KR20250021821A - Scroll compressor - Google Patents

Abstract

The present invention relates to a scroll compressor, comprising: a rotating scroll that receives power and rotates; a fixed scroll that is engaged with the rotating scroll to form a compression chamber; a rear housing having a discharge chamber that receives refrigerant discharged from the compression chamber; a discharge valve that communicates and shields the compression chamber and the discharge chamber; and a support member that supports the discharge valve; wherein the support member is formed of an elastic material and is supported by the rear housing and the fixed scroll, thereby fixing the discharge valve while suppressing weight increase, cost increase, and deformation of the fixed scroll.

Description

SCROLL COMPRESSOR

The present invention relates to a scroll compressor, and more particularly, to a scroll compressor capable of compressing a refrigerant using a fixed scroll and an orbiting scroll.

In general, an air conditioning (A/C) device is installed in a car for cooling and heating the interior. The air conditioning device is a component of the cooling system and includes a compressor that compresses low-temperature, low-pressure gaseous refrigerant introduced from an evaporator into high-temperature, high-pressure gaseous refrigerant and sends it to a condenser.

The above compressors include a reciprocating type that compresses the refrigerant through the reciprocating motion of the piston, and a rotary type that compresses while rotating. The reciprocating type includes a crank type that transmits power to multiple pistons using a crank, and a swash plate type that transmits power using a rotating shaft with a swash plate installed, depending on the power transmission method. The rotary type includes a vane rotary type that uses a rotating rotary shaft and vanes, and a scroll type that uses an orbiting scroll and a fixed scroll.

Scroll compressors are widely used for refrigerant compression in air conditioning systems because they can achieve a relatively high compression ratio compared to other types of compressors, while the suction, compression, and discharge cycles of the refrigerant are smoothly connected to obtain stable torque.

Figure 1 is a cross-sectional view illustrating a conventional scroll compressor.

Referring to FIG. 1, a conventional scroll compressor includes a motor (20) that generates power, a rotating scroll (50) that receives power from the motor (20) and rotates, and a fixed scroll (60) that is engaged with the rotating scroll (50) to form a compression chamber.

Here, the fixed scroll (60) includes a discharge port (63) for discharging the refrigerant of the compression chamber, and a discharge valve (70) for opening and closing the discharge port (63) is fixed to the fixed scroll (60) by a fastening bolt (80).

In a conventional scroll compressor according to this configuration, when power is supplied to the motor (20), the rotating scroll (50) receives power generated from the motor (20) and rotates, and the compression chamber continuously moves toward the center while reducing its volume. Then, the refrigerant flows into the compression chamber and is compressed while moving toward the center along the movement path of the compression chamber. Then, the compressed refrigerant is discharged through the discharge port (63) and flows to the outside.

However, in these conventional scroll compressors, since the discharge valve (70) is fixed to the fixed scroll (60) by the fastening bolt (80), there is a problem that the weight and cost increase, and the fixed scroll (60) becomes deformed. That is, the fixed scroll (60) must include a fastening hole (64) for screw-connection with the fastening bolt (80), and in order to secure sufficient fastening strength between the fastening bolt (80) and the fastening hole (64), the fastening hole (64) must be formed deeper than the fixed plate (61) of the fixed scroll (60), and therefore, one side of the fixed wrap (62) of the fixed scroll (60) must be formed thick enough to allow the fastening hole (64) to be formed. As the thickness of the fixed wrap (62) increases in this way, the weight and material cost of the fixed scroll (60) increase. In addition, considerable manufacturing cost is required to form the above-mentioned fastening bolt (80) and the above-mentioned fastening hole (64). In particular, the processing time and manufacturing cost increase due to the screw processing. Meanwhile, the above-mentioned screw processing causes deformation in the above-mentioned fixed scroll (60), and the above-mentioned fixed scroll (60) is deformed due to the stress generated when the above-mentioned fastening bolt (80) is screwed into the above-mentioned fastening hole (64).

Republic of Korea Patent Publication No. 10-2022-0017765

Accordingly, the present invention aims to provide a scroll compressor capable of fixing a discharge valve while suppressing weight increase, cost increase, and deformation of a fixed scroll.

