KR101452487B1 - Compressor - Google Patents

Abstract

The present invention relates to a compressor. According to the present invention, a part of the outer surface of the compressor 120 is formed by the cylinder block 121 having the cylinder bore 121 'therein. A rear housing 125 having suction and discharge chambers 125a and 125b is coupled to one side of the cylinder block 121. A valve unit 130 is provided between the cylinder block 121 and the rear housing 125. The valve unit 130 includes a valve plate 131, a suction reed valve 135, and a discharge reed valve 139. The valve plate 131 is formed with suction holes and discharge holes 131a and 131b so that the suction holes 131a and the discharge holes 131b are provided with stepped suction and discharge steps 131a 'and 131b' Respectively. The suction reed 137 of the suction reed valve 135 is spaced apart from the valve plate 131 at its tip.

According to the present invention having such a configuration, the force applied to the suction and discharge reed valves 135 and 139 is increased by the suction and discharge steps 131a 'and 131b', and the suction reed 137 The area of the mucous membrane formed between the suction reed 137 and the valve plate 131 is reduced so that the opening and closing operations of the suction and discharge reed valves 135 and 139 are performed more smoothly .

Compressor, cylinder bore, valve unit, suction chamber, discharge chamber

Description

Compressor

The present invention relates to a compressor, and more particularly, to a compressor having a valve unit for selectively communicating a cylinder bore with an inlet and an outlet.

Generally, a compressor used in an automotive air conditioning system sucks refrigerant evaporated from an evaporator and transfers it to a condenser in a state of high temperature and high pressure which is easy to be liquefied.

FIG. 1 is a cross-sectional view of a portion of a conventional compressor, and FIG. 2 is an exploded perspective view of a conventional valve unit.

A part of the skeleton of the compressor (20) is formed by the cylinder block (21). A plurality of cylinder bores 21 'are formed in the cylinder block 21. A piston 23 is connected to a driving shaft (not shown) which is rotated by the driving force of the engine in the cylinder bore 21' Respectively. The piston 23 is reciprocated in the cylinder bore 21 'by the rotation of the drive shaft to compress the refrigerant.

A rear housing 25 having a suction chamber 25a and a discharge chamber 25b is coupled to one end of the cylinder block 21. The suction chamber 25a is a space in which the refrigerant introduced into the compressor 20 is stored and the discharge chamber 25b is a space in which the refrigerant compressed in the cylinder bore 21 'is temporarily stored.

A valve unit (30) is provided between the cylinder block (21) and the rear housing (25). The valve unit 30 selectively communicates the cylinder bore 21 'with the suction chamber 25a and the discharge chamber 25b. The skeleton of the valve unit (30) is formed by a valve plate (31). The valve plate 31 is formed in a disk shape, and a plurality of suction holes 31a are formed to penetrate through the valve plate 31. [ The suction hole 31a communicates the suction chamber 25a and the cylinder bore 21 '.

A discharge hole 31b is formed in one side of the suction hole 31a. The discharge hole 31b serves to communicate the cylinder bore 21 'and the discharge chamber 25b.

The valve plate 31 is formed with an engagement hole 31c. The coupling hole 31c is a portion through which a fastening bolt (not shown) for coupling the components constituting the external appearance of the compressor 20 passes.

The valve plate 31 is formed with a fixing boss 31d protruding on both sides. The fixed boss 31d is a portion to which a discharge reed valve 33 and a suction reed valve 35 to be described later are fixed.

As shown in FIG. 2, a discharge reed valve 33 is installed on one side of the valve plate 31. The discharge reed valve 33 opens and closes the discharge hole 31b of the valve plate 31 to selectively communicate the cylinder bore 21 'and the discharge chamber 25b.

The valve plate 31 is provided with a discharge lead 33 '. The discharging lead 33 'is formed in a plate shape having a predetermined length and is elastically deformable due to the characteristics of materials and shapes. The discharge lead 33 'serves to open and close the discharge hole 31b of the valve plate 31. When the refrigerant is compressed by the piston 23 and the pressure in the cylinder bore 21 'becomes higher than the pressure inside the discharge chamber 25b, the discharge lead 33' is elastically deformed, And the compressed refrigerant flows into the discharge chamber 25b through the discharge hole 31b.

A fixing portion 33 "for inserting the fixing boss 31d of the valve plate 31 is formed at the edge of the discharge reed valve 33 so as to be protruded.

