The present invention relates to a variable displacement compressor used in a refrigerant circuit of a vehicle air-conditioner.
In a variable displacement compressor, a cylinder bore is formed in a housing and a drive shaft is rotatably supported in the housing. A lug plate is connected to the drive shaft so as to rotate therewith, and a swash plate is supported on the drive shaft so as to incline with respect to the drive shaft. A link mechanism is arranged between the lug plate and the swash plate. A piston is accommodated in the cylinder bore for reciprocation and is engaged with the outer periphery of the swash plate.
The drive shaft is rotationally driven by a vehicle engine. The rotation of the drive shaft is transmitted to the swash plate through the lug plate and the link mechanism, so that the piston is reciprocated to compress refrigerant gas. The inclination angle of the swash plate is varied while the swash plate is guided by the link mechanism so that the stroke of the piston is changed and the displacement of the compressor is varied.
Japanese Patent Application Publication No. 2001-289159 discloses a link mechanism. As shown in
The rotation of the lug plate 102 is transmitted from the lug plate 102 to the swash plate 101 through the inner surface of the first guide groove 102a and the spherical surface of the first spherical portion 103a. Compression reactive force is eccentrically applied to the swash plate 101 through the piston, and its load center is indicated by the arrow X in
Here, the rotation of the lug plate 102 is not transmitted to the swash plate 101 through the second guide groove 102b since the second guide groove 102b is located on the preceding side of the rotational direction R with respect to the second spherical portion 103b. And also, the inner surface area of the second guide groove 102b that faces to the swash plate 101 receives the compression reactive force but other surface area does not. Accordingly, a wall portion 104a of the second bracket 104 is relevant to neither transmitting the lug plate rotation to the swash plate 101 nor transmitting the compression reactive force X from the swash plate 101 to the lug plate 102. The wall portion 104a of the second bracket 104 functions to restrict the swash plate 101 from further rotating toward the preceding side of the rotational direction R relative to the lug plate 102 when the second spherical portion 103b comes into contact with the inner surface of the second guide groove 102b. If the wall portion 104a of the second bracket 104 is simply removed, the swash plate 101 would substantially wobble forward and backward of the rotational direction R relative to the lug plate 102. Namely, when the swash plate 101 substantially wobbles forward and backward of the rotational direction R, the first spherical portion 103a repeatedly and fiercely collides with the inner surface of the first guide groove 102a, so that the variable displacement compressor generates abnormal noise and vibration.
Meanwhile, when the wall portion 104 of the second bracket 104 is provided, since the wall portion 104a has to have certain thickness, the interval between the first and second spherical portions 103a, 103b and the interval between the first and second guide grooves 102a, 102b has to be narrow by the thickness of the wall portion 104a. When the interval between the first and second spherical portions 103a, 103b and the interval between the first and second guide grooves 102a, 102b are narrow, the support of the swash plate 101 by the lug plate 102 is unstable under the compression reactive force X which is eccentrically applied to the radially outer portion of the swash plate 101. The eccentrically applied compression reactive force X makes the swash plate 101 incline in a direction different from its inclining direction when the displacement is varied. Due to this differently inclining swash plate 101, the first and second spherical portions 103a, 103b contact the respective first and second guide grooves 102a, 102b in different manners, so that sliding resistance between them becomes large. Thus, controllability of the displacement of the variable displacement compressor deteriorates.
The present invention is directed to a variable displacement compressor having a link mechanism that prevents a cam plate from substantially wobbling forward and backward along the rotational direction and being inclined in a direction different from its inclining direction when the displacement is varied.
According to the present invention, a variable displacement compressor for compressing gas includes a housing having a cylinder bore. A drive shaft is rotatably supported by the housing. A lug plate is connected to the drive shaft so as to rotate together with the drive shaft. A cam plate is supported on the drive shaft so as to incline with respect to the drive shaft. A piston is accommodated in the cylinder bore for reciprocation and engaged with the cam plate. A link mechanism is provided between the lug plate and the cam plate for transmitting rotation of the lug plate to the cam plate to reciprocate the piston thereby performing gas compression. An inclination angle of the cam plate being varied while being guided by the link mechanism to change a stroke volume of the piston so that displacement of the compressor is varied. The link mechanism includes a support portion protruding from the cam plate toward the lug plate, a first transmitting portion for transmitting rotation of the lug plate to the cam plate, the first transmitting portion includes a first transmitting surface formed in the lug plate and a first receiving surface formed in the cam plate, a second transmitting portion for transmitting compression reactive force from the cam plate to the lug plate, the second transmitting portion includes a second transmitting surface formed on a peripheral surface of a roller rotatably supported by the support portion and a second receiving surface formed in the lug plate, the first and second transmitting portions being arranged along a rotational direction of the drive shaft, the support portion being arranged between the first and second transmitting portions in the rotational direction of the drive shaft, and a movement restrictor arranged between the first transmitting portion and the second transmitting portion, the movement restrictor includes a restricting surface formed in the lug plate and a restricted surface protruding from the support portion, wherein a movement of the first receiving surface away from the first transmitting surface in the rotational direction of the drive shaft is restricted by the movement restrictor in such a manner that the restricted surface comes into contact with the restricting surface.
