Lubricating oil feeding mechanism in a swash type compressor
Lubricating oil feeding mechanism has an oil-collecting recess and an oil-supplying groove formed on the wall of the housing. The oil-collecting recess connects a gap defined between the through hole and the bolt to the oil-supplying groove, the gap being in the upper position with respect to a sliding part to be lubricated in the housing in an operating state of the mounted compressor. The oil-collecting recess extends from the gap in the circumferential direction of the drive shaft, and the oil-supplying groove upwardly extends toward the oil-collecting recess. The oil-supplying groove is arranged so as to guide lubricating oil to the sliding part. Lubricating oil adhered on the bolt can be collected to the oil-collecting recess via the gap, and is fed to the sliding part through the oil-supplying groove. Therefore, a large amount of lubricating oil in a swash plate chamber can be utilized to lubricate the sliding part.
1. Field of the Invention
The present invention relates to a swash type compressor and, more particularly, to an improved lubricating oil feeding mechanism for such compressors.
2. Description of the Related Art
In general, swash type compressors with variable or fixed displacement mechanism have a swash plate chamber to arrange a swash plate therein. The compressors also have a bearing for supporting a drive shaft coupled to the swash plate and a shaft seal for preventing refrigerant gas in the swash plate chamber from leaking outside. The bearing and the shaft seal are to be lubricated by lubricating oil contained in refrigerant gas in the swash plate chamber.
Japanese Utility Model Application Laid-Open Publication No. 57-112082 discloses a swash type compressor having a cylinder block forming cylinder bores and a swash plate chamber therein; a drive shaft rotatably supported on the cylinder block via radial bearings; a swash plate coupled to the drive shaft and arranged in the swash plate chamber; and pistons slidably arranged in the cylinder bores and operatively engaged with the swash plate via shoes in
Furthermore, Japanese Patent Application Laid-Open Publication No. 2005-171851 discloses a variable displacement swash type compressor having a front housing forming a shaft seal chamber therein; an oil-guiding passage formed on the front housing, the oil-guiding passage including an oil-guiding groove and a recess connected to the oil-guiding groove, the recess having a side wall; a aperture formed in the front housing, the aperture connecting the shaft seal chamber to the oil-guiding groove; a wall formed on the front housing, the wall protruding from the bottom surface of the recess so as to divide the recess into small areas in
In the conventional arts as mentioned above, some of the solutions are disclosed to conduct lubricating oil in the swash plate chamber toward a sliding part to be lubricated such as the shaft seal or the bearing. These solutions are, however, not sufficient in view of utilizing limited lubricating oil in the swash plate chamber more efficiently to obtain sufficient lubrication of the sliding part in the compressor. In general, lubricating oil in the swash plate chamber is splashed and circulated therein by the rotation of the swash plate during compressor operation. In such a state some amount of lubricating oil adheres to a side wall of the swash plate chamber, and then, flows downwardly along the side wall due to its own weight. The compressors as mentioned above are compressors which have mechanism for the collection of such lubricating oil flowing downwardly along the side wall. In this connection, the inventors have found a particularity of lubricating oil distribution in the swash plate chamber that a large amount of lubricating oil in the swash plate chamber tends to adhere to bolts arranged through the swash plate chamber to fasten each housing elements, due to the fact that it is easy for lubricating oil splashed and circulated by the rotation of the swash plate to collide with the bolts arranged in the area of the circulation of lubricating oil. In the compressors as mentioned above, such the lubricating oil adhered on the bolts cannot positively be used for the lubrication of the sliding part.
SUMMARY OF THE INVENTIONAn object of the present invention is to provide a lubricating oil feeding mechanism in a swash type compressor, which can efficiently conduct a large amount of lubricating oil in the swash plate chamber to the sliding part in the compressor so that the sliding part can become more reliable.
