The present invention relates to an axial piston motor.
Conventionally, there has been an axial piston motor described in Japanese Patent No. 4828371 (Patent Document 1). As illustrated in
Incidentally, when the piston 103 is reciprocally moved, heat caused by friction with the piston 103 is generated on an inner surface of the cylinder 102a. A heating value thereof depends on a contact pressure between the cylinder 102a and the piston 103.
In a conventional low speed rotation specification, since centrifugal force (illustrated by arrows) acted on the piston 103 and the shoe 105 is small, the contact pressure is small and the heating value is also small. Accordingly, only by securing a small clearance between the cylinder 102a and the piston 103 for causing the operation oil to flow, the inner surface of the cylinder 102a can be sufficiently cooled by the operation oil escaped into the clearance.
Currently, in construction machinery or industrial machinery, because of weight reduction and space saving of a driving device, higher pressure and higher speed thereof are in progress. As a result, it is desirable that a hydraulic device can be used at high speed rotation.
In a case where the cylinder block 102 is rotated at a high speed, the centrifugal force (illustrated by the arrows) affects the contact pressure, and the heating value generated on the inner surface of the cylinder 102a becomes large. Accordingly, the operation oil escaped into the clearance cannot sufficiently cool the inner surface of the cylinder 102a. Further, as the centrifugal force increases, the piston 103 is pressed outward in a radial direction, and a width of the clearance on an outer side of the piston 103 in the radial direction is narrowed.
As a result, an amount of operation oil passing through the outer side of the piston 103 in the radial direction is reduced, and seizure of at least one of the piston 103 and the cylinder 102a is generated. On the other hand, when the clearance is widened to secure the amount of operation oil passing through the outer side of the piston 103 in the radial direction, an amount of operation oil leaked from the cylinder 102a increases, which deteriorates the performance of the device.
Accordingly, an object of the present invention is to provide an axial piston motor which is capable of preventing seizure of a piston and seizure of a cylinder and operating a cylinder block at high speed rotation and which is capable of preventing deterioration of performance due to an increase in an amount of operation oil leaked from the cylinder.
In order to accomplish the above object, there is provided, an axial piston motor comprising:
a housing;
a drive shaft which is mounted to the housing so as to be freely rotatable;
a cylinder block which is fixed to the drive shaft and has a plurality of cylinders arrayed in a circumferential direction;
a plurality of pistons which is fitted into the plurality of cylinders so as to be capable of freely advancing and retreating; and
a swash plate which supports the plurality of pistons by a tiltable surface relative to the drive shaft, wherein
on an inner surface of the housing, a nozzle for jetting operation oil is provided at a position opposite to an outer circumferential surface of the cylinder block.
According to the axial piston motor of this invention, on the inner surface of the housing, the nozzle for jetting operation oil is provided at the position opposite to the outer circumferential surface of the cylinder block. With this configuration, by spraying the operation oil from the nozzle to the outer circumferential surface of the cylinder block during rotation of the cylinder block, this operation oil can remove frictional heat generated by sliding between the piston and the cylinder, and seizure of the piston and seizure of the cylinder can be prevented.
Therefore, since the seizure of the piston and the seizure of the cylinder can be prevented, the cylinder block can be operated at high speed rotation. Further, since the seizure of the piston and the seizure of the cylinder can be prevented without increasing a clearance between the piston and the cylinder, deterioration of performance due to an increase in an amount of the operation oil leaked from the cylinder can be prevented.
In the axial piston motor of one embodiment, the outer circumferential surface of the cylinder block has a high temperature zone which has a temperature higher than a predetermined threshold value during rotation of the cylinder block, and
the nozzle is opposed to the high temperature zone of the cylinder block.
Here, the threshold value is a value in which seizure of at least one of the piston and the cylinder can occur between during the rotation of the cylinder block.
According to the axial piston motor of this embodiment, since the nozzle is opposed to the high temperature zone of the cylinder block, the operation oil can be sprayed from the nozzle to the high temperature zone, and the seizure of the piston and the seizure of the cylinder can be reliably prevented.
