始部阶梯状地减小。各层差部的位置和高度设定为,在将涡旋状的各环绕件(24、32)在规定的平面上展开时,各层差部的基点载置于在平面上绘制的规定的圆弧上。(Provided is a scroll compressor which effectively suppresses the occurrence of local collision caused by deformation of a fixed scroll and a movable scroll due to the influence of compression reaction force or thermal expansion, and which shortens the time of usage. The wraparound members (24, 32) of the fixed scroll (21) and the movable scroll (22) are configured to have a plurality of step portions between a winding ending portion at the outermost periphery and a winding starting portion at the innermost periphery, and the heights of the step portions decrease from the winding ending portion to the winding starting portion. The position and height of each step portion are set such that, when each spiral wrap (24, 32) is developed on a predetermined plane, the base point of each step portion is placed on a predetermined arc drawn on the plane.)

1. A scroll compressor includes a compression mechanism composed of a fixed scroll and an orbiting scroll, in which respective spiral-shaped surrounding members are formed to face respective front surfaces of mirror plates, and the orbiting scroll is moved while a compression chamber formed between the surrounding members of the two scrolls is reduced from an outer side to an inner side by orbiting and orbiting movements of the orbiting scroll with respect to the fixed scroll, so as to compress a working fluid,

it is characterized in that the preparation method is characterized in that,

the wrap of the fixed scroll and the wrap of the movable scroll are configured to have a plurality of step portions between a winding ending portion of an outermost circumference and a winding starting portion of an innermost circumference, and a height thereof is reduced stepwise from the winding ending portion to the winding starting portion,

the position and height of each of the stepped portions are set such that, when each of the spiral wraps is stretched on a predetermined plane, a base point of each of the stepped portions is placed on a predetermined arc drawn on the plane.

2. The scroll compressor of claim 1,

each of the step portions is formed in an arc shape of a concentric circle.

3. The scroll compressor of claim 2,

each of the step portions has an arc shape concentric with a base circle of a scroll of each of the surrounds or the mirror plate.

4. The scroll compressor of any one of claims 1 to 3,

the outermost step portion is located at a position located 180 ° or more inward from the winding end portion.

5. The scroll compressor of claim 4,

the outermost step portion is located at an inward side of 270 ° from the winding end portion.

Technical Field

The present invention relates to a scroll compressor for compressing a working fluid through a compression chamber formed between surrounding members of two scrolls by orbiting a movable scroll relative to a fixed scroll.

Background

Conventionally, this scroll compressor includes a compression mechanism including a fixed scroll including a spiral surrounding member on a front surface of a mirror plate and an orbiting scroll including a spiral surrounding member on a front surface of the mirror plate, wherein a compression chamber is formed between the surrounding members by opposing the surrounding members of the respective scrolls, and the orbiting scroll is moved while reducing a volume of the compression chamber from an outer side to an inner side by orbiting movement of the orbiting scroll relative to the fixed scroll by a motor, thereby compressing a working fluid (refrigerant).

In this case, the innermost circumference (central portion) of each scroll deforms in a convex shape under the influence of compression reaction force or thermal expansion. Accordingly, although the local collision occurs and the volumetric efficiency decreases, the operation is performed for a predetermined period of time so that the volumetric efficiency is improved or saturated with respect to time (habit time (japanese: らし)). This is because, although the locally collided portion is cut to an allowable shape, that is, a run-in (japanese: dye/(だ)), due to the wear with time, when the operation is performed under a high load condition in a state where there is no wear at the start of the operation (a state before the run-in), the surface pressure of the locally collided portion increases, and the risk of damage to the scroll increases.

Therefore, a technique is considered in which the height of the wrap is gradually reduced from the winding end portion of the outermost circumference of the scroll (for example, see patent documents 1, 2, and 3). Accordingly, it is considered that a shape which does not cause local collision due to the influence of the compression reaction force or the thermal expansion can be adopted.

Documents of the prior art

Patent document

Patent document 1: japanese patent laid-open publication No. 2017-15000

Patent document 2: japanese patent application laid-open No. 2002-364561

Patent document 3: japanese patent laid-open No. Hei 11-190287

Disclosure of Invention

Technical problem to be solved by the invention

However, the above conventional measures alone have a problem that actual wear of the scroll cannot be coped with, and further, occurrence of local collision cannot be effectively suppressed.

