JPH11125241A - Journal breaing - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a journal bearing on the tilting pad system for supporting a rotary shaft to sustain a high load at a high speed, in which the end of an oil supply groove and the two sides of the bearing surface are free of risk of shortage in the lubricating oil and there is no fear of seizure. SOLUTION: Oil supply nozzles 4a-4d (4) bored in the radial direction with independent hole diameter with the outlet opened at the bearing surface 3 so as to feed a new oil 7 to the bearing surface 3 are at certain intervals across the width furnished in positions upstream in rotating direction of a rotary shaft 1 of a plurality of bearing pads 25a-25d (25) installed along the arc of circle of a journal and oil pockets 26a-26d (26) are bored across the width in the bearing pads 25 at the periphery of each nozzle 4 so as to feed the new oil 7 supplied externally to the inside through oil passages 24a-24d (24) to the nozzles 4.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION The present invention relates to a bearing for supporting a rotating shaft, such as a turbine or a generator, which rotates at high speed and receives a high load, by arranging a plurality of bearing pads around a journal of the rotating shaft. The invention relates to a journal bearing formed using a tilting pad bearing.

[0002]

2. Description of the Related Art A bearing for supporting a rotating shaft of a large rotating machine such as a steam turbine or a gas turbine. The bearing has a bearing surface formed between an outer peripheral surface of a journal and a sliding surface of the bearing. A plurality of bearing pads are movably supported by a pivot, and are formed by arranging them on the entire circumference of the journal of the rotating shaft. Each bearing pad is tilted according to the movement of the rotating shaft, and rotated by dynamic oil film force. 2. Description of the Related Art Rotary shaft bearings that use a tilting pad bearing as a journal bearing so as not to have a component that causes the shaft to oscillate have been widely used.

That is, journal bearings in which lubricating oil is injected into the bearing surface to lubricate the outer peripheral surface of the journal and the sliding surface of the bearing are roughly classified into two types in terms of lubricating oil lubrication system for lubricating the bearing surface. One is to supply and fill the lubricating oil into the conventionally widely used bearing housing, soak the bearing surface with the lubricating oil and discharge the oil used for sliding from above. Oil bath system (Flood) in which lubricating oil is immersed and circulated on the bearing surface
d Lubrication), and the other is forming a lubricating oil film on the bearing surface, which has recently been expanding its application because it is advantageous in terms of reducing the amount of supplied oil and reducing loss. Direct lubrication system that lubricates the bearing surface by using
ation) journal bearings.

The journal bearing of the present invention relates to the latter direct lubrication type journal bearing. As a typical example of a tilting pad bearing conventionally used as the journal bearing of the direct lubrication system, FIG.
This will be described with reference to FIG.

FIG. 5 is a transverse sectional view of the tilting pad bearing, FIG. 6 is a longitudinal sectional view taken along the line BB of FIG. 7, and FIG. 7 is a sliding surface of the bearing pad of the tilting pad bearing shown in FIG. It is a perspective view for explaining the shape of the groove provided in the (inner peripheral surface), and the flow of lubricating oil. As shown in FIG. 5, these tilting pad 10 bearings have a lower lubricating pad 2c due to a fluid lubrication effect caused by the rotation of the rotating shaft 1.
2d are slightly inclined in the rotation direction of the rotating shaft 1 to support the load.

That is, the outer peripheral surface of each of the four bearing pads 2, the upper bearing pads 2 a and 2 b and the lower bearing pads 2 c and 2 d, is inscribed in the inner peripheral surface of the support ring 6, and both sides are formed. It is held by the oil retaining ring 8 so that it can be tilted in the rotation direction of the rotary shaft 1. In particular, the lower bearing pads 2 c to 2 d are inclined in the rolling direction to support the load of the rotary shaft 1. ing.

The lubricating oil 7 supplied to the bearing surface 3 is
The lubricating oil 7 is supplied to the outer peripheral side of the support ring 6 from an oil supply hole provided in a bearing casing (not shown) which is arranged on the outer periphery of the support ring 6 and fixes the support ring 6, and the lubricating oil 7 is recessed on the outer periphery of the support ring 6. The support ring 6 is turned around the entire circumference by the provided annular oil supply pocket 12.