In the axial piston motor of one embodiment, as viewed in an axial direction of the drive shaft, the high temperature zone of the cylinder block is in a set range where a center angle is from +40° to −40° when a bottom dead center of the piston is selected as a standard.
Here, a positive direction of the center angle is a rotation direction of the cylinder block.
According to the axial piston motor of this embodiment, though the high temperature zone becomes a zone where seizure can occur the most, the high temperature zone is in the set range. Therefore, the seizure can be reliably prevented by the jetting of the operation oil from the nozzle.
In the axial piston motor of one embodiment, as viewed in the axial direction of the drive shaft, the nozzle is disposed outside the position at which the piston is at the bottom dead center in a radial direction, and
as viewed in the axial direction of the drive shaft, a jetting direction of the nozzle intersects the set range of the cylinder block.
According to the axial piston motor of this embodiment, since the nozzle is disposed outside the position where the piston is at the bottom dead center in the radial direction, and the jetting direction of the nozzle intersects the set range of the cylinder block, the nozzle can be disposed at the appropriate position.
In the axial piston motor of one embodiment, the axial piston motor further comprises
a plug screwed to the housing in a penetrated state, wherein
the plug has the nozzle.
According to the axial piston motor of this embodiment, since the plug is screwed to the housing and the plug has the nozzle, the attachment and removal of the nozzle to and from the housing can be easily performed by attaching and removing the plug to and from the housing.
In the axial piston motor of one embodiment, the housing has a pair of main passages, which is connected to the cylinder and supplies and discharges the operation oil to the cylinder and
a flushing valve, which is switched by pressure difference between the pair of main passages and guides the operation oil passing through the main passage on a low pressure side to the nozzle, is provided at the housing.
According to the axial piston motor of this embodiment, since the flushing valve is provided at the housing, the motor can be made compact.
According to the axial piston motor of this invention, on the inner surface of the housing, the nozzle for jetting operation oil is provided at the position opposite to the outer circumferential surface of the cylinder block. With this configuration, the seizure of the piston and the seizure of the cylinder can be prevented, the cylinder block can be operated at high speed rotation, and deterioration of performance due to the increase in the amount of the operation oil leaked from the cylinder can be prevented.
Hereinafter, this invention will be described in detail by way of embodiments thereof illustrated in the accompanying drawings.
The cylinder block 4 has a plurality of cylinders 40 arrayed in a circumferential direction. A plurality of pistons 5 is fitted into this plurality of cylinders 40 so as to be capable of freely advancing and retreating.
A tip part of the piston 5 is formed in a spherical shape and coupled to a shoe 6. This shoe 6 is supported by a swash plate 7 positioned relatively to the housing 1. This swash plate 7 has a tiltable surface relative to the drive shaft 3, and supports the plurality of pistons 5 by the tilted surface. A tilting angle of this swash plate 7 relative to the drive shaft 3 is adjusted by a first control piston 81 and a second control piston 82.
The housing 1 has a cover 10 covering an end part side of the drive shaft 3. A first main passage 11 and a second main passage 12, which are connected to the cylinder 40 and supply and discharge operation oil to the cylinder 40, are provided at this cover 10.
A valve plate 9 is mounted on an end surface of the cover 10 on the cylinder block 4 side. This valve plate 9 has an arc-shaped first port 91 and an arc-shaped second port 92, and the first port 91 and the second port 92 are formed symmetrically.
A port 40a for supplying and discharging the operation oil to an inside of the cylinder 40 is formed at a bottom part of each cylinder 40. An end surface of the cylinder block 4 is in contact with the valve plate 9.
The first main passage 11 of the cover 10, the first port 91 of the valve plate 9, and the port 40a of the predetermined cylinder 40 communicate with one another. The second main passage 12 of the cover 10, the second port 92 of the valve plate 9, and the port 40a of the predetermined cylinder 40 communicate with one another.