In accordance with an aspect of the present invention, there is provided a lubricating oil feeding mechanism in a swash type compressor having a housing comprising a plurality of housing elements, in which a swash plate chamber is formed for receiving a swash plate therein, and which defines a cylinder bore therein; a plurality of bolts arranged through the swash plate chamber and in through holes formed on a wall of the housing for fastening the housing elements to form the housing; a drive shaft rotatably supported by the housing, the drive shaft being coupled to the swash plate; a piston accommodated in the cylinder bore so as to define a compression chamber in the cylinder bore, the piston being coupled to the swash plate; and a suction chamber and a discharge chamber formed in the housing respectively, both being connectable to the compression chamber. The lubricating oil feeding mechanism comprises an oil-collecting recess and an oil-supplying groove formed respectively on a side wall surface being defined on the wall of the housing and facing the swash plate chamber. The oil-collecting recess connects a gap defined between the through hole and the bolt to the oil-supplying groove, the gap being in the upper position with respect to a sliding part to be lubricated in the housing in an operating state of the mounted compressor. The oil-collecting recess extends from the gap in the circumferential direction of the drive shaft. The oil-supplying groove extends upwardly toward the oil-collecting recess. The oil-supplying groove is arranged so that oil guided along the oil-supplying groove is led to the sliding part.
In the aspect of the present invention, lubricating oil adhered on the bolts is collected to the gap defined between the through holes and the bolts due to its own weight. The oil-collecting recess collects not only lubricating oil flowing downwardly on the side wall surface of the housing but also such lubricating oil gathered in the gap, and then feeds the lubricating oil collected therein by the oil-supplying groove. Lubricating oil guided to the oil-supplying groove is, then, led to the sliding part. Therefore, a large amount of lubricating oil in the swash plate chamber can efficiently be conducted to the sliding part of the compressor. Namely, this positive utilization of lubricating oil in the swash plate chamber enables the sliding part to be come more reliable during compressor operation.
Other features and advantages of the invention will be apparent from the following description taken in connection with the accompanying drawing wherein:
Referring to
The front housing 1 and cylinder block 2 have a central axial bore formed therein respectively for receiving a drive shaft 6 which is rotatably supported by a pair of radial bearings 7 and 9 provided in the central axial bore, wherein one end of which is further supported by a thrust bearing 8 provided in the central axial bore of the cylinder block 2. Furthermore, in the central axial bore, a shaft seal 11 is disposed between the drive shaft 6 and the front housing 1 in a certain space 10 outside the radial bearing 9 and prevents refrigerant gas in the swash plate chamber 12 from leaking outside. The drive shaft 6 is engaged with engine E as a motor of the vehicle at the other end thereof and can be driven by the engine E.
There are disposed a lug plate 15 and a swash plate 16 coupled to the lug plate 15 through a hinge mechanism 17 in the swash plate chamber 12. The lug plate 15 is fixed on the drive shaft 6 and is supported on a side wall 13 of the front housing 1 via a thrust bearing 14 provided therebetween. The swash plate 16 is supported on the drive shaft 6 slidably and movably in the direction along the axis thereof and is connected to the hinge mechanism 17 to be allowed to incline with respect to the axis of drive shaft 6. Therefore, the swash plate 16 rotates together with the lug plate 15 when the drive shaft 6 rotates, while the inclination of the swash plate 16 changes in accordance with the pressure control of the swash plate chamber 12. It is here noted that each of the radial bearings 7 and 9, the thrust bearings 8 and 14, and the shaft seal 11 represents a sliding part in accordance with the definition of the present invention.
As can be seen from
A compression chamber 21 is defined in the cylinder bore 18 on the right side of
As each piston 19 moves from the top dead center to the bottom dead center in the associated cylinder bore 18, the refrigerant gas in the suction chamber 22 is sucked up into the compression chamber 21 through an associated suction port 24 formed on the valve plate unit 4, causing an associated suction valve 25 disposed in the valve plate unit 4 to flex to an open position. Further, as each piston 19 moves from the bottom dead center to the top dead center in the associated cylinder bore 18, the refrigerant gas in the compression chamber 21 is compressed to a certain pressure level and is discharged out into the discharge chamber 23 through an associated discharge port 26 formed on the valve plate unit 4, causing an associated discharge valve 27 disposed in the valve plate unit 4 to flex to an open position.