The present invention, in order to achieve the above-mentioned object, provides a scroll compressor including: a rotating scroll that receives power and rotates; a fixed scroll that is engaged with the rotating scroll to form a compression chamber; a rear housing having a discharge chamber that receives refrigerant discharged from the compression chamber; a discharge valve that communicates and shields the compression chamber and the discharge chamber; and a support member that supports the discharge valve; wherein the support member is formed of an elastic material and is supported by the rear housing and the fixed scroll.

The above support member may include a first portion supporting the discharge valve and a second portion supported by the fixed scroll and the rear housing.

The second portion may include a first pin extending toward the fixed scroll, and the fixed scroll may include a first pin groove into which the first pin is inserted.

The above fixed scroll includes a fixed plate having a first surface facing the orbiting scroll and a second surface forming a back surface of the first surface, and the first pin groove is engravedly formed on the second surface, and a depth of the first pin groove, which is a distance from the second surface to a base surface of the first pin groove, may be formed smaller than a thickness of the fixed plate, which is a distance between the first surface and the second surface.

The first pin includes a proximal portion adjacent to the first portion and a distal portion positioned on an opposite side of the first portion with respect to the proximal portion, and the first pin groove includes an inlet portion for receiving the proximal portion and a base portion for receiving the distal portion, and an outer diameter of the proximal portion may be formed smaller than an outer diameter of the distal portion, an inner diameter of the inlet portion may be formed at a level equivalent to the outer diameter of the proximal portion, and an inner diameter of the base portion may be formed at a level equivalent to the outer diameter of the distal portion.

The above first pin may further include an engraved groove on the distal end surface of the above distal portion, and the first pin groove may further include a protrusion inserted into the groove.

The above support member may further include a first flange portion protruding radially outwardly of the support member between the first portion and the first pin.

The above discharge valve includes a leg portion supported on the first portion, and the first flange portion can be interposed between the leg portion and the fixed scroll.

The above discharge valve may further include a head portion facing the discharge port of the fixed scroll and a body portion extending from the leg portion to the head portion, and the support member may further include a buffer portion extending from the first flange portion toward the body portion and interposed between at least a portion of the body portion and the fixed scroll.

The above fixed scroll further includes a settling groove into which the first flange portion and the buffer portion are inserted, and the settling groove is formed in a shape corresponding to the first flange portion and the buffer portion, and the depth of the settling groove can be formed at a level equivalent to the thickness of the first flange portion and the buffer portion.

The rear housing includes a post protruding toward the support member, and the second portion further includes a second pin extending toward the rear housing, the second pin being capable of being supported by contacting the post.

The above post may include a second pin groove into which the second pin is inserted.

The above support member may further include a second flange portion protruding radially outwardly of the support member between the first portion and the second pin.

The above discharge valve includes a leg portion supported on the first portion, and the second flange portion can be interposed between the leg portion and the post.

The above discharge valve may include a leg portion supported on the support member, and the leg portion may include a slit opened toward the support member so as to be detachable in a radial direction of the support member.

A scroll compressor according to the present invention comprises: a rotating scroll that receives power and rotates; a fixed scroll that is engaged with the rotating scroll to form a compression chamber; a rear housing having a discharge chamber that receives refrigerant discharged from the compression chamber; a discharge valve that communicates and shields the compression chamber and the discharge chamber; and a support member that supports the discharge valve; wherein the support member is formed of an elastic material and is supported by the rear housing and the fixed scroll, thereby fixing the discharge valve while suppressing weight increase, cost increase, and deformation of the fixed scroll.

Figure 1 is a cross-sectional view showing a conventional scroll compressor.
FIG. 2 is a cross-sectional view showing a fixed scroll, a discharge valve, a support member, and a rear housing in a scroll compressor according to one embodiment of the present invention;
Figure 3 is an enlarged view of part A of Figure 2.
Figure 4 is a perspective view showing the fixed scroll, lead and support member of Figure 2;
Figure 5 is an enlarged view of part B of Figure 4.
Figure 6 is a front view showing the support members of Figures 2 to 5;
FIG. 7 is a cross-sectional view showing a fixed scroll, a discharge valve, and a support member in a scroll compressor according to another embodiment of the present invention;
Figure 8 is an enlarged view of part C of Figure 7.
FIG. 9 is a perspective view illustrating the support members of FIGS. 7 and 8.