The features of the present invention that are believed to be novel are set forth with particularity in the appended claims. The invention together with objects and advantages thereof, may best be understood by reference to the following description of the presently preferred embodiments together with the accompanying drawings in which:
The following will describe the preferred embodiment, in which the present invention is applied to a variable displacement compressor used in a refrigerant circuit of a vehicle air-conditioner.
In the housing, a crank chamber 15 is defined by the cylinder block 11 and the front housing 12. A drive shaft 16 is rotatably supported by the cylinder block 11 and the front housing 12 and extends in the crank chamber 15. An engine E or a drive source for a vehicle is operatively connected to the drive shaft 16. The drive shaft 16 receives the driving power from the engine E and is rotated on its axis T in the direction indicated by an arrow R in
A substantially disc-shaped lug plate 17 is mounted on the drive shaft 16 in the crank chamber 15 so as to rotate therewith. A swash plate 18 or a cam plate is accommodated in the crank chamber 15 and has a through hole 18a at its center portion. The drive shaft 16 is inserted through the through hole 18a. A link mechanism 19 is arranged between the lug plate 17 and the swash plate 18 and connects the lug plate 17 and the swash plate 18. The connection is between the lug plate 17 and the swash plate 18 through the link mechanism 19 and allows the swash plate 18 to rotate synchronously with the lug plate 17 and the drive shaft 16. The support by the drive shaft 16 through the through hole 18a also allows the swash plate 18 to incline with respect to the drive shaft 16 while it slides along the axis T of the drive shaft 16.
A plurality of cylinder bores 27 is formed in the cylinder block 11 to extend therethrough in the longitudinal direction of the compressor 10 and equiangularly arranged around the axis T of the drive shaft 16. Only one cylinder bore 27 is shown in
The piston 28 is engaged with a pair of shoes 30 at an outer periphery of the swash plate 18. The rotational movement of the swash plate 18 is converted into the reciprocating movement of the piston 28 through the shoes 30. In the rear housing 14, a suction chamber 31 and a discharge chamber 40 are defined. A suction port 32 and a suction valve 33 provided in the valve plate assembly 13 are located between the compression chamber 29 and the suction chamber 31. A discharge port 34 and a discharge valve 35 provided in the valve plate assembly 13 are located between the compression chamber 29 and the discharge chamber 40.
As the piston 28 moves from its top dead center to its bottom dead center, refrigerant gas (carbon dioxide) in the suction chamber 31 is drawn to the compression chamber 29 through the suction port 32 and the suction valve 33. As the piston 28 moves from its bottom dead center to its top dead center, the drawn refrigerant gas in the compression chamber 29 is compressed to a predetermined pressure and discharged to the discharge chamber 40 through the discharge port 34 and the discharge valve 35.
In the housing of the compressor 10, a bleed passage 36, a supply passage 37 and a control valve 38 are arranged. The bleed passage 36 interconnects the crank chamber 15 with the suction chamber 31. The supply passage 37 interconnects the discharge chamber 40 with the crank chamber 15. The control valve 38 which is an electromagnetic control valve is arranged on the supply passage 37.
By adjusting an opening degree of the control valve 38, the pressure balance is controlled between the high-pressure discharge gas introduced from the discharge chamber 40 into the crank chamber 15 through the supply passage 37 and the gas flowing from the crank chamber 15 into the suction chamber 31 through the bleed passage 36. Thus, the internal pressure in the crank chamber 15 is determined. In accordance with the variation of the internal pressure in the crank chamber 15, the pressure difference is changed between the crank chamber 15 and the compression chamber 29 by the piston 28, and the inclination angle of the swash plate 18 is varied. Consequently, the stroke of the piston 28, that is, the displacement of the compressor 10 is adjusted. The inclination angle of the swash plate 18 is defined as an angle made between the swash plate 18 and a hypothetical plane perpendicular to the axis T of the drive shaft 16.