A suction reed valve 35 is provided on the opposite surface of the valve plate 31 on which the discharge reed valve 33 is provided. The suction reed valve 35 selectively opens and closes the suction hole 31a of the valve plate 31 to selectively communicate the cylinder bore 21 'and the suction chamber 25a. The suction reed valve 35 is formed with a through hole 35 'through which the fixing boss 31d is inserted.

The suction reed valve (35) is formed with a suction reed (37). The suction reed 37 is formed by cutting off a part of the suction reed valve 35 which is in close contact with the periphery of the suction hole 31a. The suction lid 37 is elastically deformable due to the nature of its material and shape. When the pressure in the cylinder bore 21 'becomes lower than the pressure in the suction chamber 25a, the suction reed 37 is elastically deformed to open the suction hole 31a and open the suction hole 31a through the suction hole 31a The refrigerant in the suction chamber 25a flows into the cylinder bore 21 '.

The suction reed 37 is formed with a through hole 37 '. The through-hole 37 'is formed to prevent the suction reed 37 from blocking the discharge hole 31b of the valve plate 31.

A restriction portion 21 '' is formed at one end of the cylinder block 21 in contact with the surface of the valve plate 31 on which the suction reed valve 35 is provided. The restriction portion 21 ' Of the suction reed 37 is elastically deformed to open the suction hole 31a so as to restrict the suction reed 37 from being excessively resiliently deformed to a portion where the suction reed 37 is tipped.

However, the compressor according to the prior art having such a configuration has the following problems.

The suction and discharge leads 37 and 33 'are operated by a pressure difference between the suction chamber and the discharge chambers 25a and 25b and the cylinder bores 21'. In order to increase the efficiency of the compressor 20, the suction and discharge leads 37 and 33 'must be smoothly moved.

Lubricant is stored in the compressor (20) to reduce friction between the components in the operation of the compressor (20). A mucous membrane is formed between the valve plate 31 and the suction and discharge leads 37 and 33 'by the lubricating oil.

The pressure difference between the cylinder bore 21 'and the inside of the suction and discharge chambers 25a and 25b necessary for elastically deforming the suction and discharge leads 37 and 33' is increased by the mucous membrane, The time for opening the discharge holes 31a and 31b is shortened and the amount of the refrigerant flowing into and out of the cylinder bore 21 'is reduced to lower the efficiency of the compressor 20. [

When the suction reed 37 is elastically deformed to open the suction hole 31a, the tip of the suction reed 37 comes into contact with the restricting portion 21 ". At this time, the suction reed 37 When the tip of the compressor 20 contacts the regulating portion 21 ", there is a problem that a noise is generated during the operation of the compressor 20. [ If the distance between the regulating portion 21 'and the suction reed 37 is further narrowed to reduce the noise, the amount of elastic deformation of the suction reed 37 is reduced and the efficiency of the compressor is lowered.

SUMMARY OF THE INVENTION It is an object of the present invention to solve the problems of the prior art as described above, and it is an object of the present invention to provide a suction valve, which has a suction stepped portion for widening a transverse sectional area of a suction hole, And a discharge stepped section for widening the cross sectional area of the discharge hole is provided at a portion in contact with the discharge port.

Another object of the present invention is to provide a compressor in which a part of the suction lead is separated from the valve plate.

Another object of the present invention is to provide a compressor in which a regulating portion is formed to be inclined at a portion of the cylinder bore which is in contact with the tip of a suction reed.

According to an aspect of the present invention for achieving the above-described object, the present invention provides a refrigerant compressor comprising a plurality of cylinder bores provided therein, a piston for linearly reciprocating within the cylinder bore, And a valve unit for selectively communicating the cylinder bore with the suction chamber and the discharge chamber, wherein the valve unit comprises: a valve plate having a suction hole through which the refrigerant flows and a discharge hole through which the refrigerant is discharged; A suction reed valve coupled to one surface of the valve plate and having a suction reed for selectively opening and closing the suction hole; And a discharge reed valve coupled to an opposite surface of the valve plate on which the suction reed valve is provided and having an ejection lead for selectively opening and closing the ejection hole, Closing auxiliary structure for smoothly opening and closing the suction and discharge reed valve.

The opening and closing auxiliary structure is formed such that a step is formed on at least one of the one side of the discharge hole on the side where the suction reed valve of the valve plate and the one side of the suction hole come in contact with the suction reed valve of the valve plate .