The suction chamber 22 is connected with the swash plate chamber 12 by a release passage 28 which is formed in the cylinder block 2 and the valve plate unit 4. The discharge chamber 23 is connected with the swash plate chamber 12 by a supply passage 29 which is formed in the cylinder block 2, the valve plate unit 4 and the rear housing 3. The supply passage 29 is regulated by a displacement control device 31 including a control valve 30, which is accommodated in the rear housing 3.
Therefore, the pressure in the swash plate chamber 12 can be controlled by the control valve 30. When the control valve 30 opens the supply passage 29, the refrigerant gas in the discharge chamber 23 is permitted to flow into the swash plate chamber 12 via the supply passage 29 and to make the pressure in the swash plate chamber 12 be high. On the other hand, when the control valve 30 closes the supply passage 29, the refrigerant gas in the discharge chamber 23 is not permitted to flow into the swash plate chamber 12 via the supply passage 29. Thus, the refrigerant gas in the swash plate chamber 12 flows out to the suction chamber 22. This makes the pressure in the swash plate chamber 12 be low. The inclination of the swash plate 16 is determined by the pressure difference between the pressure in the swash plate chamber 12 and the pressure in the compression chamber 21. Therefore, the displacement of the compressor can be controlled based on the inclination of swash plate 16.
As shown in
As shown in
As shown in
The oil-collecting recess 35 is formed so as to have an arched shape and extends from the gap 321a in the rotational direction of the drive shaft 6 as indicated by an arrow shown in
On the other hand, the oil-collecting recess 36 is formed so as to have an arched shape and extends from the gap 321b in the opposite direction of the rotational direction of the drive shaft 6. A sub oil-collecting recess 40 is formed on the side wall surface 34 and is connected with the gap 321b in the opposite side of the oil-collecting recess 36 with respect to the gap 321b. The sub oil-collecting recess 40 is formed so as to have an arched shape and extends, with a relatively short length as compared with the oil-collecting recess 36, from the gap 321b in the rotational direction of the drive shaft 6. Further, the oil-collecting recesses 35, 36 and the sub oil-collecting recesses 39, 40 extend so that their width is substantially the same as the diameter of the first bore 32 along the longitudinal direction thereof.
The oil-supplying groove 37 extends in the radial direction of the drive shaft 6 and is, at the top end thereof, connected to a forward position of the oil-collecting recess 35 in the rotation direction of the drive shaft 6. As can be seen in
As shown in
The operation of the compressor having the lubricating oil feeding mechanism will now be described.
When the drive shaft 6 of the compressor is rotated by the engine E, the swash plate 16 is also rotated for receiving rotational power of the drive shaft 6 through the lug plate 15 and the hinge mechanism 17. Rotation of the swash plate 16 gets each of the piston 19 to be reciprocated in the cylinder bore 18 so that refrigerant gas in the suction chamber 22 is sucked into the compression chamber 21, and then refrigerant gas in the compression chamber 21 is compressed and is discharged into the discharge chamber 23.
The hinge mechanism 17 serves as an agitator so as to agitate or splash lubricating oil contained in refrigerant gas in the swash plate chamber 12 while the swash plate 16 is rotating because the hinge mechanism 17 corresponds to a portion which partially protrudes from the lug plate 15 and the swash plate 16. When the swash plate 16 is rotated, the hinge mechanism 17 makes lubricating oil stayed in/under the swash plate chamber 12 be circulated therein. By that agitation, some amount of the circulated lubricating oil in the swash plate chamber 12 adheres to the side wall 13, an inner peripheral surface of the swash plate chamber 12 and an end face of the cylinder block 2.
On the other hand, however, a large amount of lubricating oil in the swash plate chamber 12 tends to adhere on the bolts 5 arranged through the swash plate chamber 12, due to the fact that it is easy for lubricating oil splashed and circulated by the rotation of the hinge mechanism 17 to collide with the bolts 5 as an obstacle in the direction of the circulation of lubricating oil. The lubricating oil adhered on the bolts 5 largely drops downwardly toward the bottom of the swash plate chamber 12 directly due to its own weight. The lubricating oil adhered on the bolt 5, a position of which is located near the side wall, tends to drop into the gap 321 due to surface tension.
