The present invention relates to a bearing that rotatably supports a rotating shaft via a bearing pad and that is supplied with a lubricant oil a space between the bearing pad and the rotating shaft and also relates to the bearing pad.
A tilting pad bearing and a thrust pad bearing, each of which configures the bearing surface with multiple independent bearing pads, have an advantage of rapidly absorbing vibration of rotating shafts. Due to this advantage, bearings of these types have been broadly applied to rotating machine, such as a steam turbine and a gas turbine. In recent years, such rotating machine has cherished heightening of the output and lowering of the loss than ever. For this purpose, bearing loss needs to be suppressed by reducing the size of the bearing that bears the rotating shaft of the rotating machine. However, it is sure that a small bearing can suppress bearing loss, but the resultant small pressed area of the bearing increases the bearing load (weight on the bearing per unit area) to raise the temperature of the bearing pads.
While the rotating machine is working, the lubricant oil between the rotating shaft and the pads evolves heat generated by shear force, and each bearing pad, if being a journal bearing, becomes hotter towards the inner surface close to the rotating shaft and becomes also hotter towards the downstream of the rotating direction of the rotating shaft. This means that the bearing pad has an inner temperature difference and would become deformed due to differential expansion (differential thermal expansion). For example, in a tilting pad journal bearing, when each tilting pad becomes hotter at a portion closer to the inner circumference side nearer to the rotating shaft and thereby has an internal temperature difference between the inner circumference side and the outer circumference side, the tilting pad becomes deformed so as to increase the radius of curvature opposing to the rotating shaft, so that the bearing has a degraded capability of dealing with load.
Specifically, the tilting pad journal bearing has tilting pads each of which has an inner circumference surface (supporting surface) opposing to the outer circumference surface (supported surface) of the rotating shaft, and a lubricant oil film is formed at a space between the opposing surfaces. The presence of the lubricant oil film enables the bearing to smoothly support the rotating shaft.
If a tilting pad undergoes thermal deformation to have an increased radius of curvature, the space is widened more than needed at the inlet and exit portions to make it impossible to retain the oil film. For this reason, the oil film is entirely thinner. However, a thin lubricant oil further evolves heat.
Consequently, the temperature of the entire tilting pad is elevated to further deform the tilting pad, and finally, the bearing comes into contact with the rotating shaft (so that the bearing becomes incapable of loading the rotating shaft). Accordingly, the bearing has a degraded capability of dealing with the load.
Furthermore, deformation of a tilting pad affects the dynamic stability of the tilting pad. Namely, the attenuation coefficient lowers and therefore the tilting pad fails to rapidly absorb the vibration of the rotating shaft.
As a solution to the above, there is proposed a technique of forming a conduit penetrating the bearing pad from the front end surface to the rear end surface and cooling the entire bearing pad by a low-temperature additional oil flowing through the conduit (see Japanese Patent Publication No. 2009-063015, hereinafter “JP 2009-063015”).
As another solution, there is provided a technique of suppressing deformation caused by internal temperature difference by using material having a high thermal conductivity, such as Chromium copper.
However, the technique of JP 2009-063015 does not have a significant differential pressure between the front end surface and the rear end surface, and does require a pump to let the low-temperature additional oil flow through the inner conduit, separately from a pump for the lubricant oil supply, which is however not described in JP 2009-063015. In addition, the technique also requires preparation of the low-temperature additional oil separately from the lubricant oil.
Accordingly, the technique of JP 2009-063015 bears an increase in both production costs and running costs.
Since material having a high thermal conductivity is extremely expensive, a technique using such material with a high thermal conductivity for a bearing pad leads to a rise in production cost.
With the foregoing problems in view, the object of the present invention is to provide a bearing and a bearing pad that are free from an increase in cost and that suppress deformation of the bearing pad.
(1) To attain the above object, there is provided a bearing that rotatably supports a rotating shaft via one or more bearing pads and that is supplied with a lubricant oil to a space between the bearing pads and a supported surface of the rotating shaft, wherein: at least one of the bearing pads comprises a conduit that extends from a first aperture formed on a high temperature zone of a sliding surface opposing to the supported surface in a direction apart from the supported surface and that reaches a second aperture; each of the bearing pads is tiltable towards a rotating direction of the rotating shaft; the high temperature zone is positioned at a pad rear portion in the downstream region of the sliding surface with respect to the rotating direction of the shaft, and the second aperture is positioned on a pad forward portion upstream of the first aperture with respect to the rotating direction; and the conduit is a flow path having the first aperture as an inlet and the second aperture as an exit and having a differential pressure letting the lubricant oil flowing therethrough.