The present invention has been made to solve the above-described conventional problems, and an object of the present invention is to provide a scroll compressor which effectively suppresses occurrence of local collision caused by deformation of a fixed scroll or a movable scroll due to an influence of a compression reaction force or thermal expansion, and which shortens a time required for the conventional operation.

Technical scheme for solving technical problem

In order to solve the above technical problems, the present invention provides a scroll compressor including a compression mechanism composed of a fixed scroll and an orbiting scroll, a spiral surrounding member formed on each of the fixed scroll and the movable scroll and facing each front surface of each mirror plate, wherein the movable scroll revolves and revolves with respect to the fixed scroll, so as to move while contracting from the outside to the inside a compression chamber formed between the respective surrounding members of the two scrolls, for compressing working fluid, the surrounding member of the fixed scroll and the surrounding member of the movable scroll are formed, a plurality of step portions are provided between the winding end portion at the outermost periphery and the winding start portion at the innermost periphery, the height of the step portions decreases stepwise from the winding end portion to the winding start portion, the position and height of each step portion are set, when each spiral wrap is developed on a predetermined plane, the base point of each step portion is placed on a predetermined arc drawn on the plane.

The scroll compressor according to the invention of claim 2 is characterized in that each of the step portions is formed in an arc shape of concentric circles.

The scroll compressor according to the invention of claim 3 is characterized in that each of the step portions has an arc shape concentric with a base circle or a mirror plate of the scroll of each of the surrounds.

The scroll compressor according to the invention of claim 4 is characterized in that, in each of the above inventions, the outermost step portion is located at a position of 180 ° or more inward from the winding end portion.

The scroll compressor according to claim 5 is characterized in that, in addition to the above invention, the outermost step portion is located at an angle of 270 ° inward from the winding end portion.

Effects of the invention

According to the present invention, a scroll compressor includes a compression mechanism constituted by a fixed scroll and an orbiting scroll, in which respective spiral surrounds of the fixed scroll and the orbiting scroll are formed to face respective fronts of mirror plates, and the orbiting scroll orbits relative to the fixed scroll so as to move while a compression chamber formed between the surrounds of the two scrolls is reduced from an outer side to an inner side to compress a working fluid, the surrounds of the fixed scroll and the orbiting scroll are constituted so that a plurality of step portions are provided between a winding end portion of an outermost periphery and a winding start portion of an innermost periphery, heights of the step portions decrease stepwise from the winding end portion to the winding start portion, positions and heights of the step portions are set so that a base point of each step portion is placed on a predetermined arc drawn on a predetermined plane when each of the spiral surrounds is expanded on the predetermined plane, therefore, the height of the surrounding member of each scroll can be set in a state of being worn by local collision due to the influence of the compression reaction force or thermal expansion, that is, in a state close to the actual shape of each scroll in a running-in state. This can effectively suppress the occurrence of local collision and significantly shorten the so-called habituation time until the volumetric efficiency is saturated.

In particular, by making each step portion in the shape of an arc having concentric circles as in the invention of claim 2, and more preferably in the shape of an arc having concentric circles with the base circle or the mirror plate of the scroll of each of the surrounds as in the invention of claim 3, the height of the surround of each scroll can be more accurately matched to the actual worn shape of the scroll, and occurrence of local collision can be more effectively suppressed.

Further, by positioning the outermost step portion at a position located 180 ° or more inward from the winding end portion as in the invention of claim 3, and more preferably at a position located 270 ° inward from the winding end portion as in the invention of claim 4, the stability when each scroll is placed so as to place the wrap below is improved, and the reference for setting the height of the wrap is also easily obtained.

Drawings

Fig. 1 is a sectional view of a scroll compressor to which an embodiment of the present invention is applied.

Fig. 2 is a plan view of a fixed scroll of the scroll compressor of fig. 1 as viewed from a side of a surround.

Fig. 3 is a plan view of an orbiting scroll of the scroll compressor of fig. 2 viewed from a side of a surround.

Fig. 4 is a view showing a state where the surrounding member of each scroll is developed on a plane.

Fig. 5 is a graph illustrating the position and height of the stepped portion at the tip when the scroll wrap is expanded as in fig. 4.

