KR20100091795A - Variable displacement swash plate type compressor - Google Patents

Abstract

PURPOSE: A capacity-variable swash plate type compressor is provided to enhance the performance of a compressor by transferring and recycling refrigerant to a cylinder bore. CONSTITUTION: A capacity-variable swash plate type compressor comprises a cylinder block(110), a front housing(120), a rear housing(130), a rotary shaft(140), a rotary valve(141), and a piston(115). The cylinder block comprises a central bore(111) and a plurality of cylinder bores(113). The center bore and the cylinder bores are communicated through a connecting line(114). A crank chamber(121) is formed in the front housing. The rotary valve is installed on one end of the rotary shaft to be rotated integrally with the rotary shaft and transfers refrigerant to the cylinder bore. A passage(143) which communicates the crank chamber and the connecting line is formed on the rotary valve so that the refrigerant of the crank chamber is transferred to the cylinder bore through the connecting line. A passage entrance(143') communicated with the crank chamber is located at the opposite side of the rotational direction of the rotary valve rather than the passage exit(143") communicated with the cylinder bore.

Description

Variable displacement swash plate type compressor

The present invention relates to a compressor, and more particularly, to a variable displacement swash plate type compressor in which a refrigerant is delivered into a cylinder bore and compressed through a rotary valve provided on a rotating shaft.

Looking briefly at the air conditioning system of the vehicle, first, the refrigerant of the high temperature low pressure gas state is brought into the high temperature high pressure gas state by the compressor. The refrigerant in the high temperature and high pressure gas state becomes a high temperature high pressure liquid state by a condensation action of the condenser via a condenser, and the refrigerant in the high temperature and high pressure liquid state becomes a low temperature low pressure liquid state by a throttling action of the expansion valve through an expansion valve. do. The refrigerant in the low temperature low pressure liquid state is returned to the high temperature low pressure gas state through heat exchange in the evaporator through the evaporator, and the high temperature low pressure gas is compressed by the compressor to become a high temperature high pressure gas state. By repeating this process, the vehicle air conditioning system is operated.

Compressors for compressing a refrigerant include a reciprocating type that actually compresses a working fluid, a reciprocating type that performs compression while reciprocating, and a rotary type that performs compression while rotating.

The reciprocating type includes a crank type for transmitting the driving force of the drive source to the plurality of pistons using a crank, a swash plate type for transmitting using a rotating shaft provided with a swash plate, and a wobble plate type using a wobble plate. Rotary type includes vane rotary type using rotary rotary shaft and vane, and scroll type using rotary scroll and fixed scroll.

1 shows a configuration of a variable displacement swash plate compressor according to the prior art. According to this, the swash plate compressor 1 is provided with a cylinder block 10. The cylinder block 10 forms part of the appearance and skeleton of the compressor 1. A center bore 11 is formed through the center of the cylinder block 10. The center bore 11 is a portion in which the rotating shaft 40 to be described below is rotatably installed.

A plurality of cylinder bores 13 are formed to radially penetrate the center bore 11 and penetrate the cylinder block 10. The communication path 14 is formed so that the cylinder bore 13 and the center bore 11 communicate with each other. The communication path 14 becomes a passage for transferring the refrigerant to the cylinder bore 13.

 The piston 15 is installed inside the cylinder bore 13 to enable a straight reciprocating motion. The piston 15 has a cylindrical shape, and the cylinder bore 13 has a cylindrical shape corresponding thereto. One end portion of the piston 15, that is, a portion 17 protruding to the outside of the cylinder bore 13 is formed with a connecting portion 17. The piston 15 compresses the refrigerant while linearly reciprocating in the cylinder bore 13.

One front housing 20 is installed at one end of the cylinder block 10. The front housing 20 is recessed to face the cylinder block 10 to form a crank chamber 21 together with the cylinder block 10. The crank chamber 21 is kept airtight with the outside.

A pulley shaft part 22 in which a pulley (not shown) is rotatably installed on the opposite side of the cylinder block 10 is formed to protrude from the front housing 20. A shaft hole 23 is formed by penetrating the center of the pulley shaft portion 22 and penetrating the front housing 20 back and forth to the crank chamber 21. The shaft hole 23 is formed to coincide with the center bore 11. One end of the rotation shaft 40 is rotatably supported by the shaft hole 23.