Further, the lubricating oil 7 flowing into the entire circumference of the oil supply pocket 12 is communicated with the annular oil supply pocket 12 so as to be equally spaced in the circumferential direction of the support ring 6 and inserted in the radial direction. Oil holes, upper bearing pads 2a, 2b and lower bearing pads 2c, 2d inscribed in support ring 6.
And an inner peripheral side of a support ring 6 for connecting an oil pad nozzle 4 composed of an upper pad oil nozzle 4a, 4b and a lower pad oil nozzle 4c, 4d, which are formed on the inner diameter side from the outer peripheral surface, respectively. Upper bearing pads 2a, 2
b and the upper bearing sleeves 5a and 5b and the lower bearing sleeves 5c and 5d inserted on the outer peripheral side of the lower bearing pads 2c and 2d.

The lubricating oil supplied to the oil supply nozzle 4 is supplied to the upper pad oil supply groove 11 provided on the sliding surface 9 on the upstream side of the bearing pad 2 in parallel with the axis of the rotary shaft 1.
a, 11b and the lower pad oil supply 11c, 11d. In addition, refueling pad 2
Lubricating oil 7 supplied to the oil supply groove 11 provided on the sliding surface 9 of
Flows into the bearing surface 3 by a pumping action (pulling action to oil) generated by the lubricating force and the rotation of the rotary shaft 1, and forms an oil film supporting the load of the rotary shaft 1 on the entire circumference of the journal of the rotary shaft 1.

[0010] At this time, the lubricating oil 7 forming the oil film is applied not only to the center of the bearing pad 2 but also to the sliding surface 9 of the bearing pad 2.
The oil is supplied to the entire surface in the width direction and an oil film needs to be formed on the entire surface of the bearing surface 3 in the axial direction.
On both sides of the oil supply groove 11, the lubricating oil 7 spreads over the entire oil supply groove 11 which is elongated in the width direction of the sliding surface 9.
A challenger 13 is provided.

However, in the journal bearing using the tilting pad bearing 10 configured as described above, the chamfers 13 are provided on both sides of the oil supply groove 11 provided on the sliding surface 9 of the bearing pad 2. The lubricating oil 7 is provided so as to fill the entire slender oil supply groove 11.
Since the oil supply is performed only from the oil supply nozzle 4 provided at the center of the bearing pad 2, the center of the oil supply groove 11 is filled with the lubricating oil 7, but both ends of the oil supply groove 11 far from the oil supply nozzle 4 lack oil. Sliding surface 9 of bearing pad 2
Oil shortage on both sides, and there is a risk that the bearing surface 3 may be seized.

In order to prevent oil shortage at both ends of the oil supply groove 11, the chamfers 13 are provided on both sides of the oil supply groove 11. From this part, the outer periphery of the journal and the inner peripheral surface of the support ring 6 are formed. The lubricating oil 7 flowing out is hardly used for lubrication of the bearing surface 3, does not effectively act to lower the metal temperature, and is a useless lubricating oil 7. Requires the supply of excess lubricating oil 7,
There is a need for improvement in terms of reducing the amount of lubricating oil supplied.

Further, since the shape of the oil supply groove 11 provided on the sliding surface 9 of the bearing pad 2 is open to the bearing surface 3, a stepped shape is formed in terms of the ratio to the bearing oil film thickness. For this purpose, the lubricating oil 7
Does not work effectively, and the lubricating oil 7 hardly flows into the bearing surface 3.