The opening / closing auxiliary structure is formed in the valve plate so that a portion of the valve plate, which is located in the suction chamber, is bent so that a circumferential portion of the valve plate is stepped with respect to a central portion thereof, so that the tip of the suction lead is separated from the valve plate.

(T) of the valve plate is 0.03 mm or more and 0.4 mm or less.

The restricting portion to be supported when the suction reed is elastically deformed is formed on a surface of the cylinder bore which is in contact with the valve plate so as to be inclined.

The inclination angle [theta] of the restricting portion is formed between 0 [deg.] And 45 [deg.].

According to the present invention, the suction step and the discharge step are respectively formed in the suction and discharge holes in the valve plate. Since the suction stepped portion and the discharge stepped portion increase the pressure action area of the suction and discharge leads, the pressure applied to the suction and discharge leads increases, and the force applied to the suction and discharge leads increases, The amount of refrigerant flowing into and out of the cylinder bore increases, thereby improving the efficiency of the compressor.

In addition, since the regulating portion is inclined at one end of the cylinder bore contacting the suction reed, when the suction reed is elastically deformed to come into contact with the regulating portion, the sound is reduced and the amount of elastic deformation of the suction reed is increased, The noise generated during operation is reduced, and the efficiency of the compressor is also improved.

Further, since the leading end of the suction reed is spaced apart from the valve plate by a predetermined distance, the area of the mucous membrane formed by the lubricating oil between the suction reed and the valve plate is reduced, and the opening and closing operation is smooth even under the same suction reed.

Hereinafter, preferred embodiments of the compressor according to the present invention will be described in detail with reference to the drawings.

3 is a sectional view of a compressor according to a preferred embodiment of the present invention. FIGS. 4 and 5 show the construction of a valve unit constituting a preferred embodiment of the compressor according to the present invention, A perspective view is shown.

According to these drawings, a part of the skeleton of the compressor 120 is formed by the cylinder block 121. A cylinder bore 121 'is formed in the cylinder block 121. The cylinder bore 121 'is formed in a circular shape in its transverse section, and the piston 123 is installed so as to reciprocate linearly within the cylinder bore 121'. The piston 123 is cylindrical in shape corresponding to the cross section of the cylinder bore 121 '. The piston 123 linearly reciprocates within the cylinder bore 121 'to compress the refrigerant in the cylinder bore 121'.

A restriction portion 121 "is formed at a portion of the cylinder block 121 where a distal end of the suction lead 137 is to be described later. When the suction lead 137 is elastically deformed, The tip of the suction reed 137 serves to prevent the suction reed 137 from being excessively resiliently deformed.

It is preferable that the restricting portion 121 "is inclined at a predetermined angle with respect to the restricting portion 121" at a portion where the suction reed 137 is in contact with the restricting portion 121 " The distance between the portion where the distal end of the suction reed 137 contacts the restricting portion 121 "and the surface facing the restricting portion 121" from the suction reed 137 is defined as a distance The speed at which the suction reed 137 is elastically deformed due to a certain force to come into contact with the restricting portion 121 "becomes small, and when the suction reed 137 abuts against the restricting portion 121" , The amount of the generated impulse is reduced, and the size of the noise generated when the suction reed 137 is in contact with the restricting portion 121 "is also reduced.

Further, since the restricting portion 121 '' is inclined, the tip of the suction reed 137 moves along the restricting portion 121 'to be further elastically deformed, so that the inside of the cylinder bore 121' The efficiency of the compressor 120 is improved.

The inclination angle? Of the regulating portion 121 "is set to be between 0 ° and 45 ° when the inclination angle? Of the regulating portion 121" And the distal end of the suction reed 137 may become too close so that the suction reed 137 may not operate properly and the frictional force between the tip of the suction reed 137 and the rest portion 121 & A phenomenon that the suction reed 137 is not restored to its original shape after the elastic deformation of the suction reed 137 may occur.

A rear housing 125 is coupled to one side of the cylinder block 121. The rear housing 125 forms a rear outer appearance of the compressor 120 and shields one side of the cylinder block 121.

A suction chamber 125a is formed on a surface of the rear housing 125 facing the cylinder block 121. [ The suction chamber 125a is a space in which the refrigerant introduced into the compressor 120 is temporarily stored. The suction chamber 125a is selectively communicated with the cylinder bore 121 'by a valve unit 130 to be described later.

A discharge chamber 125b is formed in the rear housing 125 at one side of the suction chamber 125a. The discharge chamber 125b is a space in which the refrigerant compressed in the cylinder bore 121 'is discharged and temporarily stored. The discharge chamber 125b is selectively communicated with the cylinder bore 121 'by the valve unit 130 in the same manner as the suction chamber 125a.