As the internal pressure in the crank chamber 15 is decreased, the inclination angle of the swash plate 18 is increased, and the stroke of the piston 28 is increased. Consequently, the displacement of the compressor 10 is increased. On the other hand, as the internal pressure in the crank chamber 15 is increased, the inclination angle of the swash plate 18 is decreased, and the stroke of the piston 28 is decreased. Consequently, the displacement of the compressor 10 is decreased. In the state as shown in
The following will describe the link mechanism 19. Firstly, elements provided on the swash plate 18 that constitutes the link mechanism 19 will be described. As shown in
A cylindrical roller 22 is supported by the second end 21b of the link pin 21 so as to rotate thereon. In order to improve its abrasion resistance, soft nitriding treatment is performed on an outer peripheral surface 22a of the roller 22 when the roller 22 is made of steel. Or, the roller 22 is made of high-silicon aluminum material. The link pin 21 is formed with a spherical portion 23 at its first end 21a. The roller 22 and the spherical portion 23 are arranged so as to place the direction TDC of the swash plate 18 therebetween along the rotational direction R.
Now, elements provided on the lug plate 17 that constitutes the link mechanism 19 will be described. A first cam portion 24 protrudes from the end face of the lug plate 17 toward the swash plate 18 and has a groove for guiding the spherical portion 23. The groove has a cylindrical inner surface 24a which is partially removed for receiving the spherical portion 23 of the link pin 21. As shown in
As shown in
The rotation of the lug plate 17 is transmitted to the swash plate 18 through the inner surface 24a of the first cam portion 24 and a spherical surface 23a of the spherical portion 23 (specifically its end region 23a-1). Compression reactive force is eccentrically applied to the radially outer portion of the swash plate 18 through the piston 28, and its load center is indicated by the arrow X in
Namely, in the preferred embodiment, the link mechanism includes the rotation transmitting portion and the compression reactive force transmitting portion. The former includes the groove inner surface 24a of the first cam portion 24 provided in the lug plate 17 and the spherical portion 23 of the link pin 21 provided in the swash plate 18. The latter includes the roller 22 of the link pin 21 and the cam surface 25a of the second cam portion 25.
As the displacement of the compressor 10 increases, the swash plate 18 is guided so that the spherical portion 23 slides over the inner surface 24a of the first cam portion 24 in a direction to move away from the drive shaft 16, and so that the roller 22 rolls on the cam surface 25 of the second cam portion 25 in the direction to move away from the drive shaft 16. On the other hand as the displacement of the compressor 10 decreases, the swash plate 18 is guided so that the spherical portion 23 slides over the inner surface 24a of the first cam portion 24 in a direction to come closer to the drive shaft 16 and so that the roller 22 rolls on the cam surface 25 of the second cam portion 25 in the direction to come closer to the drive shaft 16. Usage of the roller 22 as an element of the link mechanism 19 enables smooth variation in the inclination angle of the swash plate 18.
As shown in
Namely, the second cam portion 25 has a restricting surface 43 formed as a planar surface that faces toward the following side of the rotational direction of the shaft 16. The support portion 20 has a protrusion 20b which protrudes toward the lug plate 17 from the top end of the support portion 20 near the roller 22. The protrusion 20b has a restricted surface 44 as a planar surface that faces toward the preceding side of the rotational direction R. The restricted surface 44 comes in contact with the restricting surface 43. Thus, even when the torque of the engine E fluctuates, the swash plate 18 is prevented from substantially rotating or wobbling relative to the lug plate 17 frontward and backward of the rotational direction R. Consequently, the compressor 10 substantially prevents abnormal noise and vibration.
The restricting surface 43 of the lug plate 17 extends in a direction that the protrusion 20b moves in accordance with the inclination of the swash plate 18. Here, the extending range of the restricting surface 43 does not cover the entire moving range of the restricted surface 44. Namely, when the inclination angle of the swash plate 18 is substantially the maximum as shown in
The movement restrictor 41 is so constructed to change between two states in accordance with the variation in the inclination angle of the swash plate 18. Namely, in a restricting state, the restricted surface 44 comes in contact with the restricting surface 43 by slight wobble of the swash plate 18 relative to the lug plate 17 as shown in
It is noted that the swash plate 18 tends to substantially wobble back and forth in the rotational direction R relative to the lug plate 17 when the displacement of the compressor 10 is not substantially the maximum, particularly when the displacement of the compressor 10 is substantially the minimum. It is because the compression reactive force X applied to the swash plate 18 is small when the displacement of the compressor 10 is small, and the swash plate 18 is softly pressed against the lug plate 17 by the small compression reactive force X. Therefore, even though the movement restrictor 41 is in the non-restricting state when the displacement of the compressor 10 is substantially the maximum, it is not disadvantageous for preventing the swash plate 18 from substantially wobbling relative to the lug plate 17.
According to the above-constructed preferred embodiment, the following advantageous effects are obtained.