(2) As another preferable feature, the high temperature zone may lie within a range of 70-100% of a length of the sliding surface from an upstream edge of the sliding surface with respect to the rotating direction.
(3) As an additional preferable feature, the second aperture may be arranged on a back surface that is an opposite side of the sliding surface.
(4) As a further preferable feature, the second aperture may be arranged on a front surface pointing upstream of the rotating direction.
(5) As a still further preferable feature, the supported surface may be a circumference surface along a radius direction of the rotating shaft.
(6) As a still preferable feature, the rotating shaft may include a thrust collar That extends outward in a radius direction of the rotating shaft; and the supported surface may be an end surface of the thrust collar toward an axis direction of the rotating shaft.
(7) To attain the above feature, there is provided a bearing pad that rotatably supports a rotating shaft and that is supplied with a lubricant oil to a space between the bearing pad and a supported surface of the rotating shaft and that is tiltable towards a rotating direction of the rotating shaft, wherein the bearing pad includes a conduit that extends from a first aperture formed on a high temperature zone of a sliding surface opposing to the supported surface in a direction apart from the supported surface and that reaches a second aperture; the high temperature zone is positioned at a pad rear portion in the downstream region of the sliding surface with respect to the rotating direction of the shaft, and the second aperture is positioned on a pad forward portion upstream of the first aperture with respect to the rotating direction; and the conduit is a flow path having the first aperture as an inlet and the second aperture as an exit and having a differential pressure letting the lubricant oil flowing therethrough.
According to the present invention, the differential pressure between the first aperture and the second aperture lets the lubricant oil flow through the conduit from the first aperture to the second aperture, which means that the first aperture serves as an inlet and the second aperture serves as an exit.
Specifically, rotation of the rotating shaft compresses and applies shear force to the lubricant oil between the supported surface of the rotating shaft and the sliding surface of the bearing pad opposing to the supported surface and consequently the lubricant oil evolves heat. This makes the lubricant oil near the sliding surface of the bearing pad close to the supported surface be high in temperature and pressure. In particular, as a zone near to a region where the lubricant oil comes to have a high pressure between the sliding surface and the supported surface is regarded as the high temperature zone of the sliding surface, the lubricant oil provided in the first aperture formed on the high temperature zone of the sliding surface is high in temperature and pressure. On the other hand, the lubricant oil at the second aperture at the end of the conduit extending in a direction apart from the supported surface is lower than the first aperture in temperature and pressure, which generates a differential pressure between the first aperture and the second aperture. Accordingly, the differential pressure lets the lubricant oil flow through the conduit from the first aperture to the second aperture.
Since the lubricant oil flowing through the conduit moves heat, which would remain around the first aperture (in the high-temperature zone) if the conduit is absent, towards the second aperture, it is possible to inhibit the temperature of the bearing pad from locally rising and thereby to make the temperature uniform, lowering the highest temperature thereof.
The temperature of the bearing pad is made uniform by using the differential pressure to let the lubricant oil flow through the conduit. This structure can eliminate the requirement of a pump to let the lubricant oil flow through the conduit, also the requirement for using an additional oil for cooling in addition to the lubricant oil, and the requirement for using material having a high thermal conductivity as the material for the bearing pad.
Accordingly, the bearing pad can be avoided from being deformed without rising costs.
Since the bearing pad is tiltable towards a rotating direction of the rotating shaft and also the second aperture is positioned on a pad forward portion upstream of the first aperture with respect to the rotating direction, the temperature of the bearing pad can be widely made uniform.
Namely, while the rotating shaft is rotating, the bearing pad tilts to have a wider space between the bearing pad and the rotating shaft at a pad forward portion upstream along the rotating direction of the rotating shaft and a narrower space between the bearing pad and the rotating shaft at a pad rear portion downstream along the rotating direction of the rotating shaft. This tilting orientation rises the pressure of the lubricant oil between the rotating shaft and the bearing pad as approaching downstream of the rotating direction, which accompanies a rise in temperature of the lubricant oil as approaching downstream along the rotating direction.
Accordingly, forming the second aperture at the pad forward portion upstream of the first aperture with respect to the rotating direction forms the exit (second aperture) of the conduit at a lower temperature portion of the bearing pad, so that the temperature of a wide range of the bearing pad can be made uniform.
