JP3762200B2 - Air turbine spindle - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention relates to an air turbine spindle, for example, an air turbine spindle that is incorporated in a hole processing machine, a precision processing machine, an electrostatic coating machine, and the like and supports a main shaft in a non-contact manner with a static pressure air bearing.
[0002]
[Prior art]
11 and 12 show an example of a conventional spindle having a structure in which a main shaft is supported by a hydrostatic air bearing. This spindle is driven by an air turbine, that is, compressed air is blown to a plurality of recesses 3 provided on the outer periphery of the thrust plate 2 b of the main shaft 1 from a turbine nozzle 4 disposed at a portion facing the recesses 3. Thus, the main shaft 1 is rotated.
[0003]
The main shaft 1 includes a shaft portion 2a and a thrust plate 2b provided at an end portion thereof, and is rotatably supported with respect to the housing 8 by a journal bearing portion and a thrust bearing portion described later. The housing 8 includes a substantially cylindrical first housing portion 8a, a circular lid-shaped second housing portion 8b integrally coupled to the end portion thereof, and a bearing sleeve 9 fixed to the inner diameter of the first housing portion 8a. And a bearing plate 18 fixed to the inner end face of the second housing portion 8b.
[0004]
A bearing sleeve 9 is fixed to the inner diameter of the first housing portion 8a by appropriate means such as shrink fitting, press fitting, or adhesion. The bearing sleeve 9 is formed with a journal bearing portion 12 having a journal bearing surface 11 facing the outer diameter surface of the shaft portion 2a of the main shaft 1 with a minute journal bearing gap 10 between the end surface of the thrust plate 2b. A thrust bearing portion 15 having a thrust bearing surface 14 facing each other with a thrust bearing gap 13 therebetween is formed. The bearing sleeve 9 is provided with a plurality of fine bearing nozzles 16 and 17 that are open to the journal bearing surface 11 and the thrust bearing surface 14.
[0005]
A bearing plate 18 is fixed to the inner end surface of the second housing portion 8b by appropriate means such as shrink fitting, press fitting, or adhesion. The bearing plate 18 is formed with a thrust bearing portion 21 having a thrust bearing surface 20 facing the end surface of the thrust plate 2b with a minute thrust bearing gap 19 therebetween. Further, the bearing plate 18 is provided with a plurality of fine bearing nozzles 22 opened to the thrust bearing surface 20.
[0006]
A fixing ring 23 is fixed to the inner diameter of the end of the first housing portion 8a by appropriate means such as shrink fitting, press fitting, or adhesion. The fixing ring 23 is formed with a plurality of turbine nozzles 4 penetratingly formed at portions facing the concave portions 3 of the thrust plate 2b. Each turbine nozzle 4 opens substantially tangentially along the outer periphery of the fixing ring 23 and communicates with the turbine air inlet 5 via an annular groove 6 formed in the first housing portion 8a. The fixing ring 23 is provided with a brake nozzle 24 for applying a braking force to the main shaft 1 that is rotating forward, and the brake nozzle 24 is formed in the second housing portion 8b via an air supply passage 25. The brake air supply port 26 is in communication.
[0007]
The radial displacement and thrust displacement of the main shaft 1 are restricted by the compressed air flowing into the journal bearing gap 10 and the thrust bearing gaps 13 and 19 from the bearing nozzles 16, 17 and 22 of the bearing sleeve 9 and the bearing plate 18. The compressed air that has flowed into the journal bearing gap 10 and the thrust bearing gaps 13 and 19 is discharged directly from the end of the shaft portion 2a of the main shaft 1 to the outside of the housing and through the recessed portion 27 of the fixing ring 23. Are also discharged.
[0008]
During forward rotation of the main shaft 1, the compressed air supplied from the turbine air supply port 5 is jetted from the turbine nozzle 4 of the fixed ring 23 toward the recess 3 of the thrust plate 2 b via the annular groove 6. The recess 3 has a radial wall surface 7 at a position facing the turbine nozzle 4 and perpendicular to the tangential direction in which the turbine nozzle 4 opens. The jetted compressed air is blown against the wall surface 7 in the radial direction of the recess 3 to give a rotational force to the main shaft 1 and is discharged from the exhaust port 28 to the outside of the housing.
[0009]
During braking of the main shaft 1, compressed air supplied from the brake air supply port 26 is jetted from the brake nozzle 24 toward the concave portion 3 of the thrust plate 2 b during normal rotation via the air supply passage 25. The jetted compressed air is blown to the wall surface 29 orthogonal to the radial wall surface 7 of the recess 3 to apply a braking force to the main shaft 1 and is discharged from the exhaust port 28 to the outside of the housing. At this time, the supply of compressed air for normal rotation of the main shaft 1 is interrupted.
[0010]
13 and 14 show another example of a conventional air turbine spindle. Since the basic configuration of the air turbine spindle is the same as that of the spindles of FIGS. 11 and 12, the same parts are denoted by the same reference numerals, and redundant description is omitted.
[0011]
In this air turbine spindle, a forward rotation recess 3 and a brake recess 30 are arranged side by side in two rows in the axial direction on the outer periphery of the thrust plate 2b, and open substantially in a tangential direction at a portion facing the recess 3 of the fixing ring 23. A turbine nozzle 4 is provided, and a brake nozzle 31 that is open in a substantially tangential direction opposite to the turbine nozzle 4 is provided at a portion of the fixing ring 23 that faces the recess 30.