Lubricating oil gathered in the gaps 321a, 321b flows by its own weight and is led to the oil-collecting recesses 35, 36. Besides, lubricating oil adhered on the side wall surface 34 of the side wall 13 flows downwardly by its own weight and a part of that is collected by the oil-collecting recesses 35, 36, the sub oil-collecting recesses 39, 40 and oil-supplying grooves 37, 38 efficiently due to their configuration. Here, lubricating oil gathered in the sub oil-collecting recesses 39, 40 is led to the oil-collecting recesses 35, 36 through the gaps 321a, 321b respectively. After being collected into the oil-collecting recesses 35, 36, lubricating oil flows in the circumferential direction of the drive shaft 6 along the oil-collecting recesses 35, 36 by its own weight. The oil-supplying grooves 37, 38 are formed further deeper than the oil-collecting recesses 35, 36 whereby feeding lubricating oil from the oil-collecting recesses 35, 36 to the oil-supplying groove 37, 38 can be ensured.
In addition, the revolution of the hinge mechanism 17 with the rotation of the swash plate 16 makes not only lubricating oil in the swash plate chamber 12 be splashed or be circulated but also lubricating oil adhere on the side wall surface 34, in the oil-collecting recesses 35, 36, and in the sub oil-collecting recesses 39, 40 as well as lubricating oil gathered in the gap 321a, 321b flow in the rotational direction of the drive shaft 6 by gas streams accompanied with the circulation of lubricating oil in the swash plate chamber 12. For this reason, lubricating oil adhered on the side wall surface 34 and gathered in the gaps 321a, 321b can easily be collected in the oil-collecting recesses 35, 36 and the sub oil-collecting recesses 39, 40. Especially, when the drive shaft 6 is rotated in the direction as indicated by the arrow shown in
Lubricating oil supplied in the oil-supplying grooves 37, 38 are further guided to the certain space 10 through the oil-supplying apertures 41, 42 so that the certain space 10 can be filled with a large amount of lubricating oil. Therefore, the shaft seal 11 can sufficiently be lubricated. Also, the radial bearing 9 can sufficiently be lubricated. This makes the sliding part such as the shaft seal 11 and the radial bearing 9 much more durable.
The first embodiment of the present invention has the following advantages.
The oil-collecting recesses 35, 36 is connected with the gap 321a, 321b so that lubricating oil collided with the bolts 5 in the route of the circulation of lubricating oil caused by the revolution of the hinge mechanism 17, a portion of which is located near the gap 321a, 321b can effectively be collected into the oil-collecting recesses 35, 36. Therefore, such the lubricating oil adhered on the bolts 5 can positively be utilized for lubrication of the sliding part.
The oil-collecting recesses 35, 36 are arranged extending in the circumferential direction of the drive shaft 6. Therefore, lubricating oil gathered in the gaps 321a, 321b and adhered on the side wall surface 34 can efficiently be collected by the oil-collecting recesses 35, 36. As a result, lubrication for the sliding part can be ensured.
The oil-supplying groove 37 is connected to the oil-collecting recess 35 at the forward position in the rotational direction of the drive shaft 6 with respect to the gap 321a. Due to the revolution of the hinge mechanism 17 with the rotation of the swash plate 16, lubricating oil flows in the rotational direction of the drive shaft 6 led by gas streams accompanied with the circulation of lubricating oil in the swash plate chamber 12, thus, lubricating oil in the oil-collecting recess 35 and lubricating oil below the oil-collecting recess 35 can more easily be fed to the oil-supplying groove 37.
While the oil-collecting recess 35 is arranged extending downwardly from the gap 321a in the rotational direction of the drive shaft 6, the oil-collecting recess 36 is arranged extending downwardly from the gap 321b in the opposite direction of the rotational direction of the drive shaft 6. Therefore, lubricating oil collecting ability of the bolts 5 can be ensured due to the own weight of lubricating oil.