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

FIG. 2 is a cross-sectional view illustrating a fixed scroll, a discharge valve, a support member, and a rear housing in a scroll compressor according to one embodiment of the present invention, FIG. 3 is an enlarged view of portion A of FIG. 2, FIG. 4 is a perspective view illustrating the fixed scroll, lid, and support member of FIG. 2, FIG. 5 is an enlarged view of portion B of FIG. 4, and FIG. 6 is a front view illustrating the support members of FIGS. 2 to 5.

Meanwhile, for convenience of explanation, components not shown in FIGS. 2 to 6 refer to FIG. 1.

Referring to FIGS. 1 to 6, a scroll compressor according to one embodiment of the present invention may include a motor (20) that generates power, a rotating scroll (50) that receives power from the motor (20) and rotates, a fixed scroll (600) that is engaged with the rotating scroll (50) to form a compression chamber, a rear housing (130) that has a discharge chamber that receives refrigerant discharged from the compression chamber, a discharge valve (700) that communicates and shields the compression chamber and the discharge chamber, and a support member (800) that supports the discharge valve (700).

The above motor (20) includes a stator (21) and a rotor (22) that rotates by interaction with the stator (21), and the rotor (22) can be connected to the rotary scroll (50) through a rotation shaft (30) and an eccentric bush (40).

The above-described turning scroll (50) may include a disc-shaped turning plate (51), a turning wrap (52) protruding from the center of the turning plate (51) toward the fixed scroll (600), and a boss portion (53) protruding from the center of the turning plate (51) toward the opposite side of the turning wrap (52) and connected to the eccentric bush (40).

The above fixed scroll (600) may include a disc-shaped fixed plate (610), a fixed wrap (620) that protrudes from the fixed plate (610) toward the orbiting scroll (50) and engages with the orbiting wrap (52), a discharge port (630) that penetrates the fixed plate (610) at the center of the fixed plate (610), and a first pin groove (640) that is engraved in the fixed plate (610) at the outer periphery of the fixed plate (610).

Here, the fixed plate (610) includes a first surface (612) facing the rotating scroll (50) and a second surface (614) forming a back surface of the first surface (612), and the fixed wrap (620) can protrude from the first surface (612).

And, the discharge port (630) can be formed to penetrate the fixed plate (610) from the first surface (612) to the second surface (614).

In addition, the first pin groove (640) may be formed so as to be engraved from the second surface (614) toward the first surface (612) but not penetrate the fixed plate (610). That is, the depth of the first pin groove (640), which is the axial distance from the second surface (614) to the base surface of the first pin groove (640), may be formed to be smaller than the thickness of the fixed plate (610), which is the axial distance between the first surface (612) and the second surface (614).

In addition, the first pin groove (640) includes a cylindrical inlet portion (642) that accommodates a proximal portion (822a) to be described later and a cylindrical base portion (644) that accommodates a distal portion (822b) to be described later, and the inner diameter of the inlet portion (642) can be formed smaller than the inner diameter of the base portion (644).

In addition, the first pin groove (640) further includes a projection (646) protruding from the center of the base surface of the first pin groove (640), and the projection (646) can be inserted into a groove (822c) to be described later.

In addition, the fixed scroll (600) may further include a fixing groove (650) into which a first flange portion (832) to be described later is inserted, and the fixing groove (650) is formed in a shape corresponding to the first flange portion (832) to be described later, and the depth of the fixing groove (650) may be formed at a level equivalent to the thickness of the first flange portion (832) to be described later.

The above rear housing (130) may include a rear plate (132) facing the discharge port (630) and a rear side plate (134) protruding from the outer periphery of the rear plate (132) and fastened to the outer periphery of the fixed plate (610).

Here, the fixed plate (610), the rear plate (132) and the rear side plate (134) can form the discharge chamber.

In addition, the rear housing (130) may further include a post (136) protruding from at least one of the rear plate (132) and the rear side plate (134) and a cylindrical second pin groove (136a) engraved at a position facing the first pin groove (640) on the leading edge surface of the post (136).

