KR101463263B1 - Swash plate type compressor - Google Patents

Abstract

The present invention relates to a swash plate type compressor. In the swash plate compressor of the present invention, a center bore 111 is formed through the center of the cylinder block 110 and a plurality of cylinder bores 113 are formed around the center bore 111. The front housing 120 and the rear housing 130 are installed at the front and rear ends of the cylinder block 110, respectively. A swash plate 148 is installed in the crank chamber 121 and rotates together with the rotation shaft 140 through the center bore 111 and the crank chamber 121, And an interlocking pin 141 eccentric from the rotation center of the rotary shaft 140 is provided. The rotation of the rotary shaft 140 is transmitted through the swash plate 148, and the piston 115 compresses the refrigerant in the cylinder bore 113. An auxiliary suction hole 116 is formed in the cylinder block 110 so as to open both ends toward the center bore 111 and the cylinder bore 113. Both ends of the auxiliary suction hole 116 are formed inside the rotating shaft 140, The hollow portion 141 is opened to the chamber 121 and the auxiliary suction hole 116 so that the refrigerant in the crank chamber 121 flows into the cylinder bore 113.

Swash plate type, compressor, plate valve

Description

[0001] Swash plate type compressor [0002]

The present invention relates to a swash plate type compressor, and more particularly, to a swash plate type compressor in which a plurality of pistons provided respectively in a plurality of cylinder bores of a cylinder block are linearly reciprocated using a swash plate installed on a rotary shaft to compress refrigerant.

The air conditioning system of a vehicle is briefly described. First, a high-temperature low-pressure gaseous refrigerant is converted into a high-temperature and high-pressure gaseous state by a compressor. The high-temperature high-pressure gaseous refrigerant is brought into a high-temperature and high-pressure liquid state by the condensing action of the condenser through the condenser, and the refrigerant in the high-temperature and high-pressure liquid state passes through the expansion valve to the low- do. The refrigerant in the low-temperature low-pressure liquid state is returned to the high-temperature low-pressure gaseous state through the heat exchanger in the evaporator via the evaporator, and the high-temperature low-pressure gas is again compressed by the compressor to become a high-temperature high-pressure gaseous state. The air conditioning system of the vehicle is operated by repeating this process.

The compressor for compressing the refrigerant includes a reciprocating type that performs compression while performing a reciprocating motion in a structure that actually compresses the working fluid, and a rotary type that performs compression while performing rotational motion.

In the reciprocating type, there is a crank type in which the driving force of the driving source is transmitted using a crankshaft, a swash plate type in which the swash plate is rotated, and a wobble plate type in which a wobble plate is used. Rotary types include rotary rotary axes with vane rotary vanes, scrolling with rotary scrolls and fixed scrolls.

Fig. 1 shows the construction of a variable displacement swash plate type compressor according to the prior art. Accordingly, the swash plate type compressor 1 is provided with the cylinder block 10. The cylinder block 10 forms a part of the skeleton and the outer appearance 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 a rotary shaft 40 to be described below is rotatably installed.

A plurality of cylinder bores 13 are formed to penetrate the cylinder block 10 radially around the center bore 11. A communication passage (14) is formed so that the cylinder bore (13) and the center bore (11) communicate with each other. The communication passage 14 serves as a passage through which the refrigerant is delivered to the cylinder bore 13.

 A piston (15) is installed in the cylinder bore (13) so as to reciprocate linearly. The piston 15 has a cylindrical shape, and the cylinder bore 13 has a cylindrical shape corresponding thereto. A connecting portion 17 is formed at one end of the piston 15, that is, a portion protruding outward from the cylinder bore 13. The piston 15 linearly reciprocates in the cylinder bore 13 to compress the refrigerant.