A valve unit 130 is provided between the cylinder block 121 and the rear housing 125. The valve unit 130 selectively communicates the cylinder bore 121 'with the suction chamber 125a and the discharge chamber 125b.

The skeleton of the valve unit 130 is formed by a valve plate 131. The valve plate 131 is formed in a disc shape having a predetermined thickness.

A plurality of suction holes 131a are formed in the valve plate 131. The suction hole 131a serves as a passage for communicating the cylinder bore 121 'and the suction chamber 125a. The suction hole 131a is selectively opened and closed by a suction reed valve 135 to selectively communicate the cylinder bore 121 'and the suction chamber 125a.

As shown in FIG. 4, a suction step 131a 'is formed at the edge of the suction hole 131a. More specifically, the suction stepped portion 131a 'is a portion formed on the valve plate 131 on the side where the suction reed valve 135 is installed, at a predetermined edge of the suction hole 131a, The cross sectional area of a part of the suction hole 131a is widened by the suction stepped portion 131a 'so that the pressure applied to the suction lead 137 to be described later becomes large, The force is increased.

A plurality of discharge holes 131b are formed in the valve plate 131. The discharge hole 131b serves as a passage for communicating the cylinder bore 121 'and the discharge chamber 125b. The discharge hole 131b is selectively opened and closed by a discharge reed valve 139 to be described later to selectively communicate the cylinder bore 121 'and the discharge chamber 125b.

As shown in FIG. 5, a discharge step 131b 'is formed at an edge of the discharge hole 131b. More specifically, the discharge stepped portion 131b 'is a portion formed in the valve plate 131 on the surface on which the discharge reed valve 139 is installed, at a predetermined distance from the edge of the discharge hole 131b, The cross sectional area of a part of the discharge hole 131b is widened by the discharge stepped portion 131b ', so that the force applied to the discharge lead 139' to be described later becomes large even under the same pressure so that the discharge lead 139 ' And is elastically deformed.

A coupling hole 131c is formed between the suction holes 131a. The coupling hole 131c is a portion through which a fastening bolt (not shown) joining parts forming the outer appearance of the compressor 120 passes.

And a fixing boss 131d is provided at a central portion of the valve plate 131. [ The fixing bosses 131d are formed in a rod shape having a predetermined length and are provided at positions corresponding to both surfaces of the valve plate 131, respectively. The fixed boss 131d serves to fix the suction and discharge reed valves 135 and 139. [

A suction reed valve 135 is provided on a surface of the valve plate 131 on which the suction step 131a 'is formed. The suction reed valve 135 is formed in a disk shape having a predetermined thickness. The suction reed valve 135 selectively opens and closes the suction hole 131a to selectively communicate the cylinder bore 121 'and the suction chamber 125a.

A boss hole 135 'is formed in the intake reed valve 135 at a position corresponding to the fixed boss 131d of the valve plate 131. The fixing boss 131d passes through the boss hole 135 'and the suction reed valve 135 is fixed to the valve plate 131. [

A part of the suction reed valve 135 is cut off to form a suction reed 137. The suction reed 137 has a cantilever shape in which one end is connected to the suction reed valve 135 and the other part is cut out, and is elastically deformable due to the nature of the material and shape. The suction reed 137 is elastically deformed by a pressure difference between the cylinder block 121 and the suction chamber 125a to selectively open and close the suction hole 131a.

As shown in FIG. 3, when the valve unit 130 is installed in the compressor 120, the valve plate 131 is bent so as not to be positioned on the same straight line. That is, the central portion and the edge portion of the valve plate 131 are stepped by a predetermined distance t. The valve plate 131 is bent at a portion of the rear housing 125 which is located in the suction chamber 125a so that the suction reed 137 is inserted into the valve plate 131. [ 131).

This is to reduce the area of the mucous membrane between the valve plate 131 formed by the lubricating oil stored in the compressor 120 and the suction lead 137. When the area of the mucous membrane is reduced, the suction reed 137 is easily elastically deformed to open the suction hole 131a, thereby increasing the amount of refrigerant flowing into the cylinder bore 121 '. The valve unit 130 is folded so that the stepped portion t is between 0.03 mm and 0.4 mm. The suction reed 137 may be adhered to the valve plate 131 by a lubricating oil and if the suction reed 137 is 0.4 mm or more, It is preferable that the step t is designed to be between 0.03 mm and 0.4 mm since the suction hole 131a of the valve plate 131 can not be securely blocked.