The rear housing 30 is installed at the other end of the cylinder block 10, that is, on the opposite side to which the front housing 20 is installed. The rear housing 30 is formed with a discharge chamber 31 in selective communication with the cylinder bore 13. The discharge chamber 31 is formed along an edge of a surface of the rear housing 30 facing the cylinder block 10. The discharge chamber 31 is a place where the refrigerant compressed in the cylinder bore 13 is discharged and temporarily stays.

The rear housing 30 has a suction chamber 33 is formed. The suction chamber 33 is also in selective communication with the cylinder bore 13. The suction chamber 33 is formed in an area corresponding to the center of the surface of the rear housing 30 facing the cylinder block 10. The suction chamber 33 serves to deliver the refrigerant to be compressed into the cylinder bore 13. The suction chamber 33 transfers the refrigerant to the communication path 14 through a flow path 41 formed in the rotary shaft 40 to be described below. Reference numeral 33 ′ serves as a suction port to transfer the refrigerant from the outside of the compressor 10 to the suction chamber 33.

The bolt 37 is fastened through to fasten the cylinder block 10, the front housing 20, and the rear housing 30 to each other. A plurality of bolts 37 are fastened through the edges of the cylinder block 10, the front housing 20, and the rear housing 30 simultaneously.

The rotating shaft 40 is rotatably installed through the center bore 11 of the cylinder block 10 and the shaft hole 23 of the front housing 20. The rotating shaft 40 is rotated by the driving force transmitted from the engine. The rotating shaft 40 is rotatably installed by the bearing 42 in the front housing 20. The flow path 41 is formed inside the rotation shaft 40. The flow passage 41 is opened to the rear end of the rotation shaft 40 to communicate with the suction chamber 33. An outlet 41 ′ is formed in the flow path 41 to selectively communicate with the communication path 14. The outlet 41 ′ is opened to the outer circumferential surface of the rotation shaft 40 and selectively communicates with the communication path 14.

The rotor 44 is installed on the rotation shaft 40. The rotor 44 is installed in the crank chamber 21 so that the rotating shaft 40 passes through the center and rotates integrally with the rotating shaft 40. The rotor 44 is fixed to the rotating shaft 40 in a substantially disk shape is installed. The hinge arm 46 protrudes from one surface of the rotor 44. A hinge slot 47 is formed in the hinge arm 46.

The swash plate 48 is installed on the rotation shaft 40. The swash plate 48 is formed to protrude a connecting arm 49 is connected to the hinge arm 46 of the rotor 44. A hinge pin 49 'is installed at a distal end of the connecting arm 49 in a direction orthogonal to the longitudinal direction of the connecting arm 49. The hinge pin 49' is a hinge arm 46 of the rotor 44. It is movably hung on the hinge slot 47 formed at the tip of the head.

The swash plate 48 is hinged and rotated together with the rotor 44. The swash plate 48 is installed so that the angle is variable on the rotation shaft 40, between the state orthogonal to the longitudinal direction of the rotation shaft 40 and inclined at a predetermined angle with respect to the rotation shaft 40 To be in position.

The radial shaft spring 50, which is a coil spring, is installed on the rotary shaft 40 to surround the rotary shaft 40. The radial yarn spring 50 exerts an elastic force between the rotor 44 and the swash plate 48. The radial yarn spring 50 exerts an elastic force in a direction in which the inclination angle of the swash plate 48 decreases, and absorbs a force acting on the swash plate 48 when the compressor 1 is stopped. do.

The swash plate 48 has its edge connected via the pistons 15 and the shoe 52. That is, the edge of the swash plate 48 is connected to the connecting portion 17 of the piston 15 through the shoe 52 so that the piston 15 is rotated in the cylinder bore 13 by the rotation of the swash plate 48. Make a straight reciprocating movement.