A front housing (20) is installed at one end of the cylinder block (10). The front housing 20 is inserted into a side facing 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 portion 22 is rotatably installed on the opposite side of the cylinder block 10 from the front housing 20 so as to be rotatable. A shaft hole 23 is formed through the center of the pulley shaft 22 and penetrates the front housing 20 forward and backward to the crank chamber 21. The shaft hole 23 is formed so as to be coaxial with the center bore 11. One end of the rotary shaft (40) is rotatably supported on the shaft hole (23).

A rear housing 30 is provided at the other end of the cylinder block 10, that is, opposite to the front housing 20. A discharge chamber (31) is formed in the rear housing (30) to selectively communicate with the cylinder bore (13). The discharge chamber 31 is formed along the edge of the rear housing 30 facing the cylinder block 10. The discharge chamber 31 is a place where refrigerant compressed in the cylinder bore 13 is discharged and temporarily stays.

A suction chamber (33) is formed in the rear housing (30). The suction chamber (33) is also selectively communicated with the cylinder bore (13). The suction chamber 33 is formed in a region of the rear housing 30 corresponding to the center of the surface facing the cylinder block 10. The suction chamber (33) serves to transfer 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 inside the rotation shaft 40 to be described below. Reference numeral 33 'denotes a suction port for transferring the refrigerant from the outside of the compressor 10 to the suction chamber 33.

The bolts 37 are fastened through the cylinder block 10, the front housing 20 and the rear housing 30 to each other. A plurality of bolts 37 pass through the edges of the cylinder block 10, the front housing 20, and the rear housing 30 to perform a fastening operation.

A rotating shaft 40 is installed to be rotatable through the center bore 11 of the cylinder block 10 and the shaft hole 23 of the front housing 20. [ The rotary shaft (40) is rotated by the driving force transmitted from the engine. The rotary shaft (40) is rotatably installed on the front housing (20) by a bearing (42). A flow path 41 is formed in the rotating shaft 40. The flow passage 41 is open to the rear end of the rotary shaft 40 and communicates 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 peripheral surface of the rotary shaft (40) and selectively communicated with the communication passage (14).

A rotor 44 is installed on the rotating shaft 40. The rotor 44 is installed in the crank chamber 21 so that the rotating shaft 40 passes through the center and is integrally rotated with the rotating shaft 40. The rotor 44 is fixed to the rotating shaft 40 in a substantially disc shape. A hinge arm (46) protrudes from a surface of the rotor (44). The hinge arm 46 has a hinge slot 47 formed therein.

A swash plate (48) is installed on the rotating shaft (40). A connecting arm 49 connected to the hinge arm 46 of the rotor 44 protrudes from the swash plate 48. A hinge pin 49 'is provided at the tip of the connecting arm 49 in a direction perpendicular to the longitudinal direction of the connecting arm 49. The hinge pin 49' And is hinged to the hinge slot 47 formed at the distal end of the hinge slot.

The swash plate 48 is hingedly coupled to the rotor 44 and rotated together. The swash plate 48 is installed between the swash plate 48 and the rotary shaft 40 so that the angle of the swash plate 48 is orthogonal to the longitudinal direction of the rotary shaft 40 and is inclined at a predetermined angle with respect to the rotary shaft 40 Position.

A semi-inclined spring 50, which is a coil spring, is installed on the rotary shaft 40 so as to surround the rotary shaft 40. The semi-inclined springs (50) exert an elastic force between the rotor (44) and the swash plate (48). The semi-inclined spring 50 exerts an elastic force in a direction in which the inclination angle of the swash plate 48 is reduced and absorbs a force acting on the swash plate 48 when the operation of the compressor 1 is stopped do.

The swash plate 48 has its edge connected to the pistons 15 through a 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 linear reciprocating motion.

A valve assembly 53 for controlling the flow of the refrigerant between the discharge chamber 31 and the cylinder bore 13 is provided between the cylinder block 10 and the rear housing 30. The valve assembly 53 is constituted by a valve plate 54 and a discharge lead 56 having a discharge hole 54 'to control the refrigerant flow from the cylinder bore 13 to the discharge chamber 31.