Fig. 6 is a graph showing the wear height of the tip of the orbiting member of each scroll when the difference in height between the winding end portion and the winding start portion of the orbiting member of each scroll is changed.

Detailed Description

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings. Fig. 1 is a sectional view of a scroll compressor 1 to which an embodiment of the present invention is applied. The scroll compressor 1 of the embodiment is a so-called inverter-integrated scroll compressor used in a refrigerant circuit of a vehicle air conditioner, for example, and configured to suck a carbon dioxide refrigerant as a working fluid of the vehicle air conditioner, compress the carbon dioxide refrigerant, and discharge the compressed carbon dioxide refrigerant, and includes a motor 2, an inverter 3 for operating the motor 2, and a compression mechanism 4 driven by the motor 2.

The scroll compressor 1 of the embodiment includes: a main housing 6 that houses the motor 2 and the inverter 3 inside the main housing 6; a compression mechanism housing 7 that houses the compression mechanism 4 inside the compression mechanism housing 7; an inverter cover 8; and a compression mechanism cover 9. The main casing 6, the compression mechanism casing 7, the inverter cover 8, and the compression mechanism cover 9 are made of metal (aluminum in the embodiment), and are integrally joined to constitute a casing 11 of the scroll compressor 1.

The main casing 6 is composed of a cylindrical peripheral wall portion 6A and a partition wall portion 6B. The partition wall 6B is a partition wall that partitions the interior of the main casing 6 into a motor housing portion 12 that houses the motor 2 and an inverter housing portion 13 that houses the inverter 3. One end surface of the inverter housing portion 13 is open, and the opening is closed by the inverter cover 8 after housing the inverter 3.

The other end surface of the motor housing 12 is open, and the opening is closed by the compression mechanism case 7 after housing the motor 2. A support portion 16 is provided so as to protrude from the partition wall portion 6B, and the support portion 16 supports one end portion (an end portion on the opposite side from the compression mechanism 4) of the rotating shaft 14 of the motor 2.

The compression mechanism housing 7 is open on the side opposite to the main housing 6, and the opening is closed by a compression mechanism cover 9 after the compression mechanism 4 is housed. The compression mechanism casing 7 is composed of a cylindrical peripheral wall portion 7A and a frame portion 7B on one end side (main casing 6 side) of the peripheral wall portion 7A, and the compression mechanism 4 is accommodated in a space defined by the peripheral wall portion 7A and the frame portion 7B. The frame 7B is a partition wall that partitions the inside of the main casing 6 and the inside of the compression mechanism casing 7.

Further, the frame portion 7B is opened with a through hole 17 through which the other end portion (end portion on the compression mechanism 4 side) of the rotating shaft 14 of the electric motor 2 is inserted, and a front bearing 18 that supports the other end portion of the rotating shaft 14 is fitted to the compression mechanism 4 side of the through hole 17. Further, reference numeral 19 denotes a seal member for sealing the outer peripheral surface of the counter shaft 14 and the inside of the compression mechanism case 7 at the through hole 17 portion.

The motor 2 is composed of a stator 25 around which a coil 35 is wound and a rotor 30. Further, for example, a direct current from a battery (not shown) of the vehicle is converted into a three-phase alternating current by the inverter 3, and the rotor 30 is driven to rotate by supplying power to the coil 35 of the motor 2.

A suction port, not shown, is formed in the main casing 6, and the refrigerant sucked from the suction port is sucked into a suction portion 37, which will be described later, outside the compression mechanism 4 in the compression mechanism casing 7 after passing through the main casing 6. Thereby, the motor 2 is cooled by the sucked refrigerant. The refrigerant compressed by the compression mechanism 4 is discharged from a discharge port, not shown, formed in the compression mechanism cover 9 from a discharge space 27, which will be described later, that is a discharge side of the compression mechanism 4.

The compression mechanism 4 is constituted by a fixed scroll 21 and a movable scroll 22 both made of metal (aluminum alloy, magnesium alloy, or cast iron). The fixed scroll 21 integrally includes a disk-shaped mirror plate 23 and a spiral surround 24, the surround 24 is formed by an involute or a curve close to the involute which is erected on a front surface (one surface) of the mirror plate 23, and the front surface of the mirror plate 23 on which the surround 24 is erected is fixed to the compression mechanism case 7 as a frame portion 7B side. Here, in the embodiment, the center of the base circle of the spiral surround 24 coincides with the center of the mirror plate 23. A discharge hole 26 is formed in the center of the mirror plate 23 of the fixed scroll 21, and the discharge hole 26 communicates with a discharge space 27 in the compression mechanism cover 9. Reference numeral 28 denotes an outlet valve provided at an opening on the back surface (the other surface) side of the mirror plate 23 of the outlet 26.