The above discharge valve (700) may include a lead (710) that opens and closes the discharge port (630) and a retainer (720) that limits the opening amount of the lead (710).

The above lead (710) may include a lead leg portion (712) supported on the support member (800), a lead head portion (716) facing the discharge port (630), and a lead body portion (714) extending from the lead leg portion (712) to the lead head portion (716).

The retainer (720) may be arranged on the opposite side of the fixed plate (610) with respect to the lead (710), and may include a retainer leg portion (722) supported by the support member (800) together with the lead leg portion (712), a retainer head portion (726) facing the lead head portion (716), and a retainer body portion (724) extending from the retainer leg portion (722) to the retainer head portion (726) and facing the lead body portion (714).

Here, the lead leg part (712) and the retainer leg part (722) may be formed to be detachable in the radial direction of the support member (800). That is, the lead leg part (712) may include a lead slit (712a) that is engraved and formed from an outer surface of the lead leg part (712) so as to open toward the support member (800), and the retainer leg part (722) may include a retainer slit (722a) that is engraved and formed from an outer surface of the retainer leg part (722) so as to open toward the support member (800).

The above-described support member (800) may be formed of an elastic material such as rubber, for example, and may include a first portion (810) that supports the discharge valve (700), a second portion (820) that is supported by the fixed scroll (600) and the rear housing (130), and a third portion (830) that protrudes radially outwardly of the support member (800) between the first portion (810) and the second portion (820).

The above first portion (810) can be formed in a cylindrical shape that can be inserted into the lead slit (712a) and the retainer slit (722a).

The second portion (820) may include a first pin (822) that extends toward the fixed scroll (600) in the axial direction of the first portion (810) and is inserted into the first pin groove (640), and a second pin (824) that extends toward the rear housing (130) (more precisely, the post (136)) and is inserted into the second pin groove (136a).

The first pin (822) includes a cylindrical proximal portion (822a) adjacent to the first portion (810) and a cylindrical distal portion (822b) positioned on the opposite side of the first portion (810) with respect to the proximal portion (822a), and the outer diameter of the proximal portion (822a) is formed at the same level as the inner diameter of the inlet portion (642), and the outer diameter of the distal portion (822b) is formed at the same level as the inner diameter of the base portion (644), so that the outer diameter of the proximal portion (822a) can be formed smaller than the outer diameter of the distal portion (822b).

In addition, the first pin (822) may further include a groove (822c) engraved from the center of the tip end surface of the distal portion (822b).

The second pin (824) may be formed in a cylindrical shape having an outer diameter equivalent to the inner diameter of the second pin groove (136a) so as to correspond to the second pin groove (136a).

Here, it may be preferable that the outer diameter of the first pin (822) and the inner diameter of the first pin groove (640) be formed smaller than the outer diameter of the second pin (824) and the inner diameter of the second pin groove (136a) in terms of stable support of the support member (800) and suppression of deformation of the fixed scroll (600). That is, unlike the present embodiment, if the outer diameter of the first pin (822) is formed large, the inner diameter of the first pin groove (640) must also be formed large, and in this case, deformation of the fixed scroll (600) due to the formation of the first pin groove (640) may increase. On the other hand, if the outer diameter of the first pin (822) is formed small as in the present embodiment, the inner diameter of the first pin groove (640) may also be formed small, and accordingly, deformation of the fixed scroll (600) due to the formation of the first pin groove (640) may be reduced. At this time, if the outer diameter of the second pin (824) and the inner diameter of the second pin groove (136a) are formed larger than the outer diameter of the first pin (822) and the inner diameter of the first pin groove (640), even if the outer diameter of the first pin (822) and the inner diameter of the first pin groove (640) are formed small, the support member (800) can obtain sufficient support force.

The third portion (830) may include a first flange portion (832) protruding radially outwardly of the support member (800) between the first portion (810) and the first pin (822), and a second flange portion (834) protruding radially outwardly of the support member (800) between the first portion (810) and the second pin (824).

The above first flange portion (832) can be inserted into the fixing groove (650) and interposed between the lead leg portion (712) and the fixed plate (610).