Hereinafter, the operation of the conventional swash plate compressor having the above-described structure will be described.

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

Accordingly, the piston 15 linearly reciprocates in the cylinder bore 13 to compress the refrigerant. 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) can be adjusted by the pressure of the refrigerant transferred into the crank chamber (21).

On the other hand, the refrigerant is transferred into the cylinder bore 13. The refrigerant is sucked into the suction chamber 33 from the outside through the suction port 33 'and the refrigerant transferred to the suction chamber 33 is transferred to the flow path 41 of the rotary shaft 40. The outlet 41 'is sequentially communicated with the respective cylinder bores 13 through the respective communication passages 14 in accordance with the rotation of the rotary shaft 40, And is transmitted 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 is delivered to the outside of the compressor 10. That is, when the refrigerant is compressed and the pressure inside the cylinder bore 13 is increased, the leading end of the discharge lead 56 is pushed by the pressure to open the discharge hole 54 ' So that the refrigerant is discharged to the discharge chamber 31.

The refrigerant is sucked into the cylinder bore 13 because the piston 15 is moved to the bottom dead center and the pressure inside the cylinder bore 13 drops and the refrigerant is sucked into the cylinder bore 13 through the communication passage 14, The flow path 41 and the cylinder bore 13 communicate with each other.

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

When the compressor 10 is started and the rotary shaft 40 is rotated, the swash plate 48 is rotated while the inclination angle thereof is increased to reciprocate the piston 15. At this time, if the inclination angle of the swash plate 48 is increased within a short time, the piston 15 also has a long reciprocating stroke in a short time, and the compression efficiency by the compressor 10 is increased.

However, in order to increase the inclination angle of the swash plate 48, the pressure in the crank chamber 21 must be lowered. Since the refrigerant exists in the crank chamber 21 at the time of starting the compressor 10, ) Pressure can not be lowered immediately but has a certain delay time. Therefore, there is a problem that the swash plate 48 is rotated at a very small inclination angle for a certain period of time, resulting in an inefficiency of the compressor 10.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to solve the problems of the prior art as described above, and to provide a swash plate which is increased in its inclination angle in a short time at the start of the compressor.

According to an aspect of the present invention, there is provided a cylinder block having a center bore formed through a center thereof and having a plurality of cylinder bores formed around the center bore, A rear housing installed at a rear end of the cylinder block and having a discharge chamber and a suction chamber formed therein,

A rotary shaft installed to penetrate through the center bore and the crank chamber and rotated together with the swash plate disposed in the crank chamber,

And a piston which receives the rotation of the rotary shaft through the swash plate and compresses the refrigerant in the cylinder bore, the swash plate compressor comprising:

Wherein the cylinder block is formed with an auxiliary suction hole having both ends opened toward the center bore and the cylinder bore, and a hollow portion having both ends thereof opened toward the crank chamber and the auxiliary suction hole is formed inside the rotating shaft, And the refrigerant in the inside flows into the inside of the cylinder bore.

The size of the auxiliary suction hole is smaller than or equal to the size of the orifice hole formed in the cylinder block to communicate the crank chamber and the suction chamber.

In the swash plate type compressor according to the present invention having the above-described structure, the following effects can be obtained.

In the present invention, since the hollow portion formed inside the rotary shaft of the compressor connects between the crank chamber and the cylinder bore, refrigerant in the crank chamber can smoothly flow into the cylinder bore through the hollow portion at the time of starting the compressor, So that the efficiency of starting the compressor can be improved.

In the present invention, when the inclination angle of the swash plate is maximized, the refrigerant can be introduced into the cylinder bore by not only the suction reed valve but also the hollow portion formed inside the rotary shaft of the compressor, So that the efficiency of the compressor can be improved.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of a swash plate type compressor according to the present invention will be described in detail with reference to the accompanying drawings.

FIG. 2 shows a configuration of a preferred embodiment of a swash plate type compressor according to the present invention, and FIG. 3 is a perspective view showing the configuration of a cylinder block constituting an embodiment of the present invention.