When the piston 123 linearly moves toward the bottom dead center of the cylinder bore 121 ', the pressure in the cylinder bore 121' is lower than the pressure in the suction chamber 125a. And the suction hole 131a is opened so that the cylinder bore 121 'and the suction hole 131a are communicated with each other. At this time, Is introduced into the cylinder bore 121 '.

When the piston 123 moves linearly toward the top dead center of the cylinder bore 121 ', the pressure inside the cylinder bore 121' becomes higher than the pressure of the suction chamber 125a, Is elastically deformed so as to come into contact with the valve plate 131 to shield the suction hole 131a.

A through hole 137 'is formed in the intake lead 137 at a portion corresponding to the discharge hole 131b of the valve plate 131. The through-hole 137 'is formed to prevent a part of the suction reed 137 from blocking the discharge hole 131b.

A discharge reed valve 139 is provided on a surface of the valve plate 131 on which the discharge step 131b 'is formed. The discharge reed valve 139 selectively opens and closes the discharge hole 131b of the valve plate 131 to selectively communicate the cylinder bore 121 'and the discharge chamber 125b.

Fixing portions 139 '' are formed at both ends of the discharge reed valve 139 at positions corresponding to the fixing bosses 131d of the valve plate 131. The fixing portions 139 ' The fixed boss 131d passes through the fixing portion 139 'and the discharge reed valve 139 is fixed to the valve plate 131 as a portion where the boss 131d is inserted.

The discharge reed valve 139 is provided with a discharge reed 139 '. The discharge lead 139 'has a plate shape having a predetermined length. The discharge reed 139 'is elastically deformable due to the nature of material and shape so that the discharge reed 139' is elastically deformed by the pressure difference between the cylinder bore 121 'and the discharge chamber 125b, And selectively opens and closes the discharge hole 131b of the valve plate 131.

Although not shown, the compressor 120 is provided with a drive shaft (not shown) provided to be interlocked with the piston 123. The piston 123 reciprocates linearly in the cylinder bore 121 'by the rotation of the drive shaft.

Hereinafter, the operation of the compressor according to the embodiment of the present invention will be described in detail with reference to the drawings.

6 is an operational state view showing a state in which a refrigerant is sucked and discharged from a cylinder bore of a compressor according to an embodiment of the present invention.

When the driving shaft of the compressor 120 rotates, the piston 123 connected to the driving shaft linearly reciprocates within the cylinder bore 121 '. The refrigerant is introduced into and discharged from the cylinder bore 121 'in the course of the linear reciprocating movement of the piston 123.

As the refrigerant is sucked in, the piston 123 moves in the cylinder bore 121 'in the direction (arrow A direction) toward the bottom dead center. At this time, the volume in which the refrigerant in the cylinder bore 121 'is introduced increases, so that the pressure inside the cylinder bore 121' becomes relatively lower than the pressure in the suction chamber 125a.

The suction reed 137 is elastically deformed toward the cylinder bore 121 'by the pressure of the suction chamber 125a which is relatively high. At this time, since the tip of the suction reed 137 is separated from the valve plate 131, the area of the mucous membrane formed by the lubricating oil becomes small, so that the suction reed 137 can be easily deformed by the relatively low pressure difference do.

Since the suction step 131a of the valve plate 131 is formed with a suction step 131a 'to increase the pressure acting area of the suction reed 137, the force applied to the suction reed 137 The suction reed 137 is elastically deformed easily. When the suction reed 137 is elastically deformed, the refrigerant flows through the suction hole 131a.

When the suction reed 137 is elastically deformed, the leading end of the suction reed 137 is supported by the restricting portion 121 '' of the cylinder block 121. The restricting portion 121 'is inclined at a predetermined angle The tip of the suction reed 137 is prevented from being inclined by the inclination of the regulating portion 121 " The amount of the refrigerant flowing into the cylinder bore 121 'increases.

The refrigerant in the cylinder bore 121 'is compressed when the piston 123 moves in the direction from the bottom dead center to the top dead center (arrow B direction). The suction reed 137 is elastically deformed toward the valve plate 131 so that the valve plate 131 is elastically deformed in the direction of the valve plate 131. As a result, The suction hole 131a is closed.