Then, when the operation oil is supplied from the first main passage 11, the operation oil flows into the predetermined cylinder 40 via the first port 91. As a result, the piston 5 reciprocates, and in this moving of piston 5 reciprocally, the cylinder block 4 and the drive shaft 3 are rotated in one direction. After that, the operation oil within the cylinder 40 is discharged from the second main passage 12 via the second port 92. A pressure within the first main passage 11 on a supply side is higher than a pressure within the second main passage 12 on a discharge side.
On the other hand, when the operation oil is supplied from the second main passage 12, the cylinder block 4 and the drive shaft 3 are rotated in another direction. After that, the operation oil within the cylinder 40 is discharged from the first main passage 11.
A nozzle 21 for jetting the operation oil is arranged on an inner surface of the housing 1 and is provided at a position opposite to an outer circumferential surface of the cylinder block 4. This nozzle 21 is provided at a tip part of a plug 20. This plug 20 is screwed to the housing 1 in a penetrated state.
The nozzle 21 faces a nozzle passage 15 provided at the housing 1, and the nozzle passage 15 is connected to a flushing valve 30 provided at the cover 10 of the housing 1. This flushing valve 30 is connected to a first sub-passage 13 communicated with the first main passage 11 and is connected to a second sub-passage 14 communicated with the second main passage 12. This flushing valve 30 is switched by pressure difference between the first main passage 11 and the second main passage 12, and the operation oil passing through the main passage on a low pressure side is guided to the nozzle 21 via the nozzle passage 15.
As illustrated in
As viewed in an axial direction of the drive shaft 3, the high temperature zone Z of the cylinder block 4 is in a set range R where a center angle is from +40° to −40° when a position L, at which the piston 5 is at a bottom dead center, is selected as a standard. Here, a positive direction of the center angle is a rotation direction of the cylinder block 4. The bottom dead center of the piston 5 is a position where the piston 5 is protruded the most from the cylinder 40.
Most specifically, a line connecting a center of the piston 5 and a center of the drive shaft 3, which represents the bottom dead center, is selected as a standard line B, the set range R is a range where the center angle is from +40° to −40° around the standard line B.
The nozzle 21 is opposed to the high temperature zone Z of the cylinder block 4. Specifically speaking, as viewed in the axial direction of the drive shaft 3, the nozzle 21 is disposed outside the position L at which the piston 5 is at the bottom dead center in a radial direction. As viewed in the axial direction of the drive shaft 3, a jetting direction of the nozzle 21 intersects the set range R of the cylinder block 4. As viewed in the axial direction of the drive shaft 3, the jetting direction of the nozzle 21 coincides with a radial direction of the cylinder block 4 (the standard line B).
The spool 31 can be situated at a first position S1, a second position S2, and a third position S3. The first position S1 is a neutral position, and the first port P1 and the second port P2 are not connected to the third port P3 in the neutral position. At the second position S2, the second port P2 is connected to the third port P3. At the third position S3, the first port P1 is connected to the third port P3.
Then, in a case where high pressure operation oil is supplied to the first main passage 11 and low pressure operation oil is discharged from the second main passage 12, the spool 31 is switched from the first position S1 to the second position S2 by a differential pressure between the high pressure operation oil in the first sub-passage 13 and the low pressure operation oil in the second sub-passage 14, and the second sub-passage 14 communicates with the nozzle passage 15. With this configuration, the low pressure operation oil in the second sub-passage 14 can be jetted from the nozzle 21 to the motor unit 50.
On the other hand, in a case where high pressure operation oil is supplied to the second main passage 12 and low pressure operation oil is discharged from the first main passage 11, the spool 31 is switched from the first position S1 to the third position S3 by a differential pressure between the high pressure operation oil in the second sub-passage 14 and the low pressure operation oil in the first sub-passage 13, and the first sub-passage 13 communicates with the nozzle passage 15. With this configuration, the low pressure operation oil in the first sub-passage 13 can be jetted from the nozzle 21 to the motor unit 50.