The orbiting scroll 22 is a scroll that orbits and revolves with respect to the fixed scroll 21, and integrally includes a disk-shaped mirror plate 31, a spiral surround 32, and a boss portion 33, the surround 32 is formed by an involute or approximately involute curve that stands on the front surface (one surface) of the mirror plate 31, and the boss portion 33 is formed protruding at the center of the back surface (the other surface) of the mirror plate 31. Here, in the embodiment, the center of the base circle of the spiral surround 32 coincides with the center of the mirror plate 31. The orbiting scroll 22 is disposed so that the protruding direction of the orbiting scroll 32 is set to the fixed scroll 21 side, the orbiting scroll 32 faces the orbiting scroll 24 of the fixed scroll 21 to be engaged with each other while facing each other, and a compression chamber 34 is formed between the respective orbiting scrolls 24 and 32.

That is, the surround 32 of the orbiting scroll 22 is opposed to the surround 24 of the fixed scroll 21, and is engaged in such a manner that the front end of the surround 32 contacts the front surface of the mirror plate 23 and the front end of the surround 24 contacts the front surface of the mirror plate 31. A drive projection 48 is provided at the other end of the rotating shaft 14, that is, at the end on the orbiting scroll 22 side, and the drive projection 48 projects at a position eccentric from the axial center of the rotating shaft 14. Further, a cylindrical eccentric bush 36 is attached to the driving projection 48, and is provided to be eccentric from the axial center of the rotating shaft 14 at the other end portion of the rotating shaft 14.

In this case, the eccentric bush 36 is attached to the driving projection 48 at a position eccentric from the axial center of the eccentric bush 36, and the eccentric bush 36 is fitted to the boss portion 33 of the orbiting scroll 22. When the rotation shaft 14 rotates together with the rotor 30 of the motor 2, the orbiting scroll 22 orbits and revolves around the fixed scroll 21 without rotating. Reference numeral 49 denotes a balance weight attached to the outer peripheral surface of the rotary shaft 14 on the orbiting scroll 22 side of the front bearing 18.

Since the orbiting scroll 22 orbits eccentrically with respect to the fixed scroll 21, the eccentric direction and contact position of the respective orbiting members 24 and 32 move while being rotated, and the volume of the compression chamber 34 into which the refrigerant is sucked from the suction portion 37 on the outer side gradually decreases while moving from the outer side to the inner side. Thereby, the refrigerant is compressed and finally discharged from the discharge hole 26 at the center to the discharge space 27 through the discharge valve 28.

In fig. 1, reference numeral 38 denotes an annular thrust plate. The thrust plate 38 is a member for defining a back pressure chamber 39 formed on the back surface side of the mirror plate 31 of the orbiting scroll 22 and a suction portion 37 as a suction pressure region outside the compression mechanism 4 in the compression mechanism casing 7, and is located outside the boss portion 33 and interposed between the frame portion 7B and the orbiting scroll 22. Reference numeral 41 denotes a seal member attached to the back surface of the mirror plate 31 of the orbiting scroll 22 and abutting against the thrust plate 38, and the back pressure chamber 39 and the suction portion 37 are defined by the seal member 41 and the thrust plate 38.

Reference numeral 42 denotes a seal member which is attached to a surface of the frame portion 7B on the thrust plate 38 side and which abuts against the outer peripheral portion of the thrust plate 38 to seal between the frame portion 7B and the thrust plate 38.

In fig. 1, reference numeral 43 denotes a back pressure passage formed from the compression mechanism cover 9 to the compression mechanism casing 7, and an orifice 44 is installed in the back pressure passage 43. The back pressure passage 43 is configured to communicate with the back pressure chamber 39 in the discharge space 27 of the compression mechanism cover 9 (discharge side of the compression mechanism 4), and thereby oil at a discharge pressure reduced and adjusted by the orifice 44 is mainly supplied to the back pressure chamber 39 as indicated by an arrow in fig. 1.