A valve assembly 53 is provided between the cylinder block 10 and the rear housing 30 to control the flow of the refrigerant between the discharge chamber 31 and the cylinder bore 13. The valve assembly 53 is composed of a valve plate 54 and a discharge lead 56 having a discharge hole 54 ′, which controls the flow of refrigerant from the cylinder bore 13 to the discharge chamber 31.

Hereinafter, the operation of the swash plate compressor according to the prior art having the configuration as described above will be described.

When the rotary shaft 40 is rotated by the driving force of the engine, the rotor 44 rotates together, and the swash plate 48 rotates together by the rotor 44. Rotation of the swash plate 48 is transmitted to the piston 15 through the shoe 52.

Accordingly, the piston 15 compresses the refrigerant while linearly reciprocating in the cylinder bore 13. At this time, the stroke distance of the piston 15 is determined according to the angle of the swash plate 48. The angle of the swash plate 48 may be adjusted by the pressure of the refrigerant delivered into the crank chamber 21.

On the other hand, it will be described that the refrigerant is delivered into the cylinder bore (13). The refrigerant is sucked from the outside through the suction port 33 ′ to the suction chamber 33, and the refrigerant transferred to the suction chamber 33 is transferred to the flow path 41 of the rotary shaft 40. Refrigerant delivered to the flow path 41 is each by the outlet 41 'is sequentially communicated with each cylinder bore 13 and each communication path 14 in accordance with the rotation of the rotary shaft 40 It is delivered to the cylinder bore (13).

The refrigerant compressed and delivered to the cylinder bore 13 is delivered to the discharge chamber 31 by the valve assembly 53 and to the outside of the compressor 10. That is, when the refrigerant is compressed to increase the pressure inside the cylinder bore 13, the tip of the discharge lead 56 is pushed by the pressure, and the discharge hole 54 ′ is opened to open the inside of the cylinder bore 13. Discharges the coolant into the discharge chamber 31.

For reference, as the refrigerant is sucked into the cylinder bore 13, the pressure in the cylinder bore 13 drops while the piston 15 moves to the bottom dead center, and the rotating shaft 40 through the communication path 14. This is because the inner flow passage 41 and the cylinder bore 13 communicate with each other.

However, the above-described conventional techniques have the following problems.

In the process in which the refrigerant is compressed by the piston 15 in the cylinder bore 13, leakage occurs during compression into a gap between the piston 15 and the inner surface of the cylinder bore 13, thereby degrading the compression performance. The refrigerant is transferred to the crank chamber 21 to change the pressure of the crank chamber 21 so that the control operation of the swash plate 48 is not properly performed.

Accordingly, an object of the present invention is to solve the problems of the prior art as described above, and to recycle the refrigerant forming the pressure of the crankcase when performing the variable compression in the variable displacement swash plate type compressor.

Another object of the present invention is to deliver the refrigerant in the crankcase into the cylinder bore at the end of the suction stroke.

Still another object of the present invention is to prevent oil from being separated from the refrigerant and transferred to the cylinder bore in the process of transferring the refrigerant in the crank chamber to the cylinder bore.

According to a feature of the present invention for achieving the object as described above, the present invention is a center bore is formed through the center and a plurality of cylinder bores are formed around the center bore and the center bore and the cylinder bore communication path A cylinder block communicating with each other through the front housing, which is installed at the front end of the cylinder block to form a crank chamber therein, and a rear housing installed at the rear end of the cylinder block and having a discharge chamber and a suction chamber formed therein; A rotating shaft installed and rotated through a center bore and a crank chamber and coupled with a swash plate positioned in a variable inclination in the crank chamber, and rotated together with one end of the rotating shaft to be integrally rotated with the rotating shaft and into the cylinder bore. A rotary valve for transmitting a coolant, and receiving the rotation of the rotary shaft through the swash plate in the cylinder bore In the swash plate-type compressor comprising a piston for compressing the refrigerant, respectively, in the rotary valve is formed an additional passage for communicating the crank chamber and the communication path is formed in the cylinder bore through the communication path of the refrigerant in the crank chamber In order to be compressed by the transmission, the extraction passage inlet communicating with the crank chamber in the extraction passage is located on the opposite side of the rotation direction of the rotary valve than the extraction passage outlet communicating with the cylinder bore side.