(1) The movement restrictor 41 is arranged between the rotation transmitting portion (the inner surface 24a of the first cam portion 24 and the spherical surface 23a of the spherical portion 23) and the compression reactive force transmitting portion (the outer peripheral surface 22a of the roller 22 and the cam surface 25a of the second cam portion 25) for preventing the swash plate 18 from substantially wobbling. Thus, the interval between the power transmitting portion and the compression reactive force transmitting portion is easily made wider without being affected by the arrangement of the movement restrictor 41. Therefore, the swash plate 18 is supported by the lug plate 17 stably with respect to the compression reactive force X eccentrically applied to the radially outer portion of the swash plate 18. Consequently, the stable support of the swash plate 18 prevents the swash plate 18 from inclining in a direction different from its inclining direction when the displacement is varied, even when the compression reactive force X is eccentrically applied to the swash plate 18.
The movement restrictor 41 is provided for preventing the swash plate 18 from substantially wobbling. Thus, the restricting surface 43 and the restricted surface 44 can be freely designed in setting shape, size and location in comparison with the technique disclosed in Unexamined Japanese Patent Application Publication No. 2001-289159, in which a part of the compression reactive force transmitting portion (the second bracket 104 in
(2) The movement restrictor 41 is so constructed to change between the restricting state where the restricted surface 44 comes into contact with the restricting surface 43 by the slight wobble of the swash plate 18; and the non-restricting state where the restricted surface 44 is out of contact with the restricting surface 43 even when the swash plate 18 wobbles, in accordance with the variation of the inclination angle of the swash plate 18. Thus, in assembling the compressor 10, the elements of the link mechanism 19 in the swash plate 18 (specifically the spherical portion 23) and the elements of the link mechanism 19 in the lug plate 17 (specifically the first cam portion 24) are easily coupled to each other in a state where the movement restrictor 41 is in the non-restricting state. Namely, the above structure of the movement restrictor 41 facilitates the assembling work.
In a case where the movement restrictor 41 is constructed so as not to be in the non-restricting state at any inclination angle of the swash plate 18 (this case does not depart from the scope of the present invention), the spherical portion 23 needs to be inserted into the first cam portion 24 while the restricting surface 43 faces to the restricted surface 44 in the rotational direction R in assembling the compressor 10. Thus, the work for connecting the swash plate 18 to the lug plate 17 is a limited and troublesome procedure. In the present preferred embodiment, the spherical portion 23 is inserted into the first cam portion 24 in a state where the swash plate 18 is inclined substantially at the maximum inclination angle. Then, the inclination angle of the swash plate 18 is changed from its maximum so that the restricting surface 43 faces to the restricted surface 44 in the rotational direction R. Therefore, the work for connecting the swash plate 18 to the lug plate 17 becomes easy.
(3) The movement restrictor 41 is so constructed to be in the restricting state at the minimum inclination angle of the swash plate 18, at which the swash plate 18 is most likely to wobble. Thus, the swash plate 18 is more effectively prevented from substantially wobbling.
(4) The movement restrictor 41 is constructed so as to be in the non-restricting state at the approximately maximum inclination angle of the swash plate 18, at which the swash plate 18 is least likely to wobble. Thus, the movement restrictor 41 both prevents the swash plate 18 from substantially wobbling and facilitates the work for connecting its elements on the swash plate 18 to its elements on the lug plate 17.
(5) The restricting surface 43 and the restricted surface 44 are planes. It is easy to process planes and control their dimensions. Thus, the swash plate 18 is more effectively prevented from substantially wobbling.
(6) The protrusion 20b protrudes from the support portion 20 that supports the roller 22, and the restricted surface 44 is formed in the protrusion 20b. Thus, the movement restrictor 41 is made smaller in size in comparison with a case where an additional protrusion directly protrudes from the swash plate 18 toward the lug plate 17 for forming the restricted surface 44.
The restricting surface 43 is formed in the second cam portion 25 that forms the cam surface 25a. Thus, the movement restrictor 41 is made simple in structure in comparison with a case where an additional protrusion directly protrudes from the lug plate 17 toward the swash plate 18 for forming the restricting surface 43.
The following alternative embodiments are practicable according to the present invention.
As shown in
As shown in
As shown in
The present invention is applied to the compressor having the similar link mechanism as disclosed in Japanese Patent Application Publication No. 2001-289159. Namely, the link mechanism 19 is constituted of a pair of spherical portions formed in one of the lug plate 17 and the swash plate 18 and a pair of guide grooves formed in the other of the lug plate 17 and the swash plate 18.
The present invention is applicable to a wobble type variable displacement compressor.
The present examples and embodiments are to be considered as illustrative and not restrictive, and the invention is not to be limited to the details given herein but may be modified within the scope of the appended claims.
Number | Date | Country | Kind |
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2004-048552 | Feb 2004 | JP | national |
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Number | Date | Country | |
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20050186086 A1 | Aug 2005 | US |