A back pressure load for pressing the orbiting scroll 22 against the fixed scroll 21 is generated by the pressure (back pressure) in the back pressure chamber 39. By pressing the orbiting scroll 22 against the fixed scroll 21 against the compression reaction force from the compression chamber 34 of the compression mechanism 4 by the back pressure load, the contact of the surrounding members 24, 32 with the mirror plates 31, 23 is maintained, so that the refrigerant can be compressed by the compression chamber 34.

On the other hand, an oil passage 46 penetrating in the axial direction is formed in the rotary shaft 14, and a pressure regulating valve 47 located on the support portion 16 side is provided in the oil passage 46. The oil passage 46 communicates the back pressure chamber 39 with the inside of the main casing 6 (suction pressure region), and the oil that flows into the back pressure chamber 39 from the back pressure passage 43 flows into the oil passage 46 from the inlet port 52 and flows out of the main casing 6, but the pressure regulating valve 47 opens when the pressure (back pressure) in the back pressure chamber 39 becomes maximum, and functions so that the back pressure does not continue to rise.

Next, the shapes of the tip portions of the orbiting scroll 32 and the orbiting scroll 24 of the fixed scroll 21 and the orbiting scroll 22 constituting the compression mechanism 4 will be described with reference to fig. 2 to 6. Fig. 2 is a plan view of the fixed scroll 21 as viewed from the side (front surface side) of the orbiting member 24, and fig. 3 is a plan view of the orbiting scroll 22 as viewed from the side (front surface side) of the orbiting member 32.

As shown in fig. 2, the orbiting scroll 24 of the fixed scroll 21 has a spiral shape from a winding start portion 24A at the innermost circumference to a winding end portion 24B at the outermost circumference. Further, a plurality of (six in the embodiment) step portions 51 to 56 are formed between the winding end portion 24B and the winding start portion 24A at the leading end portion of the hoop 24, and the height of the hoop 24 gradually decreases from the winding end portion 24B to the winding start portion 24A.

In the embodiment, the outermost step portion is denoted by a symbol "51", the inner step portion thereof is denoted by a symbol "52", the further inner step portion thereof is denoted by a symbol "53", the further inner step portion thereof is denoted by a symbol "54", the further inner step portion thereof is denoted by a symbol "55", and the innermost step portion thereof is denoted by a symbol "56". The outermost and height-increasing tip portion of the stepped portions 51 to 56 is denoted by a symbol "61", the inner tip portion thereof is denoted by a symbol "62", the further inner tip portion thereof is denoted by a symbol "63", the further inner tip portion thereof is denoted by a symbol "64", the further inner tip portion thereof is denoted by a symbol "65", the further inner tip portion thereof is denoted by a symbol "66", and the innermost tip portion thereof is denoted by a symbol "67".

The orbiting scroll 32 of the orbiting scroll 22 also has a spiral shape from a winding start portion 32A at the innermost circumference to a winding end portion 32B at the outermost circumference as shown in fig. 3. Further, a plurality of (six in the embodiment) step portions 71 to 76 are formed between the winding end portion 32B and the winding start portion 32A at the leading end portion of the hoop 32, and the height of the hoop 32 is reduced stepwise from the winding end portion 32B to the winding start portion 32A.

In the embodiment, the outermost step portion is denoted by a symbol "71", the inner step portion thereof is denoted by a symbol "72", the further inner step portion thereof is denoted by a symbol "73", the further inner step portion thereof is denoted by a symbol "74", the further inner step portion thereof is denoted by a symbol "75", and the innermost step portion thereof is denoted by a symbol "76". The outermost and height-increasing tip end portion of the stepped portions 71 to 76 is denoted by the symbol "81", the inner tip end portion thereof is denoted by the symbol "82", the further inner tip end portion thereof is denoted by the symbol "83", the further inner tip end portion thereof is denoted by the symbol "84", the further inner tip end portion thereof is denoted by the symbol "85", the further inner tip end portion thereof is denoted by the symbol "86", and the innermost tip end portion thereof is denoted by the symbol "87".