[0014]

SUMMARY OF THE INVENTION According to the present invention, there is provided a tilting pad bearing 1 in which a plurality of bearing pads 2 are arranged along an arc of the above-mentioned journal to support a rotating shaft 1.
In order to solve the above-mentioned disadvantages of the conventional journal bearing in which no oil is used, no lubrication oil shortage occurs at both ends of the oil supply groove 11 and oil shortage occurs on both sides of the bearing surface. There is no risk of seizure occurring, and all the lubricating oil supplied to the oil supply groove can flow out to the bearing surface including both sides of the bearing,
Since it can effectively act to lower the metal temperature, the amount of lubricating oil to be supplied can be reduced without being wasted, and the lubricating oil must be supplied evenly over the entire width of the bearing pad. Even if the shape of the supply channel provided in the width direction does not form a step on the sliding surface of the bearing pad even with the ratio of the lubricating oil film, the lubricating oil drawing action by the rotation of the rotating shaft is effectively generated It is an object of the present invention to provide a journal bearing which can make the lubricating oil effectively flow into a bearing surface provided on a journal outer peripheral surface.

[0015]

For this reason, the journal bearing of the present invention has the following means.

(1) A plurality of bearing pads, which constitute a journal bearing for supporting the rotating shaft, are arranged along the arc of the journal of the tilting pad bearing, on the upstream side in the rotation direction of the rotating shaft of the rotating shaft, in the respective width directions. A lubrication nozzle was provided that was bored in the radial direction at an interval, had an independent hole diameter, opened the outlet to the bearing surface, and fed new lubricating oil to the bearing surface.

The hole diameter of the refueling nozzle can be varied for each refueling nozzle, and the hole diameter of the selected refueling nozzle in the width direction of the bearing pad can be controlled to be fully open and fully closed. It is preferable to use

(2) a refueling nozzle is formed in a radial direction;
The new oil that is bored in the bearing pad on the outer diameter side of the lubrication nozzle of the bearing pad in the width direction and is supplied inside through an oil supply passage such as an oil supply sleeve that supplies new oil of lubricating oil from the outside. Was supplied to each of the oil supply nozzles. It is preferable that the oil pocket has a structure in which lubricating oil cannot be supplied to the inside of the bearing from other than the oil supply nozzle.

The metal temperature of the bearing surface of the pad bearing of the tilting pad bearing is determined by the oil temperature on the inlet side of the pad bearing, heat generated by shearing of the oil film, heat radiation from the bearing pad to the surroundings, and the like. In the circumferential direction and the width direction, large temperature irregularities of about 20 ° to 40 ° usually occur. It is very important to reduce the temperature unevenness and, consequently, the maximum metal temperature from the viewpoint of improving the reliability of the bearing. Further, the oil temperature on the bearing surface is determined by determining the oil temperature and oil amount of the lubricating oil having a higher temperature flowing out of the bearing pad disposed on the upstream side of the bearing pad forming the bearing surface, and the bearing pad. Is controlled by the temperature and the amount of cold oil newly flowing in from the oil supply nozzle, and is affected by the manner of mixing these lubricating oils.

The journal bearing of the present invention is characterized in that
According to (2), (a) drilled in the radial direction of the pad bearing,
Independent oil supply nozzles are arranged at intervals in the width direction of the bearing pad, and the oil amount controlled independently from the oil pockets provided in the width direction of the pad bearing is supplied to the bearing surface by setting the oil supply nozzle hole diameter. As a result, the oil amount in the width direction can be adjusted, and lubricating oil in the width direction is supplied to the required places, and the required amount of lubrication is performed. By the distribution, the distribution of the oil temperature on the bearing surface can be optimized, the temperature distribution of the metal temperature distribution in the width direction of the bearing pad can be reduced, and the maximum metal temperature can be reduced.

The lubricating oil supplied to the oil pocket is
Since all oil is supplied from the oil supply nozzle to the bearing surface, it is possible to effectively act on the reduction of the metal temperature from this point, and it is not necessary to supply excess lubricating oil, so that the amount of oil to be supplied can be reduced. . In addition, the oil pocket
It is bored in the bearing pad on the outer peripheral side of the oiling nozzle, does not open to the bearing surface like the conventional oiling groove, and even when viewed in terms of the bearing oil film thickness ratio, the step due to the formation of oil pockets is completely It is not formed, and the lubricating oil discharged from the oil supply nozzle by the rotation of the rotary shaft is effectively drawn into the bearing surface, making it easier for the lubricating oil to flow into the bearing surface. Oil film formation becomes better,
Wear on the sliding surface of the bearing pad or the outer peripheral surface of the journal can be reduced.