The above second flange portion (834) can be interposed between the retainer leg portion (722) and the front end surface of the post (136).

Below, the operation and effect of the scroll compressor according to the present embodiment will be described.

That is, when power is applied to the motor (20), the rotation shaft (30) can rotate together with the rotor (22). In addition, the rotation scroll (50) can rotate by receiving power from the rotation shaft (30) through the eccentric bush (40). Accordingly, the compression chamber can continuously move toward the center while its volume is reduced. In addition, the refrigerant can be compressed while flowing into the compression chamber and moving toward the center along the movement path of the compression chamber. In addition, the refrigerant compressed in the compression chamber can be discharged to the discharge chamber through the discharge port (630) opened by the discharge valve (700) (more precisely, the lid (710)) and then flow to the outside.

Here, in the scroll compressor according to the present embodiment, since the support member (800) is formed of an elastic material such as rubber, the cost required for manufacturing the support member (800) can be reduced. In addition, when the support member (800) is fastened to the fixed scroll (600), the stress applied to the fixed scroll (600) is reduced, so that deformation of the fixed scroll (600) can be suppressed.

And, since the support member (800) is fastened to the fixed scroll (600) by the approximately cylindrical first pin (822) and the first pin groove (640), that is, since the support member (800) and the fixed scroll (600) are not screw-connected, the cost required to form the first pin (822) and the first pin groove (640) can be reduced. In particular, since there is no need to perform screw processing on the first pin groove (640), the processing time and manufacturing cost can be reduced. And, the depth of the first pin groove (640) can be made smaller than the thickness of the fixed plate (610). That is, the first pin groove (640) may not extend to the fixed wrap (620) by penetrating the fixed plate (610). Accordingly, the fixed wrap (620) does not need to be formed thick enough to form the first pin groove (640), so that the weight and cost of the fixed scroll (600) can be reduced. In addition, since screw processing is not performed on the first pin groove (640), deformation of the fixed scroll (60) due to the formation of the first pin groove (640) is suppressed, and since the support member (800) is not screw-coupled when fastened to the fixed scroll (600), deformation of the fixed scroll (600) due to stress caused by screw-coupled can be suppressed.

And, in order to suppress the support member (800) from being separated from the fixed scroll (600), the first pin (822) includes the proximal portion (822a) having a smaller outer diameter than the distal portion (822b), and the first pin groove (640) includes the inlet portion (642) having a smaller inner diameter than the base portion (644). Since the support member (800) is formed of an elastic material, the distal portion (822b) can be inserted into the base portion (644) by passing through the inlet portion (642) without damage to the first pin (822) and the fixed plate (610).

And, since the first pin (822) includes the groove (822c), the groove (822c) can absorb deformation of the distal portion (822b), so that the distal portion (822b) can be easily compressed and deformed when passing through the inlet portion (642).

And, when the distal portion (822b) is inserted into the base portion (644), the protrusion (646) inserted into the groove (822c) is provided, so that the support member (800) can be more stably supported on the fixed plate (610) by the protrusion (646).

Here, in the present embodiment, the groove (822c) is formed in the first pin (822), and the protrusion (646) is formed in the first pin groove (640), but is not limited thereto. That is, the protrusion may be formed in the first pin (822), and the groove may be formed in the first pin groove (640). In addition, the groove may be formed in one of the second pin (824) and the second pin groove (136a), and the protrusion may be formed in the other.

In addition, the support member (800) can be supported more stably as it is pressed toward the fixed plate (610) by the post (136) while being connected to the fixed plate (610).

And, as the second pin (824) and the second pin groove (136a) are provided, the support member (800) can be supported more stably.

Here, the first pin (822), the first pin groove (640), the second pin (824) and the second pin groove (136a) are not essential. That is, the second portion (820) may be supported by being compressed between the post (136) and the fixed plate (610), and in this case, although it may be somewhat disadvantageous in terms of stable support of the support member (800), it may be advantageous in terms of cost reduction and deformation suppression of the fixed scroll (600).