Here, as described above, the innermost peripheries (central portions) of the scrolls of the surrounds 24 and 31 deform in a convex shape under the influence of the compression reaction force or thermal expansion from the compression chamber 34 in the fixed scroll 21 and the movable scroll 22, and therefore, local collision occurs, and the volumetric efficiency is lowered. Further, the operation for a certain period of time improves the volumetric efficiency over time and saturates at a certain period of time (habitual time), but this is because the portion that is locally collided is cut into an allowable shape, that is, a running-in due to the wear over time. Therefore, if the operation under high load is performed in a state where the wear does not occur before the above-described conventional time elapses, the surface pressure at the locally colliding portion increases, and there is a risk that the scrolls 21 and 22 are damaged.

On the other hand, as a result of actually measuring the shapes of the scrolls 21 and 22 after the elapse of the conventional time, that is, the shapes of the scrolls 21 and 22 after the running-in, the cross section of the wraparound 24 and 31 is cut into a shape recessed in an arc shape from the winding end portions 24B and 32B on the outermost periphery to the winding start portions 24A and 32A on the innermost periphery.

Therefore, in the present invention, the positions and heights of the respective step portions 51 to 56, 71 to 76 of the orbiting scroll 24, 32 of the fixed scroll 21 and the orbiting scroll 22 are set so that, when the respective orbiting scroll 24, 32 is expanded on a predetermined plane, the base points of the respective step portions 51 to 56, 71 to 76 are placed on a predetermined arc drawn on the plane.

The above-described case will be described with reference to fig. 4 and 5. In fig. 4 and 5, the surrounding member 24 of the fixed scroll 21 is described as an example, but the basic features of the surrounding member 32 of the orbiting scroll 22 are also the same. Fig. 4 is a plan view of the orbiting member 24 of the fixed scroll 21, and fig. 5 is a diagram showing the positions and heights of the stepped portions 51 to 56 at the tip of the orbiting member 24 when it is expanded. In fig. 4, the height of each of the stepped portions 51 to 56 is exaggerated, but actually, it is on the order of μm.

In fig. 5, the horizontal axis represents the length of the surround 24 with reference to the winding start portion 24A on the innermost circumference as (0), and the vertical axis represents the height of each of the tip portions 62 to 67 with reference to the tip portion 61 (on the winding end portion 24B side) on the outermost circumference as (0). In the present invention, as shown in fig. 5, base points 51A to 56A of the respective step portions 51 to 56 are set so as to be placed on a predetermined arc R drawn on a plane after the hoop 24 is developed. The arc R is set to a concave arc or an arc close to the concave arc of each scroll 21, 22 actually measured after the running-in.

In addition, the heights of the different layers 51-56 are the same in the embodiment. As described above, the base points of the respective step portions 71 to 76 of the orbiting scroll 32 of the orbiting scroll 22 are also set to be placed on a predetermined arc drawn on a plane where the orbiting scroll 32 is expanded. In the embodiment, as shown in fig. 2, the respective stepped portions 51 to 56 of the orbiting member 24 of the fixed scroll 21 are formed in an arc shape (radial circle shape) concentric with the base circle of the scroll of the orbiting member 24, and as shown in fig. 3, the respective stepped portions 71 to 76 of the orbiting member 32 of the movable scroll 22 are formed in an arc shape (radial circle shape) concentric with the base circle of the scroll of the orbiting member 32.

With the above configuration, the heights of the surrounds 24 and 32 of the scrolls 21 and 22 can be set in a state of being worn by local collision due to the influence of the compression reaction force or thermal expansion, that is, in a state in which the fitted scrolls 21 and 22 are close to the actual shape, and the surrounds 24 and 32 uniformly collide with the mirror plates 31 and 23 of the opposing scrolls 22 and 21 from the start of operation, so that occurrence of local collision can be effectively suppressed, and the so-called habitual time until the volume efficiency is saturated can be significantly shortened.

In particular, in the embodiment, since the respective stepped portions 51 to 56, 71 to 76 are formed in the arc shape concentric with the base circle of the scroll of the respective surrounds 24, 32, the height of the surrounds 24, 32 of the respective scrolls 21, 22 can be more accurately matched with the actual wear shape of the respective scrolls 21, 22, and the occurrence of local collision can be more effectively suppressed.