In the bleeding passage, the bleeding passage outlet is formed to be opened at a position corresponding to a rear end of the rotary valve in the rotational direction with respect to the outlet of the flow passage opening to the outer surface of the rotary valve so that the refrigerant is sucked into the cylinder bore through the outlet. After that, the refrigerant in the crankcase is transferred to the cylinder bore.

In the variable displacement swash plate compressor according to the present invention, since the refrigerant introduced into the crank chamber and controlling the inclination angle of the swash plate is transferred to the inside of the cylinder bore for recycling, the performance of the compressor can be relatively improved.

Next, in the present invention, the refrigerant in the crankcase having a relatively high pressure is introduced into the cylinder bore at the end of the suction stroke in each cylinder bore, thereby improving the compression performance in the cylinder bore.

In addition, in the present invention, the inlet of the bleeding passage is opened in the direction opposite to the rotational direction of the rotary valve so that oil is separated from the refrigerant in the process of transferring the refrigerant in the crank chamber to the cylinder bore. Therefore, the oil of the crankcase is not transferred to the cylinder bore, so that the compression performance is improved, and the oil in the compressor is not transferred to the outside of the compressor, so that the operation performance of the compressor is maintained for a long time.

Hereinafter, a preferred embodiment of a variable displacement swash plate compressor according to the present invention will be described in detail with reference to the accompanying drawings.

2 is a cross-sectional view showing the configuration of a preferred embodiment of the variable displacement swash plate compressor according to the present invention, FIG. 3 is a perspective view showing the main structure of the embodiment of the present invention, and FIG. 4 is a main part of the embodiment of the present invention. The configuration is shown in cross section.

As shown in these figures, the swash plate compressor 100 is provided with a cylinder block 110. The cylinder block 110 forms part of an appearance and a skeleton of the compressor 100. A center bore 111 is formed through the center of the cylinder block 110. The center bore 111 is a portion in which the rotating shaft 140 to be described below is rotatably installed.

A plurality of cylinder bores 113 are formed to radially penetrate the center bore 111 and penetrate the cylinder block 110. A communication path 114 is formed to communicate the cylinder bore 113 and the center bore 111. The communication path 114 is a passage for transferring the refrigerant to the cylinder bore 113.

The piston 115 is installed inside the cylinder bore 113 to enable a straight reciprocating motion. The piston 115 has a cylindrical shape, and the cylinder bore 113 has a cylindrical shape corresponding thereto. One end portion of the piston 115, that is, a portion protruding to the outside of the cylinder bore 113 is formed with a connecting portion 117. The piston 115 compresses the refrigerant while linearly reciprocating in the cylinder bore 113.

The front housing 120 is installed at one end of the cylinder block 110. The front housing 120 has a concave side facing the cylinder block 110 to cooperate with the cylinder block 110 to form a crank chamber 121 therein. The crank chamber 121 is kept airtight with the outside of the compressor.

The pulley shaft portion 122, in which the pulley 160 is rotatably installed, protrudes from the opposite side of the cylinder block 110 of the front housing 120. The shaft hole 123 is formed by penetrating the center of the pulley shaft portion 122 and penetrating the front housing 120 back and forth to the crank chamber 121. The shaft hole 123 is formed to coincide with the center bore 111. One end of the rotating shaft 140 is rotatably supported by the shaft hole 123.

The rear housing 130 is installed at the other end of the cylinder block 110, that is, on the opposite side to which the front housing 120 is installed. The rear housing 130 is formed with a discharge chamber 131 in selective communication with the cylinder bore 113. The discharge chamber 131 is formed along an edge of a surface of the rear housing 130 that faces the cylinder block 110. The discharge chamber 131 is a place where the refrigerant compressed in the cylinder bore 113 is discharged and temporarily stays.

The suction chamber 133 is formed at the center of the rear housing 130 facing the cylinder block 110. The suction chamber 133 also selectively communicates with the cylinder bore 113. The suction chamber 133 serves to deliver a refrigerant to be compressed into the cylinder bore 113. The suction chamber 133 transfers the refrigerant to the communication path 114 through the rotary valve 141 formed at one end of the rotary shaft 140.