The first and second control pistons 81, 82 (illustrated in
In the above-structured axial piston 5 motor, on the inner surface of the housing 1, the nozzle 21 for jetting operation oil is provided at the position opposite to the outer circumferential surface of the cylinder block 4. With this configuration, by spraying the operation oil from the nozzle 21 to the outer circumferential surface of the cylinder block 4 during the rotation of the cylinder block 4, this operation oil can remove frictional heat generated by the sliding between the piston 5 and the cylinder 40, and seizure of the piston 5 and seizure of the cylinder 40 can be prevented.
Therefore, since the seizure of the piston 5 and the seizure of the cylinder 40 can be prevented, the cylinder block 4 can be operated at high speed rotation. Further, since the seizure of the piston 5 and the seizure of the cylinder 40 can be prevented without increasing a clearance between the piston 5 and the cylinder 40, deterioration of performance due to an increase in an amount of the operation oil leaked from the cylinder 40 can be prevented.
Further, since the nozzle 21 is opposed to the high temperature zone Z of the cylinder block 4, the operation oil can be sprayed from the nozzle 21 to the high temperature zone Z, and the seizure of the piston 5 and the seizure of the cylinder 40 can be reliably prevented.
Further, though the high temperature zone Z becomes a zone where seizure can occur the most, the high temperature zone Z is in the set range R. Accordingly, the seizure can be reliably prevented by the jetting of the operation oil from the nozzle 21.
Further, the nozzle 21 is disposed outside in the radial direction of the position L at which the piston 5 is at the bottom dead center, and the jetting direction of the nozzle 21 intersects the set range R of the cylinder block 4. Accordingly, the nozzle 21 is disposed at the appropriate position.
Further, the plug 20 is screwed to the housing 1, and the plug 20 has the nozzle 21. Accordingly, the attachment and removal of the nozzle 21 to and from the housing 1 can be easily performed by attaching and removing the plug 20 to and from the housing 1.
Further, since the flushing valve 30 is provided at the housing 1, the motor can be made compact.
It should be noted that this invention is not limited to the aforementioned embodiment. The numbers of the piston 5 and the cylinder 40 may be increased and decreased. The number of the nozzle 21 may be increased and decreased.
Further, in the above-described embodiment, the set range R of the cylinder block 4 is a range where the center angle is from +40° to −40° around the standard line B. However, the set range R may be a range where the center angle is from +15° to −15° around the standard line B. With this configuration, the operation oil can be sprayed at pinpoint from the nozzle 21 to an area of the cylinder block 4 where it is highly possible that the seizure occurs.
Further, in the above-described embodiment, as viewed in the axial direction of the drive shaft 3, the jetting direction of the nozzle 21 coincides with the radial direction of the cylinder block 4. However, as long as the jetting direction of the nozzle 21 intersects the set range R, the jetting direction may be tilted in the radial direction of the cylinder block 4. Needless to say, a specific numerical value of the set range R is not limited to this embodiment, and designs can be modified.
Further, in the above-described embodiment, on the plane surface including the nozzle 21 and the axis of the drive shaft 3, the jetting direction of the nozzle 21 coincides with the direction (the radial direction) orthogonal to the axis of the drive shaft 3. However, as illustrated in
Further, in the above-described embodiment, the nozzle 21 is a part of the plug 20. However, the nozzle 21 may be directly formed at the housing 1.
In the above-described embodiment, the nozzle may be opposed to a zone other than the high temperature zone. The high temperature zone may be a range other than the range where the center angle is from +40° to −40°. The nozzle may be disposed outside a position other than the position where the piston is at the bottom dead center in the radial direction. The nozzle may be provided at a part other than the plug. The flushing valve may be omitted.
Number | Date | Country | Kind |
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2012-285032 | Dec 2012 | JP | national |
Filing Document | Filing Date | Country | Kind |
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PCT/JP2013/081730 | 11/26/2013 | WO | 00 |