Here, fig. 6 is a graph (vertical axis) in which the wear height of the tip of the wraparound member 24, 32 of each scroll 21, 22 is actually measured when the total difference between the differential portions 51 to 56 of the fixed scroll 21 (difference in height between the tip portion 61 of the winding end portion 24B and the tip portion 67 of the winding start portion 24A) and the total difference between the differential portions 71 to 76 of the movable scroll 22 (difference in height between the tip portion 81 of the winding end portion 32B and the tip portion 87 of the winding start portion 32A) are changed (horizontal axis). As is clear from the above figure, in fig. 6, the wear of the tips of the surrounds 24 and 32 is the smallest among the values (difference in total of the step portions) indicated by OPTdep.

In the embodiment, as shown by X1 in fig. 2, the outermost step portion 51 of the fixed scroll 21 is located inward at 270 ° from the winding end portion 24B, and as shown by X2 in fig. 3, the outermost step portion 71 of the movable scroll 22 is also located inward at 270 ° from the winding end portion 32B. In the embodiment, since the stepped portions 51 and 71 have the arc shapes as described above, the 270 ° position is the center of the arc of each stepped portion 51 and 72.

By setting the positions of the stepped portions 51 and 71 in this way, the stability when the scrolls 21 and 22 are placed on the table so as to place the wraps 24 and 32 downward is improved, and the reference for setting the heights of the wraps 24 and 32 is also easily obtained. In the present embodiment, the stepped portions 51 and 71 are positioned at 270 ° inward, but the present invention is not limited thereto, and the respective scrolls 21 and 22 are stabilized as long as they are positioned at 180 ° or more inward.

In the embodiment, as described above, the fixed scroll 21 in which the center of the base circle of the scroll of the surround 24 coincides with the center of the mirror plate 23 is used, the movable scroll 22 in which the center of the base circle of the scroll of the surround 32 coincides with the center of the mirror plate 31 is used, the respective step portions 51 to 56 of the surround 24 of the fixed scroll 21 are formed in the shape of an arc concentric with the base circle of the scroll of the surround 24, and the respective step portions 71 to 76 of the surround 32 of the movable scroll 22 are formed in the shape of an arc concentric with the base circle of the scroll of the surround 32, but the present invention is not limited thereto, and the respective step portions 51 to 56 are formed in the shape of an arc concentric circle, and the respective step portions 71 to 76 are formed in the shape of an arc concentric circle, whereby occurrence of local collision can be effectively suppressed. The reason for this is that, as described above, the cross section of each of the scrolls 21 and 22 after the passage of the conventional time is cut into an arcuate concave shape.

However, as in the embodiment, by setting the respective step portions 51 to 56 of the orbiting member 24 of the fixed scroll 21 to the arc shape concentric with the base circle of the scroll of the orbiting member 24 and setting the respective step portions 71 to 76 of the orbiting member 32 of the movable scroll 22 to the arc shape concentric with the base circle of the scroll of the orbiting member 32, local collision can be more effectively suppressed.

Further, unlike the embodiment, there is also a case where the center of the base circle of the wrap of the fixed scroll and the orbiting scroll is different from the center of the mirror plate. In this case, the respective level differences 51 to 56 may be formed in an arc shape concentric with one of the base circle of the scroll of the surround 24 and the mirror plate 23, and the respective level differences 71 to 76 may be formed in an arc shape concentric with one of the base circle of the scroll of the surround 32 and the mirror plate 31. That is, the center of the arc of each of the stepped portions 51 to 56, 71 to 76 is aligned with either the center of the base circle of the spiral of the surrounds 24 and 32 or the center of the mirror plates 23 and 31, thereby more effectively suppressing the occurrence of the local collision.

In the embodiments, the present invention is applied to the scroll compressor used in the refrigerant circuit of the vehicle air conditioner, but the present invention is not limited to this, and is also effective in the scroll compressor used in the refrigerant circuit of various refrigeration apparatuses. In the embodiment, the present invention is applied to a so-called inverter-integrated scroll compressor, but the present invention is not limited to this, and may be applied to a general scroll compressor which does not integrally include an inverter.

(symbol description)

1a scroll compressor;

4, a compression mechanism;

11 a housing;

21 fixed scroll pan;

22 an orbiting scroll;

23. 31 a mirror plate;

24. 32a surround;

24A, 32A winding start portion;

24B, 32B winding end portions;

34 a compression chamber;

39 a back pressure chamber;

51-56, 71-76 level difference parts;

61 to 67, 81 to 87.