The bolt 137 penetrates and fastens the cylinder block 110, the front housing 120, and the rear housing 130 to be fastened to each other. A plurality of bolts 137 penetrates through the edges of the cylinder block 110, the front housing 120, and the rear housing 130 simultaneously.

The rotating shaft 140 is rotatably installed through the center bore 111 of the cylinder block 110 and the shaft hole 123 of the front housing 120. The rotating shaft 140 is rotated by the driving force transmitted from the engine. The rotation shaft 140 is rotatably installed in the front housing 120 and the cylinder block 110. Reference numeral 140 ′ denotes an axis spring for supporting the rotation shaft 140 in the longitudinal direction.

One end of the rotary shaft 140 is provided with a rotary valve 141. The rotary valve 141 is formed integrally with the rotary shaft 140 in the present embodiment, but need not necessarily be, and may be coupled after being made separately from the rotary shaft 140.

A flow path 142 is formed in the rotary valve 141 to communicate with the suction chamber 133. The flow path 142 is formed to be opened to one end of the rotary valve 141. A flow path outlet 142 ′ is formed at an outer surface of the rotary valve 141 to selectively communicate the flow path 142 and the communication path 114.

On the other hand, the outer diameter of the rotary valve 141 is formed relatively larger than the rotary shaft 140. Therefore, a portion of the rotary valve 141 connected to the rotary shaft 140 faces the crank chamber 121 through the center bore 111. That is, the rotary valve 141 forms a part of the inner surface of the crank chamber 121.

The rotary valve 141 is formed with a bleeding passage 143. The additional passage 143 serves to communicate the crank chamber 121 and the communication path 114. The additional passage 143 is formed in the rotary valve 141, and is formed separately from the flow path 142. The cardinal passage 143 communicates with the crank chamber 121 and the cardinal passage inlet 143 ′, and the cardinal passage 143 communicates with the cardinal passage outlet 143 ″. 143 'is formed at a portion of the outer surface of the rotary valve 141 facing the crank chamber 121, and the bleeding passage outlet 143' is the center bore 111 of the outer surface of the rotary valve 141. ) Is formed on the surface in contact with.

In particular, the bleeding passage outlet 143 ″ is formed at a position adjacent to the bleeding passage 142 ′, and the bleeding passage outlet 142 ′ is formed at a rear end of the bleeding passage 142 ′ based on the rotational direction of the rotary valve 141. 143 "is formed to transfer the refrigerant of the crank chamber 121 to the cylinder bore 113 at the end of the suction stroke, which is after the refrigerant is sucked into the cylinder bore 113 through the flow path outlet 142 '.

On the other hand, the rotation shaft 140, that is to look at the position of forming the additional passage inlet 143 ′ and the additional passage outlet 143 ″ on the basis of the rotation direction of the rotary valve 141, in the present invention the additional passage passage inlet The opening direction of the 143 'is the opposite direction to the rotational direction of the rotary valve 141. In other words, the directional passage inlet 143' is a rotational direction of the rotary valve 141 rather than the directional passage outlet 143 ". The additional passage 143 is formed to be inclined so as to be located on the opposite side. The opening direction and the position of the additional extraction passage inlet 143 'is the rotational valve 141 is rotated, the refrigerant in the crank chamber 121 is due to the pressure difference between the crank chamber 121 and the cylinder bore 113 Although moved to the cylinder bore 113, even if some oil enters into the bleeding passage 143, as indicated by the arrow in Fig. 3, the guiding passage inlet 143 'by the centrifugal force according to the rotation of the rotary valve 141. Escaped into).

The rotor 146 is installed on the rotation shaft 140. The rotor 146 is installed in the crank chamber 121 so that the rotating shaft 140 passes through the center and rotates integrally with the rotating shaft 140. The rotor 146 is fixed to the rotating shaft 140 in a substantially disk shape is installed. The hinge arm 147 protrudes from one surface of the rotor 146. A hinge slot 147 'is formed in the hinge arm 147.