Further, the journal bearing of the present invention employs the following means in addition to the above-mentioned means (1) and (2).

(3) The lubricating nozzle is arranged at intervals in the width direction of the bearing pad and is bored in the radial direction of the bearing pad to supply the lubricating oil in the oil pocket to the bearing surface. In the opening, the depth of the rotating shaft on the upstream side of rotation is increased, and the depth of the rotating shaft on the downstream side is reduced. The lubrication that flows out of the bearing surface on the upstream side to the bearing surface by the pumping action due to the rotation of the rotating shaft A scoop-type lubrication port is provided which facilitates the flow of oil and lubricating oil supplied from the lubrication nozzle to the bearing surface.

According to the journal bearing of the present invention, the lubricating oil flowing from the outlet of the oil supply nozzle to the bearing surface of the bearing pad by the rotation of the rotating shaft is provided by the means of (3) in addition to the above (a). Since the retraction is performed more smoothly by the installation of the scoop type oil supply port, the lubrication oil shortage on the bearing surface is less likely to occur in the entire width of the bearing pad.

Further, even in the case where the lubricating oil supply oil pressure drops due to any cause and the amount of oil flowing into the bearing surface decreases due to the pressure, the installation of the scoop type oil supply port will The pulling force due to the pump action is increased, and the amount of oil required for lubrication on the bearing surface can be sufficiently ensured in the entire width of the bearing pad.

[0026]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS One embodiment of a journal bearing according to the present invention will be described below with reference to the drawings. FIG. 1 is a cross-sectional view of a tilting pad bearing as a first embodiment of the journal bearing of the present invention, and FIG.
FIG. 3 is a perspective view of a bearing pad constituting the tilting pad bearing shown in FIG. In addition,
In these drawings, the same members as those shown in FIGS. 5 to 7 are denoted by the same reference numerals, and description thereof will be omitted.

As shown in these figures, in the tilting pad bearing 20 of the present embodiment, the lubricating oil 7
Is supplied from an oil supply passage 22 penetrating the inside of the casing 21.
The lubricating oil 7 filled in an annular oil supply pocket 12 formed in the outer peripheral surface of the support ring 6 in the same manner as that shown in FIG. 6 is communicated with the annular oil supply pocket 12. Oil pockets formed in the width direction of the bearing pad 25 via an oil supply sleeve 5 for connecting an oil supply passage 23 penetrating the support ring 6 side and an oil supply passage 24 penetrating the bearing pad side 25. The lubricating oil 7 is supplied to 26.

Incidentally, the bearing pads 25 are, similarly to the conventional example, upper bearing pads 25a, 25 above the journal.
b, a lower pivot pad composed of four lower bearing pads 25c and 25d, which is inserted into a groove recessed in the outer periphery of the bearing pad 25 in contact with the inner periphery of the support ring 6 and the inner periphery of the support ring 6. 28a, 28b, 28c and 28d are connected to the support ring 6 so as to be tiltable in the rotation direction of the rotary shaft 1.

Therefore, from the oil supply passage 23 of the support ring 6,
Upper bearing pads 25a, 25b, lower bearings 25c, 25
d, the oil supply passages 24a, 24b, 2
5, lubricating oil 7 is supplied via upper pad oiling sleeves 5a and 5b and lower pad oiling sleeves 5c and 5d, and upper bearing pads 25a and 25b and lower bearing pad 2 are supplied.
The oil pockets 26a, 26b for the upper bearing pad and the oil pockets 26c, 26d for the lower bearing pad, which are formed in 5c and 25d, respectively, are filled.

Further, the lubricating oil 7 filled in the oil pocket 26 is supplied to each of the upper pad oil supply nozzles 4a and 4b and the lower pad oil supply nozzles 4c and 4d by the bearing pad 25.
Refueling nozzle 4 arranged at intervals in the width direction
Through x to 4z, it is supplied from the sliding surface 9 of the bearing pad 25 to the bearing surface 3. Here, the refueling nozzles 4x to 4z
The lubricating oil 7 can be supplied independently of each other.
The supply flow rate to the bearing surface 3 at the axial position where they are arranged can be set by freely setting the diameter of each of the oil supply nozzles 4x to 4z, so that the supply oil of the lubricating oil to each part in the width direction of the bearing pad 25 is provided. The quantities 7x to 7z can be adjusted.