The lubricating oil feeding mechanism comprising the oil-collecting recesses 35, 36 and the oil-supplying grooves 37, 38 can easily be provided due to the fact that a recess and a groove have only to be formed on the side wall 13.
The present invention may be alternatively embodied in the following forms:
Since stress concentration is likely to take place around the first bore 32 under strong fastening power by the bolts 5, in this case, it may be difficult in view of the strength required for the front housing 1 that an oil-collecting recess 50 is formed being connected to all around the circumference of the first bore 32 with a cutting process. According to the second embodiment, however, the connection groove 51 connected with the first bore 32 is arranged narrower than the diameter of the first bore 32. Therefore, the stress concentration to be generated around the first bore 32 can be reduced.
According to the fourth embodiment, lubricating oil adhered on the bolt 5a flows to the first sub oil-collecting recess 56 through the gap 321a. Also, lubricating oil adhered on the bolt 5c flows to the oil-collecting recess 55 through the gap 321c together with lubricating oil flowing in the first sub oil-collecting recess 56. On the other hand, the second sub oil-collecting recess 57 collects lubricating oil adhering on the side wall surface 34 and guides the lubricating oil to the oil-collecting recess 55 through the gap 321a, the first sub oil-collecting recess 56 and the gap 321c in turn. The oil-collecting recess 55 as well as the first sub oil-collecting 56 can collect lubricating oil adhering on the side wall surface 34 as same as in the first embodiment described above.
Lubricating oil collected in the oil-collecting recess 55 is guided along the oil-supplying groove 58 and is led to the certain space 10 shown in
The present invention may further be embodied in the following forms:
In addition, it is possible to omit the sub oil-collecting recesses 39, 40 in the first embodiment, and also possible to omit the sub oil-collecting recess 57 in the fourth embodiment.
In the first embodiment, the oil-supplying grooves 37, 38 may be connected to the oil-collecting recesses 35, 36 at approximately the middle point thereof respectively.
In the first embodiment, it is not necessarily required to make the oil-supplying grooves 37, 38 deeper than the oil-collecting recesses 35, 36. it may be implemented that both of the grooves 37, 38 and recesses 35, 36 have the same depth.
In the fourth embodiment, in addition to the lubricating oil feeding mechanism described before, a first sub oil-collecting recess connects the gap 321b to a gap 321d which is in the upper position with respect to the shaft seal 11 as sliding part to be lubricated in the housing in an operating state of the mounted compressor. Also, a second sub oil-collecting recess is connected to the gap 321b, and an oil-collecting recess is connected to the gap 321d, the oil-collecting recess being connected to an oil-supplying groove. Although both of those mechanism are adopted together so as to collect lubricating oil gathered in the gaps 321a, 321b, 321c and 321d, only one of the described mechanism might be used to improve the lubricativity.
In the fourth embodiment, the oil-supplying groove 58 is connected to the sub oil-collecting recess 56. In this embodiment, the sub oil-collecting recess 56 represents an oil-collecting recess, and the oil-collecting recess 55 represents a sub oil-collecting recess.
In each embodiment described above, the shape of each oil-collecting recess 35, 36, 50 and 55, each sub oil-collecting recess 39, 40, 54 and 56, and the connection groove 51 is formed arched. It may, however, be possible to form each recess and the groove mentioned above to a straight shape or a wave shape.
The present invention may be embodied in compressors other than the compressors of
Finally, it will be understood by those skilled in the art that the foregoing description is of preferred embodiments of the disclosed invention, and that various changes and modifications may be made to the present invention without departing from the spirit and scope thereof.