In cases where the second aperture is arranged on the back surface opposite to the sliding surface, it is possible to prevent the hot lubricant oil exhausted from the second aperture, that is, the exit of the conduit, from reflowing into the opposite sliding surface. This can further suppress a rise in the temperature of the bearing pad.
In cases where the second aperture is arranged on a front surface pointing upstream of the rotating direction, the conduit is formed at a wider range across the bearing pad, so that the region in which the temperature is made uniform can be widened.
Hereinafter, embodiments of the present invention will now be described with reference to the accompanying drawings. The following embodiments are merely exemplary and there is no intention to exclude modification and application of another technique that are not described in the following examples. The following embodiments can be variously modified without departing from the purposes thereof.
1. First Embodiment
Description will now be made in relation to a tilting pad journal bearing and a bearing pad for a journal bearing according to the first embodiment of the present invention by referring to
1-1. Entire Structure of Tilting Pad Journal Bearing:
As illustrated in
Specifically, the bearing 100 includes multiple (two in this example) tilting pads (bearing pad of the first embodiment) 2 that support the rotating shaft 1 in the vertically upward direction, a bearing housing 4 arranged around the rotating shaft 1 and the tilting pads 2, and oil supply nozzles 6 that each sprays lubricant oil from the ejector 6a disposed at the tip of the nozzle 6. On the inner circumference surface of the bearing housing 4, multiple (two in this example) pivots 5 are installed, which swingably support the respective tilting pads 2.
Two oil supply nozzles 6 are provided for each tilting pad 2. Specifically, one oil supply nozzle 6 is arranged at the forward portion (i.e., an upstream portion of the rotating direction A of the rotating shaft 1) and the other is arranged at the backward portion (i.e., a downstream portion of the rotating direction A of the rotating shaft 1). The additional lubricant oil sprayed from the ejectors 6a of the respective oil supply nozzles 6 forms an oil film between the circumference surface (supported surface, hereinafter also called a rotating shaft circumference surface) 1a of the rotating shaft 1 and a sliding surface (hereinafter also called a pad sliding surface) 2a of a tilting pad 2 opposing to the rotating shaft circumference surface 1a.
1-2. Structure of Tilting Pad of Journal Bearing:
In the tilting pad 2, which is the main part of the present invention, a conduit 3 is formed so as to connect a first aperture (hereinafter also called aperture or inlet) 3a formed on the sliding surface 2a to a second aperture (hereinafter also called aperture or exit) 3d formed on the back surface (surface on the opposite side of the sliding surface 2a and opposing to the bearing housing 4) 3d. In the first embodiment, the conduit 3 is divided into two parts of a path 3b towards the sliding surface 2a and a path 3c towards the back surface 2b that have different angles and therefor the conduit 3 bends.
Here, rotation of the rotating shaft 1 compresses and applies shear force generated by the sliding to the lubricant oil between the rotating shaft circumference surface 1a and the pad sliding surface 2a opposing to the rotating shaft circumference surface 1a and consequently the lubricant oil evolves heat. This makes the lubricant oil near to the sliding surface 2a close to the rotating shaft circumference surface 1a be high in both pressure and temperature, and above all, the lubricant oil comes to be the highest in both pressure and temperature at a zone (hereinafter called high temperature portion) 2H corresponding to a pad rear portion 2c as to be detailed below (see
The first aperture 3a of the conduit 3 is arranged within the high temperature zone 2H that is also a high pressure zone while the second aperture 3d of the conduit 3 is arranged on the pad back surface 2b. The lubricant oil near the second aperture 3d on the pad back surface 2b is lower in temperature and pressure than that near the first aperture 3a (than the lubricant oil in the state of being pressurized and evolving heat between circumference surface 1a and sliding surface 2a) and has a pressure close to atmospheric pressure.
Accordingly, the oil pressure near the first aperture 3a on the sliding surface 2a has a large differential pressure from the oil pressure near the second aperture 3d on the pad back surface 2b. This differential pressure lets the lubricant oil spontaneously flow through the conduit 3 in the direction of the arrow a from the first aperture 3a as the inlet to the second aperture 3d as the exit. This means that the conduit 3 functions as an oil extraction hole.
The conduit 3 will now be further detailed by referring to
The high temperature zone 2H lies at the pad rear portion 2c of the sliding surface 2a as the above description for the following reasons.