The swash plate 148 is installed on the rotation shaft 140. The swash plate 148 protrudes from the connecting arm 149 which is connected to the hinge arm 147 of the rotor 146. A hinge pin 149 'is installed at a distal end of the connecting arm 149 in a direction orthogonal to the longitudinal direction of the connecting arm 149. The hinge pin 149' is a hinge arm 147 of the rotor 146. It is movably walked to the hinge slot 147 'formed at the tip of the head.

The swash plate 148 is hinged and rotated together with the rotor 146. The swash plate 148 is installed so that the angle is variable on the rotating shaft 140, between the state orthogonal to the longitudinal direction of the rotating shaft 140 and inclined at a predetermined angle with respect to the rotating shaft 140 To be in position.

The radial shaft spring 150, which is a coil spring, is installed on the rotary shaft 140 to surround the rotary shaft 140. The radial yarn spring 150 exerts an elastic force between the rotor 146 and the swash plate 148. The radial yarn spring 150 exerts an elastic force in a direction in which the inclination angle of the swash plate 148 decreases, and absorbs a force acting on the swash plate 148 when the compressor 100 is stopped. do.

The swash plate 148 has an edge thereof connected to the pistons 115 and the shoe 152. That is, the edge of the swash plate 148 is connected to the connecting portion 117 of the piston 115 through the shoe 152 so that the piston 115 is in the cylinder bore 113 by the rotation of the swash plate 148. Make a straight reciprocating exercise at.

A valve assembly 153 is provided between the cylinder block 110 and the rear housing 130 to control the flow of the refrigerant between the discharge chamber 131 and the cylinder bore 113. The valve assembly 153 is constituted by a valve plate 154 and a discharge lead 156 having a discharge hole 154 ′, which controls the flow of refrigerant from the cylinder bore 113 to the discharge chamber 131.

A pulley 160 is rotatably installed at the pulley shaft portion 122 formed at the front end of the front housing 120. The pulley 160 is selectively connected to the rotary shaft 140 and the clutch 162 to transmit the driving force of the engine to the rotary shaft 140 via the pulley 160, the clutch 162.

Hereinafter, the operation of the variable displacement swash plate compressor according to the present invention having the configuration as described above.

When the rotary shaft 140 is rotated in the direction of arrow A of FIG. 4 by the driving force of the engine, the rotor 146 rotates together, and the swash plate 148 rotates together by the rotor 146. Rotation of the swash plate 148 is transmitted to the piston 115 through the shoe 152.

Accordingly, the piston 115 compresses the refrigerant while linearly reciprocating in the cylinder bore 113. At this time, the stroke distance of the piston 115 is determined according to the angle of the swash plate 148. The angle of the swash plate 148 may be adjusted by the pressure of the refrigerant delivered into the crank chamber 121.

On the other hand, it will be described that the refrigerant is delivered into the cylinder bore (113). The refrigerant delivered from the outside into the suction chamber 133 is transferred to the flow path 142 provided in the rotary valve 141 of the rotary shaft 140. The refrigerant delivered to the flow path 142 is sequentially communicated with each of the cylinder bores 113 and the respective communication paths 114 by the outlet 142 'according to the rotation of the rotary shaft 140. The cylinder bore 113 is delivered.

After the refrigerant is transferred to the cylinder bore 113 through the flow path 142, the refrigerant is transferred through the bleeding passage 143 to the cylinder bore 113 through which the refrigerant is transferred by the rotation of the rotary valve 141. The refrigerant in the crank chamber 121 is delivered. The refrigerant is delivered to the corresponding cylinder bore 113 as the bleeding passage outlet 143 " communicates with the communication passage 114. The refrigerant has a higher pressure than the refrigerant already sucked into the cylinder bore 113. will be.

For reference, the cylinder bore 113 indicated by the arrow in FIG. 4 is in a state where the piston 115 is in the top dead center, and the first cylinder bore 113 in the counterclockwise direction is just before the suction stroke starts. In addition, the second cylinder bore 113 is a state in which the suction stroke is made, and the third cylinder bore 113 is a state in which the refrigerant delivered through the additional passage 143 is sucked.