Claims
1. Lubricating oil feeding mechanism in a swash type compressor having:
- a housing comprising a plurality of housing elements, in which a swash plate chamber is formed for receiving a swash plate therein, and which defines a cylinder bore therein;
- a plurality of bolts arranged through the swash plate chamber and in through holes formed on a wall of the housing for fastening the housing elements to form the housing;
- a drive shaft rotatably supported by the housing, the drive shaft being coupled to the swash plate;
- a piston accommodated in the cylinder bore so as to define a compression chamber in the cylinder bore, the piston being coupled to the swash plate; and
- a suction chamber and a discharge chamber formed in the housing respectively, both being connectable to the compression chamber;
- the lubricating oil feeding mechanism comprising an oil-collecting recess and an oil-supplying groove formed respectively on a side wall surface being defined on the wall of the housing and facing the swash plate chamber,
- wherein the oil-collecting recess connects a gap defined between the through hole and the bolt to the oil-supplying groove, the gap being in the upper position with respect to a sliding part to be lubricated in the housing in an operating state of the mounted compressor, wherein the oil-collecting recess extends from the gap in the circumferential direction of the drive shaft, and wherein the oil-supplying groove extends upwardly toward the oil-collecting recess,
- wherein the oil-supplying groove is arranged so that oil guided along the oil-supplying groove is led to the sliding part.
2. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess extends from the gap in the rotational direction of the drive shaft.
3. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess extends from the gap in the opposite direction of the rotational direction of the drive shaft.
4. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess has a connection groove as a part thereof, the connection groove connecting the gap to the rest of the oil-collecting recess,
- wherein the width of the connection groove is narrower than the diameter of the through hole.
5. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess further extends downwardly from the through hole in an operating state of the mounted compressor.
6. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess extends so that the width of the oil-collecting recess is substantially the same as the diameter of the through hole along the longitudinal direction of the oil-collecting recess.
7. Lubricating oil feeding mechanism according to claim 1, further comprising a sub oil-collecting recess extending from the gap in the opposite direction of the extending direction of the oil-collecting recess with respect to the gap from which the oil-collecting recess extends.
8. Lubricating oil feeding mechanism according to claim 7, wherein the sub oil-collecting recess extends over two of the gaps to connect the gaps to each other.
9. Lubricating oil feeding mechanism according to claim 1, wherein the oil-supplying groove is formed deeper than the oil-collecting recess to promote oil flow from the oil-collecting recess to the groove.
10. Lubricating oil feeding mechanism according to claim 1, wherein the oil-collecting recess has a first oil-collecting recess and a second oil-collecting recess, the first oil-collecting recess extending from one of the gaps in the rotational direction of the drive shaft, the second oil-collecting recess extending from another one of the gaps in the opposite direction of the rotational direction of the drive shaft,
- wherein the oil-supplying groove has a first oil-supplying groove and a second oil-supplying groove, the first oil-supplying groove being connected to the first oil-collecting recess at a forward position in the rotational direction of the drive shaft with respect to the gap connected to the first oil-collecting recess, the second oil-supplying groove being connected to the second oil-collecting recess at a backward position in the rotational direction of the drive shaft with respect to the gap connected to the second oil-collecting recess.
11. Lubricating oil feeding mechanism in the swash type compressor according to claim 1, wherein the housing elements include a front housing in which the oil-collecting recess and the oil-supplying groove are formed respectively, wherein the front housing supports the sliding part, and
- the lubricating oil feeding mechanism includes a oil-supplying aperture formed in the front housing,
- wherein the oil-supplying aperture is connected to the oil-supplying groove and extends toward the sliding part so that oil guided along the oil-supplying groove and the oil-supplying aperture is led to the sliding part.
12. Lubricating oil feeding mechanism in the swash type compressor according to claim 11, the compressor having a shaft seal disposed between the front housing and the drive shaft to prevent refrigerant gas in the swash plate chamber from leaking outside;
- wherein the sliding part is the shaft seal.
Type: Application
Filed: Sep 27, 2007
Publication Date: Apr 3, 2008
Inventors: Takayuki Imai (Kariya-shi), Masakazu Murase (Kariya-shi), Hiroki Nagano (Kariya-shi), Naoya Yokomachi (Kariya-shi), Tetsuhiko Fukanuma (Kariya-shi)
Application Number: 11/904,945
International Classification: F04B 1/12 (20060101); F01M 11/04 (20060101);