The lubricant oil (lubricant oil film) being pressurized between the rotating shaft circumference surface 1a and the tilting pad 2 has an oil pressure (hereinafter also called oil film pressure) much higher than the oil pressure on the pad back surface 2b as described above, and above all has a particularly high oil film pressure at the pad rear portion 2c. As illustrated in
Since a higher oil film pressure P increases an amount of heat that the lubricant oil film evolves, the temperature of the lubricant oil film and the temperature of the tilting pad 2 which are assumed not to form the conduit 3 therein have a high temperature zone 2H at the pad rear portion 2c of the sliding surface 2a.
It has been revealed, through practice, experiment, and simulation, that the maximum value of the oil film pressure P lies within a range of 70-90% of the length Lt (see
As illustrated in
As described above, the conduit 3 consists of the paths 3b, 3c having different angles. Specifically, the upstream path 3b, which passes through the high temperature zone 2H extends in a direction substantially along the thickness direction (hereinafter also called pad thickness direction) of the tilting pad 2 while the downstream path 3c extends in a direction substantially along the front-rear direction (hereinafter also called pad front-rear direction) of the tilting pad 2.
This is because the tilting pad 2 has a temperature distribution that lowers in a direction substantially along the pad thickness direction around the high temperature zone 2H and lowers in a direction substantially along the pad front-rear direction in the remaining zone, and therefore the conduit 3 is formed to let the lubricant oil flow to conform such a temperature distribution. Namely, since lubricant oil, which carries heat, moves from a higher-temperature side to a lower-temperature side by the path 3b around the high temperature zone 2H and by the path 3c around the remaining zone, so that the temperature of the tilting pad 2 can be efficiently made uniform. If the conduit 3 is formed into a straight line connecting the inlet 3a to the exit 3b, the conduit 3 at the high temperature zone 2H lies in a shallow position from the sliding surface 2a. This structure has a possibility of lowering the strength of the tilting pad 2 at the high temperature side, which requires further rigidness. The conduit 3 is bent also to avoid this inconvenience.
If the tilting pad 2 can ensure the rigidness at the high temperature side, the conduit 3 may be formed into a straight line connecting the inlet 3a to the exit 3b. The conduit 3 having a bent structure requires two processes of drilling from the inlet 3a and drilling from the exit 3d. In contrast, forming the straight-line conduit 3 can be completed through a single process of drilling from either the inlet 3a or the exit 3d.
Alternatively, as illustrated by the two-dotted line in
An excessively large diameter of the conduit 3 may affect formation of the oil film pressure between the pad sliding surface 2a and the circumference surface 1a, and therefore a preferable diameter of the conduit 3 is equal to or less than 5% of the size of the pad width.
1-3. Effects and Advantages:
Hereinafter, description will now be made in relation to the effects and advantages of the journal bearing and the tilting pad according to the first embodiment.
The conduit 3 has the inlet 3a arranged within the high temperature zone 2H that is also a high pressure zone and the exit 3d is opened to the pad back surface 2b of the low temperature zone that is a low pressure zone having the substantially atmospheric pressure. The conduit 3 consequently has a large differential pressure between the inlet 3a and the exit 3d to let the lubricant oil spontaneously flow through time conduit 3 in the direction of the arrow a. At that time, the flowing lubricant oil moves heat in the high temperature zone 2H to the low temperature side.
The presence of the conduit 3 lowers the temperature at the pad rear portion 2c accommodating the high temperature zone 2H of the tilting pad 2 and also raises the temperature at the pad forward portion 2d lower in temperature than the pad rear portion 2c so that the temperature of the tilting pad 2 is made uniform as compared with a tilting pad not having a conduit 3. Consequently, the tilting pad 2 can be escaped from locally having a high temperature portion and the highest temperature can be lowered. This can suppress thermal deformation accompanied by differential thermal expansion and therefore can eliminate the requirement of using expensive material having a high terminal conductivity for the bearing pad.
Furthermore, the differential pressure is used to let the lubricant oil flow through the conduit 3 to make the temperature of the tilting pad 2 uniform. This structure can eliminate the requirement for a pump to let the lubricant oil flow through the conduit 3. Furthermore, letting the lubricant oil flow through the conduit 3 avoids locally raising the temperature of the tilting pad 2 and also lowers the highest temperature of the tilting pad 2. This structure can eliminate the requirement to prepare a low-temperature additional oil for the purpose of cooling in addition to the lubricant oil.
Accordingly, it is possible to inhibit the bearing pad from being deformed without increasing costs.
The above advantages can be easily accomplished by simply forming conduits in a tilting pad.