According to this, the swash plate type compressor 100 is provided with the cylinder block 110. The cylinder block 110 forms a part of the outer structure and the skeleton of the compressor 100. A center bore 111 is formed through the center of the cylinder block 100. The center bore 111 is a portion in which a rotation shaft 140, which will be described below, is rotatably installed.

A plurality of cylinder bores 113 are formed to penetrate the cylinder block 110 radially around the center bore 111. A piston 115 is installed in the cylinder bore 113 so as to reciprocate linearly. The piston 115 has a cylindrical shape and the cylinder bore 113 is a cylindrical space corresponding to the cylinder bore. A connecting portion 117 is formed at one end of the piston 115, that is, a portion protruding outward from the cylinder bore 113. The piston 115 linearly reciprocates in the cylinder bore 113 to compress the refrigerant.

As shown in FIG. 3, an orifice hole 114 is formed in the cylinder block 110. The orifice hole 114 penetrates the cylinder block 110 and connects the suction chamber 133 and the crank chamber 121, which will be described below.

An auxiliary suction hole 116 is formed in the cylinder block 110. 3, the auxiliary suction hole 116 is formed in a direction substantially orthogonal to the opening direction of the orifice hole 114 so that the cylinder bore 113 and the hollow portion of the rotation shaft 140, Thereby making the portion 141 communicate.

The auxiliary suction hole 116 allows the refrigerant in the crank chamber 121 to flow into the cylinder bore 113 at the initial stage of the compressor 100 to reduce the internal pressure of the crank chamber 121, And serves to increase the inclination angle. At the same time, the auxiliary suction hole 116 smoothly supplies the refrigerant into the cylinder bore 113 together with the suction hole 155, which will be described later, during the operation of the compressor 100, Coefficient Of Performance.

At this time, the size of the auxiliary suction hole 116 is preferably smaller than or equal to the size of the orifice hole 114. 4, when the size of the auxiliary suction hole 116 is equal to or smaller than the size of the orifice hole 114, the performance coefficient of the compressor 100 is maintained, and at the same time when the compressor 100 is started The operation delay time caused by the small inclination angle of the swash plate 148 is reduced. Preferably, the size of the auxiliary suction hole 116 is equal to the size of the orifice hole 114.

A front housing 120 is installed at one end of the cylinder block 110. The front housing 120 is inserted into a side facing the cylinder block 110 to form a crank chamber 121 together with the cylinder block 110. The crank chamber 121 is kept airtight with the outside.

A pulley shaft portion 122 is installed on the opposite side of the cylinder block 110 of the front housing 120 so that a pulley (not shown) is rotatably installed. A shaft hole 123 is formed through the center of the pulley shaft portion 122 and penetrates the front housing 120 forward and backward to the crank chamber 121. The shaft hole 123 is centered with the center bore 111. One end of the rotation shaft 140 is rotatably supported on the shaft hole 123.

A rear housing 130 is installed at the other end of the cylinder block 110, that is, opposite to the front housing 120. A discharge chamber 131 is formed in the rear housing 130 so as to selectively communicate with the cylinder bore 113. The discharge chamber 131 is formed along the edge of the rear housing 130 facing the cylinder block 110. Particularly, the discharge chamber 131 is formed along a position adjacent to the outer peripheral edge of the rear housing 130. The discharge chamber 131 is a place where the refrigerant compressed by the cylinder bore 113 is discharged and temporarily stays.

A suction chamber 133 is formed in the rear housing 130. The suction chamber 133 is also selectively communicated with the cylinder bore 113. The suction chamber 133 is formed in a region of the rear housing 130 corresponding to the center of a surface facing the cylinder block 110. The suction chamber 133 serves to transfer the refrigerant to be compressed into the cylinder bore 113. The suction port for transferring the refrigerant from the outside to the suction chamber 133 is not shown in this embodiment.