Further, the openings of the refueling nozzles 4x to 4z on the sliding surface 10 are formed such that the upstream side in the rotation direction of the rotary shaft 1 is made deeper and the downstream side thereof is made shallower, so that the upstream side bearing surface 3 A scoop-type oil supply port 27 shaped like a scoop, which facilitates scooping outflowing lubricating oil, is provided with upper pad oil supply nozzles 4a and 4b and lower pad oil supply nozzles 4c and 4d.
Are provided at respective outlets of the refueling nozzles 4x to 4z which are arranged at intervals in the width direction of the bearing pad 25.

Also, the upper bearing pads 25a, 25b,
Each of the lower bearing pads 25c and 25d, particularly the lower bearing pads 25c and 25d, is slightly inclined in the rotation direction of the rotating shaft 1 and supports the load of the rotating shaft 1 similarly to the conventional bearing pad 2.

Next, FIG. 4 shows a case where a plurality of refueling nozzles 4x to 4 are arranged at intervals in the width direction.
It is a figure which shows typically the filling degree of the oil of the pad surface when the opening degree of 4z and the number of oil supply nozzles are changed.

As shown in FIG. 4A, when the load on the rotating shaft 1 is small, for example, the lubrication nozzles 4x to 4z provided in the width direction of the bearing pad 25 are located at the center of the lubrication nozzles 4x to 4z. Lubricating oil 7 is supplied only from nozzle 4y,
Other lubrication nozzles 4x, 4z for supplying lubricating oil to bearing surface 3
, The supply amount can be reduced to the oil amount according to the load.

As shown in FIG. 4 (b), the diameter of the oil supply nozzle 4y at the center position is relatively larger than the diameter of the oil supply nozzles 4x and 4z on both sides, so that The width of the bearing surface 3 is increased by increasing the amount of supplied oil, reducing the amount of lubricating oil 7 supplied from the oil supply nozzles 4x, 4z on both sides to the bearing surface 3 and reducing the amount of oil on both sides. It is also possible to form an oil film having a uniform thickness in the direction.

Further, as shown in FIG. 4 (c), by increasing the number of oiling nozzles 4 in the axial direction of the bearing pad 25 to three or more as shown in FIGS. 4 (a) and 4 (b). The oil amount in the width direction of the bearing surface 3 can be finely evenly distributed, and an oil film having a more uniform film thickness can be formed in the width direction.

Therefore, in the journal bearing of the present embodiment, the supply of the lubricating oil 7 in the width direction is performed by supplying the necessary amount of the lubricating oil 7 to the necessary places, and the lubricating oil 7 is optimally supplied in the width direction of the bearing surface 3. By using the amount distribution, the distribution of the oil temperature in the width direction of the bearing surface 3 can be set to an optimum state, the temperature unevenness of the metal temperature distribution can be reduced, and the maximum metal temperature can be reduced.

Further, since all the lubricating oil 7 supplied to the oil pocket 26 is supplied to the bearing surface 3, the lubricating oil 7 is not wasted and the amount of supplied oil can be reduced. Does not directly open into the bearing surface 3,
The sliding surface of the bearing pad 25 does not have a step of about the oil film thickness, and the lubricating oil 7 is more easily drawn into the bearing surface by the rotating shaft 6. Further, by providing the scoop type oil supply port 27 provided at the outlet of the oil supply nozzle 4 to the bearing surface 3, the lubricating oil is drawn into the bearing surface 3 by the rotation of the rotating shaft 1, and the bearing surface 3 is further increased. In this case, a sufficient amount of oil required for lubrication can be secured.

As described above, according to the journal bearing of this embodiment, (1) by providing a plurality of oil supply pad oil supply passages 24 having independent hole diameters on the upstream side (width direction) of the bearing pad 25,
Since the amount of lubrication in the width direction can be adjusted, the shortage of oil on both sides of the bearing pad 25, which is a drawback of the conventional single groove type lubrication nozzle 4, can be solved.