When the rotating shaft 1 vibrates, a tilting pad having a larger spring constant bounces the rotating shaft 1 and makes it difficult to absorb the vibration. In contrast, a tilting pad having a larger attenuation coefficient more absorbs the vibration of the rotating shaft 1 to cease the vibration more rapidly. Inhibiting deformation of the tilting pad 2 can keep the attenuation coefficient to be high as compared with a traditional tilting pad not being inhibited from being deformed but even having an equivalent sprint constant.
Multiple conduits 3 arranged across the pad width direction bring an advantage of making the temperature of the entire tilting pad 2 uniform.
Since the exit 3d of the conduit 3 is formed on the pad back surface 2b, the hot lubricant oil heated by the friction loss between the rotating shaft circumference surface 1a and the sliding surface 2a does not re-flow onto the sliding surface 2a after passing through the exit 3d. In addition, since the hot lubricant oil does not re-flow onto the sliding surface 2a, the low-temperature additional lubricant oil (additional oil) supplied from each oil supply nozzle 6 is not inhibited from flowing into the sliding surface 2a. Accordingly, rising the temperature of the rotating shaft 1 and the tilting pad 2 can be advantageously avoided.
2. Second Embodiment
Description will now be made in relation to a bearing and a bearing pad according to a second embodiment of the present invention by referring to
2-1. structure of tilting pad journal bearing and structure of tilting pad for journal bearing: In place of the tilting pads 2 of the bearing 100 of the first embodiment, the bearing device according to the second embodiment of the present invention uses tilting pads (bearing pads according to the second embodiment of the present invention) 2A illustrated in
The tilting pad 2A of the second embodiment is different from the tilting pad 2 of the first embodiment in the point that the tilting pad 2A arranges the exit 3d of the conduit 3A on the front surface (hereinafter called tilting pad front surface) 2g of the tilting pad 2A pointing towards the upstream of rotating direction A while the tilting pad 2 of the first embodiment arranges the exit 3d of the conduit 3 on the pad back surface 2b.
The structure of the conduit 3A will now be further detailed by comparing the conduit 3 of the first embodiment. The path 3b from the inlet 3a (the pad sliding surface 2a side) of the conduit 3A is the same as the first embodiment, but the path 3c to the exit 3d lies shallower than the path 3c of the first embodiment (in other words, the path 3c of the second embodiment runs more parallel with the front-rear direction of the pad). Accordingly, this arranges the exit 3d of the end of the path 3c on the front surface 2g, not on the pad back surface 2b.
Likewise the conduit 3 of the first embodiment, the conduit 3A may take a form of a straight line that connects the inlet 3a to the exit 3d if the structure rigidness permits, and further alternatively, the conduit 3A may have a curved connection between the paths 3b and 3c as illustrated by the two-dotted line in
2-2. Effects and Advantages:
The journal bearing and the tilting pad 2A of the second embodiment arranges the exit 3d of the conduit 3A on the pad front surface 2g around which the oil pressure is in the same extent as the atmospheric pressure. This structure allows the hot lubricant oil to spontaneously flow from the inlet 3a high in temperature, and pressure to the exit 3d low in temperature and pressure, so that the same effects and advantages as the first embodiment can be obtained.
In addition, the exit 3d of the conduit 3A is arranged on the pad front surface 2g, which can widen the area of the tilting pad through which the conduit passes as compared with the structure in which the exit 3d is arranged on the pad back surface 2b. This makes the temperature of the tilting pad 2A uniform over the wider area.
3. Third Embodiment
Description will now be made in relation to the bearing and the bearing pad according to a third embodiment of the present invention by referring to
3-1. Entire Structure of Tilting Pad Thrust Bearing:
As illustrated in
Specifically, the bearing 200 includes tilting pads (bearing pads of the third embodiment of the present invention) 22 that rotatably support a thrust collar (supported portion) 21a in the form of a flange portion of the rotating shaft 21 from the axis direction of the rotating shaft 21, a bearing housing 24 arranged around the rotating shaft 21 and tilting pads 22, and oil supply nozzles 26 that spray lubricant oil from the respective ejectors 26a at the tips of the nozzles.
The tilting pads 22 are arranged on the both sides of the thrust collar 21a along the axis direction. Specifically, multiple (in this example, twelve) tilting pads 22 are arranged around the entire circumference of each side of the thrust collar (supported portion) 21a. On the back surface (hereinafter also called pad back surface) 22b of the each tilting pad 22, a pivot 25 is arranged to make the tilting pad 2 swingably.
The oil supply nozzles 26 are alternately arranged with the tilting pads 22 and spray the lubricant oil (additional oil) from the ejectors 26a thereof to form an oil film between the thrust collar 21a serving as the supported portion and the sliding surfaces (hereinafter also called pad sliding surfaces) 22a of the tilting pads 22 opposing to the thrust collar 21a.