A bolt 137 is inserted through the cylinder block 110, the front housing 120, and the rear housing 130 so as to be coupled with each other. A plurality of bolts 137 pass through the edges of the cylinder block 110, the front housing 120, and the rear housing 130 to perform a tightening action.

A rotating shaft 140 is installed to be rotatable through the center bore 111 of the cylinder block 110 and the shaft hole 123 of the front housing 120. The rotation shaft 140 is rotated by the driving force transmitted from the engine. The rotary shaft 140 is rotatably mounted on the front housing 120 by a bearing B.

The rotation shaft 140 has a hollow portion 141 formed therein. The hollow portion 141 is an empty space formed along the longitudinal direction inside the rotation shaft 140 and serves to communicate the crank chamber 121 and the cylinder bore 113.

More precisely, an inlet portion 142 and an outlet portion 143 are formed at both ends of the hollow portion 141. The inlet portion 142 is formed to open toward the crank chamber 121, The outlet 143 is formed to open toward the auxiliary suction hole 116. The refrigerant in the crank chamber 121 flows into the hollow portion through the inlet portion 142 and the outlet portion 143 of the hollow portion 141 and the auxiliary suction hole 116 communicated therewith, To the inside of the cylinder bore (113).

A rotor 144 is installed on the rotating shaft 140. The rotor 144 is installed in the crank chamber 121 so that the rotation shaft 140 passes through the center and is integrally rotated with the rotation shaft 140. The rotor 144 is fixed to the rotating shaft 140 in a substantially disc shape. A hinge arm 146 protrudes from a surface of the rotor 144.

The swash plate 148 is installed on the rotating shaft 140. A connecting arm 149 hinged to the hinge arm 146 of the rotor 144 protrudes from the swash plate 148. The connecting arm 149 is connected at its tip by the hinge arm 146 and the hinge structure 149 '. Accordingly, the swash plate 148 is hingedly coupled to the rotor 144 and rotated together.

The swash plate 148 is installed to vary the angle of the swash plate 148 with respect to the rotation axis 140 and is disposed between the swash plate 148 and the swash plate 148 in a state in which the swash plate 148 is inclined at a predetermined angle with respect to the rotation axis 140 Position.

A semi-inclined spring 150, which is a coil spring, is installed on the rotation shaft 140 so as to surround the rotation shaft 140. The anti-tilt spring 150 exerts an elastic force between the rotor 144 and the swash plate 148. The antireflection spring 150 exerts an elastic force in a direction in which the inclination angle of the swash plate 148 is reduced and absorbs a force acting on the swash plate 148 when the operation of the compressor 100 is stopped do.

The swash plate 148 has its edge connected to the pistons 115 through a 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 rotated in the cylinder bore 113 by the rotation of the swash plate 148 Make a linear reciprocating motion.

A valve assembly 153 for controlling the flow of the refrigerant between the discharge chamber 131 and the cylinder bore 113 is provided between the cylinder block 110 and the rear housing 130. The valve assembly 153 includes a valve plate 154 and a discharge lead 156 having a discharge hole 154 'to control the refrigerant flow from the cylinder bore 113 to the discharge chamber 131.

The discharge hole 154 'and the suction hole 155 are formed in the valve plate 154 at positions corresponding to the respective cylinder bores 113. The suction hole 155 is a path through which the refrigerant is delivered from the suction chamber 133 to the cylinder bore 113. The suction hole 155 is a path through which the compressed refrigerant is discharged to the discharge chamber 131, .

Hereinafter, the operation of the swash plate type compressor according to the present invention will be described.

The driving force of the engine is transmitted to the rotating shaft 140 to rotate the rotating shaft 140. When the rotation shaft 140 rotates, the rotor 144 rotates together and the swash plate 148 rotates together with the rotor 144. [ The rotation of the swash plate 148 is transmitted to the piston 115 through the shoe 152.