Further, since the oil supply amount in the width direction can be independently distributed, the inlet temperature in the width direction of the bearing pad 25 determined by the inflow of the high-temperature oil from the upstream-side bearing pad 25 and the mixture of the supplied fresh oil is set to a predetermined distribution. Can be Thereby, a large amount of lubricating oil 7 is supplied to a place where the metal temperature becomes high, and the oil amount is reduced in a place where the metal temperature is low, so that the maximum metal temperature and the oil amount can be reduced. Also,
If a metal temperature level equivalent to the current state is allowed, the amount of oil can be significantly reduced.

(2) Most of the supplied lubricating oil 7 is supplied to the sliding surface 9 of the bearing pad 25 and is efficiently used to reduce the metal temperature. Therefore, a bearing having a low metal temperature with a small amount of oil is realized. it can.

(3) By providing the scoop-type oil supply port 27 at the outlet of the bearing pad 25 to the bearing surface 3, the lubricating oil 7 is effectively and stably drawn into the bearing surface 3 by the rotation of the rotating shaft 1. It can be carried out.

Further, even when the supply hydraulic pressure is reduced, the amount of oil necessary for lubricating the bearing surface 3 can be sufficiently secured, so that seizure of the bearing surface 3 can be avoided and stable bearing characteristics can be maintained. .

[0044]

The journal bearing according to the present invention has a plurality of bearing pads arranged along the arc of the journal on the upstream side in the rotation direction of the rotating shaft, and is spaced apart from each other in the width direction.
Inside the bearing pad on the outer diameter side of the lubrication nozzle and the lubrication nozzle of the bearing pad, which have an independent hole diameter and are drilled in the radial direction, the outlet is opened to the bearing surface, and new lubricating oil is sent to the bearing surface. Oil pockets are provided in the width direction to feed the new oil supplied inside through oil supply passages such as an oil supply sleeve for supplying new oil from the outside to each of the oil supply nozzles.

[0045] Thereby, an independent refueling nozzle is provided in the radial direction of the pad bearing and spaced apart in the width direction of the bearing pad, and is provided in the width direction of the pad bearing by setting the diameter of the refueling nozzle hole. The amount of oil that is independent of the oil pockets that can be adjusted is supplied to the bearing surface in an adjustable manner, so that the required amount of lubrication oil is supplied to the required bearing surface at locations where lubrication oil needs to be supplied in the width direction. By optimizing the lubrication amount distribution in the width direction of the bearing, the distribution of the oil temperature at the bearing pad inlet can be set to an optimum state, and the temperature unevenness of the metal temperature distribution can be reduced and the maximum metal temperature can be lowered.

The lubricating oil supplied to the oil pocket is
Since the oil supply nozzle and all the oil are supplied to the bearing surface, it is possible to effectively reduce the metal temperature from this point as well, so that it is not necessary to supply the surplus lubricating oil and the oil amount can be reduced. Furthermore, the oil pocket is bored in the bearing pad on the outer peripheral side of the oil supply nozzle, the opening is not exposed on the bearing surface like an oil supply groove, and no step is formed even when viewed from the bearing oil film thickness ratio. In addition, the lubricating oil discharged from the oil supply nozzle by the rotation of the rotating shaft is effectively drawn in, and the lubricating oil easily flows into the bearing surface.

Also, the journal bearing of the present invention is formed in the radial direction of the bearing pad, and the lubrication oil in the oil pocket is supplied to the bearing surface. A scoop-type refueling port having a scoop shape with a reduced depth on the rotation side and a reduced depth on the rotation downstream side is provided.

Thus, the lubricating oil flowing from the outlet of the oil supply nozzle into the bearing surface of the bearing pad due to the rotation of the rotating shaft is smoothly drawn in, so that the lubricating oil on the bearing surface is less likely to be insufficient.