On the other hand, when the pressure inside the cylinder bore 121 'becomes larger than the pressure of the discharge chamber 125b, the discharge lead 139' of the discharge reed valve 139 is elastically deformed toward the suction chamber 125a. Since the ejection hole 131b 'is formed in the ejection hole 131b, the pressure acting area of the ejection reed 139' widens and the ejection reed 139 'is elastically deformed easily even with a small pressure difference. When the discharge reed 139 'is elastically deformed, the discharge hole 131b is opened and the refrigerant compressed through the discharge hole 131b is discharged to the discharge chamber 125b.

The tip of the suction reed 137 is separated from the valve plate 131 and the suction step 131a 'and the discharge step 131b' are formed in the suction hole 131a and the discharge hole 131b, The suction reed 137 and the discharge reed 139 'are easily elastically deformed even if the pressure difference between the cylinder bore 121' and the suction chamber 125a and the discharge chamber 125b is relatively small, The amount of refrigerant flowing into and out of the bore 121 'increases.

In addition, the restricting portion 121 '' is inclined so that the sound generated when the suction reed 137 and the restricting portion 121 'are in contact with each other is reduced, 121 "of the cylinder bore 121 'to be more elastically deformed, the amount of refrigerant flowing into the cylinder bore 121' increases, and the efficiency of the compressor 120 is improved.

The scope of the present invention is not limited to the embodiments described above, but may be defined by the scope of the claims, and those skilled in the art may make various modifications and alterations within the scope of the claims It is self-evident.

For example, even if only one of the suction and discharge steps 131a 'and 131b' is formed and the suction lead 137 is separated from the valve plate 131, The effect of improving the efficiency can be obtained.

Further, even if any one of the suction and discharge steps 131a 'and 131b' is formed, the efficiency of the compressor 120 can be improved.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a cross-sectional view showing a part of a compressor according to a prior art; FIG.

2 is an exploded perspective view showing the structure of a valve unit according to the prior art.

3 is a sectional view showing a part of a preferred embodiment of the compressor according to the present invention.

FIG. 4 and FIG. 5 are exploded perspective views of the valve unit constituting the preferred embodiment of the compressor according to the present invention, viewed from different directions; FIG.

6 is an operational state view showing a state in which a refrigerant is sucked and discharged from a cylinder bore of a compressor according to an embodiment of the present invention.

Description of the Related Art [0002]

120: compressor 121: cylinder block

121 ': cylinder bore 121': regulating portion

123: piston 125: rear housing

125a: suction chamber 125b: discharge chamber

130: Valve unit 131: Valve plate

131a: Suction hole 131a ': Suction step

131b: Discharge hole 131b ': Discharge step

131c: coupling ball 131d: fixed boss

135: suction reed valve 135 ': boss hole

137: Suction lead 137 ': Through hole

139: Discharge reed valve 139 ': Discharge reed

139 ": Fixed Government

Claims (6)

A piston 123 and a suction chamber 125a and a discharge chamber 125b through which the refrigerant is introduced and discharged so that the cylinder bores 121 'can linearly reciprocate within the cylinder bores 121' And a valve unit (130) for selectively communicating the cylinder bore (121 '), the compressor comprising: The valve unit (130) comprises: A valve plate 131 having a suction hole 131a through which the refrigerant flows and a discharge hole 131b through which the refrigerant is discharged; A suction reed valve 135 coupled to one surface of the valve plate 131 and having a suction reed 137 selectively opening and closing the suction hole 131a; And The discharge reed valve 139 is coupled to an opposite surface of the valve plate 131 on which the suction reed valve 135 is provided and includes a discharge reed 139 'for selectively opening and closing the discharge port 131b. ≪ / RTI > A portion of the valve plate 131 located in the suction chamber 125a is bent in the valve unit 130 so that a circumferential portion of the valve plate 131 is stepped with a center portion of the valve plate 131, Is supported on a surface of the cylinder bore 121 'that is in contact with the valve plate 131 when the suction lead 137 is elastically deformed, (121 ") is formed obliquely . The valve unit according to claim 1, wherein the valve unit is disposed on one side of the suction hole and on the discharge lead of the valve plate, Wherein stepped portions (131a ', 131b') are stepped on at least one side of the discharge hole (131b) on the side where the valve (139) contacts. delete 2. The compressor according to claim 1, wherein the step (t) of the valve plate (131) is 0.03 mm or more and 0.4 mm or less. delete 2. The compressor according to claim 1, wherein the inclination angle &thetas; of the restricting portion 121 "

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