Accordingly, the piston 115 linearly reciprocates in the cylinder bore 113 to compress the refrigerant. At this time, the stroke of the piston 115 is determined according to the angle of the swash plate 148. The strength of the swash plate 148 is adjusted according to the pressure inside the crank chamber 121. That is, when the pressure of the crank chamber 121 is low, the swash plate 148 can have a large inclination angle.

Since the hollow portion 141 is formed in the rotary shaft 140, the refrigerant in the crank chamber 121 can flow into the cylinder bore 131 along the hollow portion 141. That is, the refrigerant introduced through the inlet portion 142 of the hollow portion 141 passes through the outlet portion 143 and the auxiliary suction hole 116 in order, and flows into the cylinder bore 113. Accordingly, the initial pressure of the crank chamber 121 can be lowered, and the inclination angle of the swash plate 148 can be increased quickly.

And, as the inclination angle of the swash plate 148 increases in a short period of time, the compressor 100 can be operated at the maximum capacity without a large delay.

On the other hand, the refrigerant is transferred into the cylinder bore 113. The suction of the refrigerant into the cylinder bore 113 causes the piston 115 to move to the bottom dead center within the cylinder bore 113, The pressure inside the bore 113 drops and the suction opening 166 of the plate rotary valve 160 communicates with the suction hole 155 of the corresponding cylinder bore 113.

The refrigerant transferred 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 delivered to the outside of the compressor 100. That is, when the refrigerant is compressed and the pressure inside the cylinder bore 113 increases, the discharge reed 156 opens the discharge hole 154 'to discharge the refrigerant from the cylinder bore 113 into the discharge chamber 131 .

The hollow portion 141 of the rotating shaft 140 assists the refrigerant to flow into the cylinder bore 113 even after the swash plate 148 reaches the maximum inclination angle. The refrigerant can be supplied smoothly.

The scope of the present invention is not limited to the embodiments described above and shown in the drawings, but is defined by the claims. It will be apparent to those skilled in the art that various modifications and variations can be made in the present invention without departing from the scope of the invention as defined by the appended claims. Do.

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a sectional view showing an internal configuration of a conventional swash plate type compressor. FIG.

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

3 is a perspective view showing a configuration of a cylinder block constituting an embodiment of the present invention.

4 is a graph showing the magnitude of the performance coefficient and the operation delay time for the size of the auxiliary suction hole and the size ratio of the orifice hole of the cylinder block constituting the embodiment of the present invention.

Description of the Related Art [0002]

100: compressor 110: cylinder block

111: center bore 113: cylinder bore

114: orifice hole 116: auxiliary suction hole

115: piston 117:

120: front housing 121: crank chamber

122: pulley shaft part 123:

130: rear housing 131: discharge chamber

133: Suction chamber 140:

141: hollow part B: bearing

144: Rotor 146: Hinge arm

148: swash plate 149: connecting arm

149 ': Hinge structure 150: Semi inclined spring

152: Shu 153: valve assembly

154: valve plate 154 ': discharge hole

155: Suction ball 156: Discharge lead

Claims (2)

A cylinder block 110 through which a center bore 111 is formed and a plurality of cylinder bores 113 are formed around the center bore 111, A front housing 120 installed at a 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 rotation shaft 140 installed to penetrate through the center bore 111 and the crank chamber 121 and rotated together with the swash plate 148 located in the crank chamber 121, And a piston (115) that receives the rotation of the rotary shaft (140) through the swash plate (148) and compresses the refrigerant in the cylinder bore (113) The cylinder block 110 is formed with an auxiliary suction hole 116 having both ends open toward the center bore 111 and the cylinder bore 113. Both ends of the auxiliary suction hole 116 are inserted into the crank chamber 121 and the hollow portion 141 is opened toward the auxiliary suction hole 116 so that the refrigerant in the crank chamber 121 flows into the cylinder bore 113 and the auxiliary suction hole 116 Is formed to be smaller than or equal to the size of the orifice hole (114) formed in the cylinder block (110) and communicating between the crank chamber (121) and the suction chamber (133). delete

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