In addition, the oil in the crank chamber 121 may be partially delivered to the bleeding passage 143, which is formed to be inclined to the rotary valve 141, the bleeding passage inlet 143 ' It is formed so as to be located in a direction opposite to the rotation direction (arrow A direction in Fig. 3) of the rotary valve 141 relative to the additional passage passage 143 "and is formed to open in the opposite direction to the rotation direction. The refrigerant is delivered to the cylinder bore 113 by the pressure difference, but the oil is discharged toward the bleeding passage inlet 143 'by the centrifugal force acting on the rotary valve 141 and then delivered back to the crank chamber 121. .

Meanwhile, the refrigerant delivered to the cylinder bore 113 and compressed by the piston 115 is delivered to the discharge chamber 131 by the valve assembly 153 and is transferred to the outside of the compressor 100. That is, when the refrigerant is compressed to increase the pressure inside the cylinder bore 113, the tip of the discharge lead 156 is pushed by the pressure, and the discharge hole 154 ′ is opened to open the inside of the cylinder bore 113. Discharges the refrigerant to the discharge chamber 131.

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

1 is a cross-sectional view showing the configuration of a variable displacement swash plate compressor according to the prior art.

Figure 2 is a cross-sectional view showing the configuration of a preferred embodiment of a variable displacement swash plate compressor according to the present invention.

Figure 3 is a perspective view showing the configuration of a rotary valve constituting an embodiment of the present invention.

Figure 4 is a cross-sectional view showing a cross section cut to the cylinder block in the embodiment of the present invention.

Explanation of symbols on the main parts of the drawings

100: compressor 110: cylinder block

111: center bore 113: cylinder bore

114: communication path 115: piston

120: front housing 121: crankcase

122: pulley shaft portion 123: shaft hole

130: rear housing 131: discharge chamber

133: suction chamber 140: rotation axis

141: rotary valve 142; Euro

142 '; Exit 146: rotor

147: hinge arm 147 ': hinge slot

148: Saphan 149: connecting arm

150: radial yarn spring 153: valve assembly

154: valve plate 154 ': discharge hole

156: discharge lead 160: pulley

Claims (2)

A center bore 111 is formed through the center, and a plurality of cylinder bores 113 are formed around the center bore 111, and the center bore 111 and the cylinder bore 113 form a communication path 114. Cylinder block 110 and each communicated through, A front housing 120 installed at the front end of the cylinder block 110 to form a crank chamber 121 therein; A rear housing 130 installed at a rear end of the cylinder block 110 and having a discharge chamber 131 and a suction chamber 133 formed therein; A rotating shaft 140 installed and rotated through the center bore 111 and the crank chamber 121 to rotate together with the swash plate 148 positioned to have a variable inclination in the crank chamber 121; A rotary valve 141 provided at one end of the rotary shaft 140 to rotate integrally with the rotary shaft 140 and to transfer the refrigerant to the cylinder bore 113; In the swash plate-type compressor comprising a piston 115 for receiving the rotation of the rotary shaft 140 through the swash plate 148 to compress the refrigerant in the cylinder bore 113, respectively, The crank chamber 121 and the additional passage 143 for communicating the communication path 114 is formed in the rotary valve 141 to cool the refrigerant in the crank chamber 121 through the communication path 114 of the cylinder bore ( To be compressed). The extraction passage inlet 143 ′ communicating with the crank chamber 121 in the extraction passage 143 is rotated by the rotary valve 141 than the extraction passage outlet 143 ″ communicating with the cylinder bore 113 side. A variable displacement swash plate compressor characterized in that it is located opposite the direction. The rotary valve of claim 1, wherein the bleeding passage outlet 143 ″ from the bleeding passage 143 is based on an outlet 142 ′ of the flow passage 142 that opens to the outer surface of the rotary valve 141. It is formed to be opened at a position corresponding to the rear end of the rotational direction of the (141) and the refrigerant is sucked into the cylinder bore 113 through the outlet 142 'and the refrigerant in the crank chamber 121 to the cylinder bore 113 Variable displacement swash plate compressor characterized in that the transmission.

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