The rotating shaft 21 is also supported by a journal bearing 300 as well as by the thrust bearing 200.
The bearing housing 24 further includes one or more non-illustrated exhausting holes through which old lubricant oil is successively drained out in place of the additional oil fed from the oil supply nozzles 26.
3-2. Structure of Tilting Pad for Thrust Bearing:
As illustrated in
The inlet 23a is formed on a high-temperature zone 23H located in the rear portion (downstream portion of the rotating direction A) 22c on the pad sliding surface 22a while the exit 23b is formed in the forward portion (upstream portion of the rotating direction A) 22d on the pad back surface 22b.
Since the high temperature zone 22H lies at a portion of the sliding surface 22a within a range of 70-100% of the length Lt of the sliding surface 22a from the upstream edge for the same reason as that described in the first embodiment, the inlet 3a is formed in this range.
As illustrated in
3-3. Effects and Advantages:
The above structure of the tilting pad thrust bearing of the third embodiment of the present invention ensures the effects and advantages the same as the first embodiment.
4. Fourth Embodiment
Here, description will now be made in relation to the tilting pad thrust bearing and the tilting pad for a tilting pad thrust bearing according to a fourth embodiment of the present invention by referring to
4-1. Structure:
The bearing according to the fourth embodiment takes a form of a thrust bearing as illustrated in
Hereinafter, the structure of the tilting pad 22A will now be described by referring to
4-2. Effects and Advantages:
The above structure of the tilting pad thrust bearing of the fourth embodiment of the present invention ensures the effects and advantages the same as the second embodiment.
5. Others
In the foregoing first and second embodiment, the tilting pads 2, 2A are arranged only below the rotating shaft 1. Alternatively, the tilting pads 2, 2A may be arranged around the entire circumference of the rotating shaft 1 including the upper side of the rotating shaft 1. In cases where the tilting pads 2, 2A are arranged around the entire circumference of the rotating shaft 1, there is no requirement to form the conduits 3, 3A in all the tilting pads 2, 2A, but it is satisfactory to form the conduits 3, 3A in at least lower tilting pads 2, 2A that are highly loaded.
The conduits 23, 23A of the third and fourth embodiments each takes a form of straight lines. Alternatively, the conduits 23, 23A may be bent or curved to conform the inner temperature distribution of the tilting pads as carried out in the first and the second embodiments.
The foregoing embodiments regard the range of 70-100% of the length Lt from the frond edge of the pad sliding surface to be the high temperature zone. However, the high temperature zone is not limited to this. Alternatively, the downstream portion (i.e., within a range of 50% or more of the length Lt from the front edge of the pad sliding surface) in the rotating direction of the pad sliding surface may be regarded as the high temperature zone. Besides, the foregoing embodiments arrange the exits (second apertures) upstream of the respective inlets (first apertures) in the rotating direction of the rotating shaft. However, the arrangement of the first and second apertures is not limited to this. Alternatively, the exit of the conduit may be arranged at the same position as the inlet with respect to the rotating direction of the rotating shaft.
The bearing of the present invention provides a conduit passing through the high temperature zone and a zone of lower temperature than that of the high temperature zone in a bearing pad, so that the heat that would remain in the high-temperature zone if the conduit is absent is moved to the other zone to lower the highest temperature of the bearing pad to finally make the temperature in the bearing pad uniform. From this viewpoint, any zone that can let the lubricant oil flow through the conduit by using differential pressure and is relatively higher in temperature than the remaining zone through which the conduit passes (i.e., a zone peripheral to the conduit) can be regarded as the high temperature zone in which the inlet of the conduit is formed.
Number | Date | Country | Kind |
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2014-192545 | Sep 2014 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2015/053805 | 2/12/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2016/047159 | 3/31/2016 | WO | A |
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Entry |
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International Search Report issued Mar. 31, 2015 in corresponding International Application No. PCT/JP2015/053805. |
Decision to Grant a Patent issued Oct. 4, 2016 in corresponding Japanese Application No. 2014-192545 (with partial English translation). |
Written Opinion of the International Search Authority issued Mar. 31, 2015 in corresponding PCT application No. PCT/JP2015/53805 (with English translation). |
Notification of Reason for Refusal dated Jun. 1, 2017 in Korean Application No. 10-2015-7036353 (English translation). |
Number | Date | Country | |
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20160265590 A1 | Sep 2016 | US |