In addition, the second pin (824) and the second pin groove (136a) are formed in a cylindrical shape with a constant diameter, unlike the first pin (822) and the first pin groove (640). This is in consideration of the role, cost, and assembling ability of the second pin (824) and the second pin groove (136a). Specifically, the support member (800) is mainly supported on the fixed plate (610) by the first pin (822) and the first pin groove (640), and is auxiliary supported on the rear housing (130) by the second pin (824) and the second pin groove (136a). In this situation, the second pin (824) and the second pin groove (136a) may be formed similarly to the first pin (822) and the first pin groove (640), but in this case, the cost required to form the second pin (824) and the second pin groove (136a) may not be high compared to the utility, and when assembling the rear housing (130) to the fixed scroll (600) and the support member (800) that are assembled to each other, considerable effort is required to insert the second pin (824) into the second pin groove (136a), which may reduce the assembling efficiency. Therefore, considering these points, it may be preferable that the second pin (824) and the second pin groove (136a) be formed in a cylindrical shape with a constant diameter, unlike the first pin (822) and the first pin groove (640), as in the present embodiment.

And, as the first flange portion (832) interposed between the lead (710) and the fixed plate (610) is provided, the lead leg portion (712) is prevented from being directly pressed against the fixed plate (610) and damaged, and the impact noise between the lead (710) and the fixed plate (610) can be reduced.

And, as the first flange portion (832) is formed to be inserted into the fixing groove (650), and the fixing groove (650) is formed in a shape corresponding to the first flange portion (832), the support member (800) can be mounted on the fixed plate (610) at a predetermined position.

And, since the depth of the fixing groove (650) is formed at a level equivalent to the thickness of the first flange portion (832), the lead (710) can be prevented from being excessively attached to or lifted from the fixed plate (610). That is, if the depth of the fixing groove (650) is greater than the thickness of the first flange portion (832), the first flange portion (832) is deeply inserted into the fixing groove (650), so that the lead leg portion (712) is biased inwardly of the fixing groove (650) based on the second surface (614) of the fixed plate (610), and the lead body portion (714) can be excessively pressed against the fixed plate (610). On the other hand, if the depth of the fixing groove (650) is smaller than the thickness of the first flange portion (832), a part of the first flange portion (832) may protrude outside the fixing groove (650), so that the lead (710) may be entirely separated from the second surface (614) of the fixed plate (610). In such cases, it may be difficult for the lead (710) to function properly. Therefore, in order for the lead (710) to function properly, it may be preferable that the depth of the fixing groove (650) be formed at a level equivalent to the thickness of the first flange portion (832), as in the present embodiment.

And, since the second flange portion (834) interposed between the post (136) portion and the retainer (720) is provided, the retainer (720) can be prevented from being directly pressed against the post (136) and damaged, while deformation toward the opposite side of the lead (710) can be suppressed.

And, since the lead leg part (712) and the retainer leg part (722) are formed to be detachable in the radial direction of the support member (800) (more precisely, the first portion (810)) including the lead slit (712a) and the retainer slit (722a), respectively, the lead (710) and the retainer (720) can be easily assembled and disassembled to the support member (800).

Meanwhile, in the case of the present embodiment, the impact sound between the lead (710) and the fixed plate (610) is reduced by the first flange portion (832), but as shown in FIGS. 7 to 9, in order to further reduce the impact sound between the lead (710) and the fixed plate (610), the support member (800) may further include a buffer portion (836) that extends from the first flange portion (832) toward the lead body portion (714) and is interposed between at least a portion of the lead body portion (714) and the fixed plate (610). In this case, since the lead (710) hits the fixed plate (610) together with the buffer portion (836) when closing the discharge port (630), the impact can be reduced.

Here, the fixing groove (650) of the fixed plate (610) is formed to accommodate not only the first flange portion (832) but also the buffer portion (836). When the fixing groove (650) is formed in a shape corresponding to the first flange portion (832) and the buffer portion (836), it can be easier to mount the support member (800) to the fixed plate (610) at a predetermined position. In addition, in order to prevent the lead (710) from being excessively attached to or lifted off the fixed plate (610), it may be preferable that the depth of the fixing groove (650) be formed at a level equivalent to the thickness of the first flange portion (832) and the buffer portion (836).