Further, even when the supply oil pressure is reduced and the amount of oil flowing into the bearing surface due to the pressure is reduced, the pulling force is increased by the pump action due to the installation of the scoop type oil supply port, which is necessary for lubrication of the bearing surface. A sufficient amount of oil can be secured.

[Brief description of the drawings]

FIG. 1 is a cross-sectional view of a tilting pad bearing as a first embodiment of a journal bearing of the present invention;

FIG. 2 is a longitudinal sectional view taken along a line AA in FIG. 1;

FIG. 3 is a perspective view of a bearing pad constituting the tilting pad bearing shown in FIG. 1;

FIG. 4 is a diagram schematically showing the state of oil filling on the pad surface when intervals are provided in the width direction of the oil supply nozzles and the opening degrees of the plurality of nozzles and the number of nozzles are changed. )
FIG. 4B is a diagram showing a case where lubricating oil is supplied only from the oil supply nozzle 4y at the center position among the three oil supply nozzles provided in the width direction of the bearing pad when the load is small, and FIG. Shows a case where the nozzle diameter of the nozzle is relatively larger than the nozzle diameter on both sides to increase the amount of oil, the nozzle diameter for oil supply on both sides is reduced, and the oil amount on both sides of the bearing surface is reduced. FIGS. 4 (c) and 4 (c) show that the number of oiling nozzles in the axial direction of the bearing pad 5 is increased from that shown in FIGS. 4 (a) and 4 (b). A diagram showing the case of distributing,

FIG. 5 is a cross-sectional view of a conventional tilting pad bearing,

6 is a longitudinal sectional view taken along the line BB shown in FIG.

FIG. 7 is a perspective view for explaining a groove shape provided on a sliding surface (inner peripheral surface) of a bearing pad of the tilting pad bearing shown in FIG. 5 and a flow of lubricating oil.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 Rotary shaft 2 Bearing pad 2a, 2b Upper bearing pad 2c, 2d Lower bearing pad 3 Bearing surface 4, 4x, 4y, 4z Lubrication nozzle 4a, 4b Upper pad lubrication nozzle 4c, 4d Lower pad lubrication nozzle 5 Lubrication Sleeve 5a, 5b Upper pad oil supply sleeve 5c, 5d Lower pad oil supply sleeve 6 Support ring 7 Lubricating oil 7 'Drainage 7x-7y Lubricating oil amount in bearing surface width direction 8 Oil retaining ring 9 Sliding surface 10 Tilting Pad bearing 11 Oil supply groove 11a, 11b Oil supply groove for upper pad 11c, 11d Oil supply groove for lower pad 12 Oil supply pocket 13 Chanfer 20 Tilt pad bearing 21 Casing 22 (Casing) oil supply passage 23 (support ring) oil supply passage 24 (Bearing) Pad) Oil supply passage 24a, 24b Oil supply passage 24c, 24d for upper bearing pad Side bearing pads for oil supply passage 25 bearing pads 25a, 25b upper bearing pads 25c, 25d lower bearing pad 26 oil pocket 27 scoop-type filler opening 28a, 28b, 28c, 28d pivot

 ────────────────────────────────────────────────── ─── Continued on the front page (72) Inventor Ryutaro Magoshi 2-1-1 Shinhama, Arai-machi, Takasago City, Hyogo Prefecture Inside the Mitsubishi Heavy Industries, Ltd. Takasago Machinery Works

Claims (2)

[Claims] 1. A tilting pad bearing formed by arranging a plurality of bearing pads along an arc of a journal, wherein the journal pad is adapted to support a rotating shaft. An oil supply nozzle that is bored in the upstream side in the radial direction at intervals in the width direction, has an independent hole diameter, opens on the bearing surface, and feeds new oil to the bearing surface, and an outer diameter of the oil supply nozzle A journal bearing provided with an oil pocket perforated in the width direction in the bearing pad on the side and for feeding new oil to each of the oil supply nozzles. 2. A scoop-type refueling port formed in a scoop shape in which a rotation upstream side of the rotation shaft is made deeper and a rotation downstream side is made shallower is provided at an opening of the refueling nozzle to the bearing surface. The journal bearing according to claim 1, wherein