20: Motor
50: Rotating Scroll
130: Rear Housing
136: Post
136a: 2nd pin home
600: Fixed scroll
610: Fixed plate
612: Page 1
614: Page 2
630: outlet
640: 1st pin home
642: Entrance
644: Base
646: protrusion
650: Settlement Home
700: Discharge valve
710: Lead
712: Lead leg
712a: Lead slit
714: Lead Body
716: Lead Head
720: Retainer
722: Retainer leg
722a: Retainer slit
724: Retainer body part
726: Retainer head
800: Absence of support
810: Section 1
820: Part 2
822: 1st pin
822a: Guards
822b: Distal
822c: Home
824: 2nd pin
832: Flange 1
834: Second flange section
836: Buffer

Claims (15)

A rotary scroll that rotates when powered;
A fixed scroll which is engaged with the above-mentioned rotating scroll to form a compression chamber;
A rear housing having a discharge chamber for receiving refrigerant discharged from the compression chamber;
A discharge valve that connects and shields the compression chamber and the discharge chamber; and
including a support member supporting the discharge valve;
A scroll compressor, characterized in that the support member is formed of an elastic material and is supported by the rear housing and the fixed scroll. In the first paragraph,
A scroll compressor, wherein the support member comprises a first portion supporting the discharge valve and a second portion supported by the fixed scroll and the rear housing. In the second paragraph,
A scroll compressor, wherein the second portion includes a first pin extending toward the fixed scroll, and the fixed scroll includes a first pin groove into which the first pin is inserted. In the third paragraph,
A scroll compressor in which the fixed scroll includes a fixed plate having a first surface facing the orbiting scroll and a second surface forming a back surface of the first surface, and the first pin groove is engravedly formed on the second surface, and a depth of the first pin groove, which is a distance from the second surface to a base surface of the first pin groove, is formed smaller than a thickness of the fixed plate, which is a distance between the first surface and the second surface. In the third paragraph,
A scroll compressor according to claim 1, wherein the first pin includes a proximal portion adjacent to the first portion and a distal portion positioned on an opposite side of the first portion with respect to the proximal portion, the first pin groove includes an inlet portion receiving the proximal portion and a base portion receiving the distal portion, and an outer diameter of the proximal portion is formed smaller than an outer diameter of the distal portion, an inner diameter of the inlet portion is formed at a level equivalent to the outer diameter of the proximal portion, and an inner diameter of the base portion is formed at a level equivalent to the outer diameter of the distal portion. In paragraph 5,
A scroll compressor wherein the first pin further includes an engraved groove on a front end surface of the distal portion, and the first pin groove further includes a projection inserted into the groove. In the third paragraph,
A scroll compressor wherein the support member further includes a first flange portion protruding radially outwardly of the support member between the first portion and the first pin. In Article 7,
A scroll compressor wherein the discharge valve includes a leg portion supported on the first portion, and the first flange portion is interposed between the leg portion and the fixed scroll. In Article 8,
A scroll compressor in which the discharge valve further includes a head portion facing the discharge port of the fixed scroll and a body portion extending from the leg portion to the head portion, and the support member further includes a buffer portion extending from the first flange portion toward the body portion and intervening between at least a portion of the body portion and the fixed scroll. In Article 9,
A scroll compressor in which the fixed scroll further includes a settling groove into which the first flange portion and the buffer portion are inserted, the settling groove is formed in a shape corresponding to the first flange portion and the buffer portion, and the depth of the settling groove is formed at a level equivalent to the thickness of the first flange portion and the buffer portion. In the third paragraph,
The above rear housing includes a post protruding toward the support member,
The second portion further includes a second pin extending toward the rear housing,
The second pin is a scroll compressor supported by contacting the post. In Article 11,
A scroll compressor, wherein the post includes a second pin groove into which the second pin is inserted. In Article 11,
A scroll compressor wherein the support member further includes a second flange portion protruding radially outwardly of the support member between the first portion and the second pin. In Article 13,
A scroll compressor wherein the discharge valve comprises a leg portion supported on the first portion, and the second flange portion is interposed between the leg portion and the post. In the first paragraph,
A scroll compressor wherein the discharge valve comprises a leg portion supported on the support member, the leg portion comprising a slit opened toward the support member so as to be detachable in a radial direction of the support member.