[0012]
During forward rotation of the main shaft 1, the compressed air supplied from the turbine air supply port 5 is jetted from the turbine nozzle 4 of the fixed ring 23 toward the recess 3 of the thrust plate 2 b via the annular groove 6. The jetted compressed air is blown against the wall surface 7 in the radial direction of the recess 3 to give a rotational force to the main shaft 1 and is discharged from the exhaust port 28 to the outside of the housing.
[0013]
When the main shaft 1 is braked, the compressed air supplied from the brake air supply port 32 passes through the annular groove 33 so that the compressed air that normally rotates the main shaft 1 is blocked. It ejects toward the recessed part 30 of the board 2b. The jetted compressed air is blown to the radial wall surface 34 of the recess 30 to apply a braking force to the main shaft 1 and is discharged from the exhaust port 28 to the outside of the housing.
[0014]
[Problems to be solved by the invention]
By the way, in the air turbine spindle of FIG.11 and FIG.12 mentioned above, the recessed part 3 provided in the fixed ring 23 for the normal rotation of the main axis | shaft 1 is utilized also at the time of a brake. That is, the compressed air ejected from the brake nozzle 24 is blown onto the wall surface 29 orthogonal to the radial wall surface 7 of the recess 3. At this time, since the angle formed between the jet direction of the compressed air and the wall surface 29 to which the compressed air is blown is small, there is a problem that the efficiency is poor in exerting the brake performance.
[0015]
In addition, in the fixing ring 23, the brake nozzle 24 must be formed in the same plane as the turbine nozzle 4. Therefore, the brake nozzle 24 needs to be provided at a position where it does not interfere with the turbine nozzle 4. It was difficult to secure. Due to these problems, it has been difficult to apply a strong braking force with the air turbine spindle.
[0016]
On the other hand, in the air turbine spindle shown in FIGS. 13 and 14, the forward rotation recess 3 and the brake recess 30 are arranged in parallel on the outer periphery of the thrust plate 2 b and supplied from the turbine nozzle 4 and the brake nozzle 31. The compressed air to be ejected separately into the respective recesses 3 and 30 is efficient in exerting brake performance, and it is necessary to consider interference with the turbine nozzle 4 in disposing the brake nozzle 31. Since there is no, a strong braking force can be applied.
[0017]
However, in this air turbine spindle, since the radial wall surface 34 of the brake recess 30 provided on the thrust plate 2b is oriented in the opposite direction to the radial wall 7 of the forward rotation recess 3, When the main shaft 1 is rotated forward, there is a problem that the radial wall surface 34 of the brake recess 30 becomes a resistance and decreases the efficiency during forward rotation.
[0018]
Therefore, the present invention has been proposed in view of the above problems, and an object of the present invention is to provide an air turbine spindle that can secure a strong braking force without reducing the efficiency during forward rotation of the main shaft. It is to provide.
[0019]
[Means for Solving the Problems]
As a technical means for achieving the above object, the present invention blows compressed air from a plurality of turbine nozzles disposed in a portion of a housing facing the recesses to a plurality of recesses provided on the outer periphery of the main shaft. In the air turbine spindle for rotating the main shaft, a plurality of brake nozzles are provided in the main shaft in a direction opposite to the turbine nozzle, and a brake air supply port communicating with the brake nozzle is provided in the housing.
[0020]
In the present invention, the brake nozzle is provided on the main shaft, and the brake performance is exhibited by ejecting compressed air in a direction opposite to the forward rotation from the brake nozzle on the outer periphery of the main shaft. As a result, it is not necessary to consider interference with the turbine nozzle in arranging the brake nozzle, so that a strong braking force can be applied, and compared with a structure in which a concave portion is provided on the rotating main shaft. In addition, it is possible to realize a structure having a small resistance when the main shaft is rotated forward.
[0021]
The present invention provides a housing having a plurality of bearing nozzles each opened to a journal bearing surface facing the outer diameter surface of the main shaft with a journal bearing gap and a thrust bearing surface facing the end surface of the thrust plate of the main shaft with a thrust bearing clearance. And can be applied to a hydrostatic air bearing that supports the main shaft in a non-contact manner by allowing compressed air to flow into the bearing gap from each bearing nozzle.
[0022]
In the present invention, (1) a structure in which the brake nozzle is disposed in the vicinity of the recess provided on the main shaft, and (2) a surface that receives the blowing force of the compressed air ejected from the brake nozzle at a portion facing the brake nozzle. For example, a structure in which irregularities including the end face of the fixed wing are formed, (3) a structure in which a pressure chamber is provided in the main shaft, and a brake nozzle and a brake air supply port are communicated with each other via the pressure chamber, (4) pressure The load capacity of the thrust bearing portion that is provided on the thrust plate of the main shaft and that is located on the opposite side of the thrust bearing portion that is formed on each end face of the thrust plate to the side that communicates with the brake air supply port. It is desirable to have a structure provided with means for increasing the pressure, a structure provided with means for reducing the axial force applied to the main shaft by the compressed air for braking, or a structure provided with both means. In (3) and (4) above, a structure in which a seal mechanism for preventing leakage of compressed air from the pressure chamber is provided between the pressure chamber of the main shaft and the brake air supply port of the bearing housing; Is a gap seal formed between the main shaft and the housing. In the above (4), the means for reducing the axial force applied to the main shaft may be an air gap between the thrust bearing portion located on the side where the pressure chamber communicates with the brake air inlet and the brake air inlet. A structure in which an exhaust passage for opening is provided is preferable.
[0023]
DETAILED DESCRIPTION OF THE INVENTION
An embodiment of an air turbine spindle according to the present invention will be described in detail below.
[0024]
1 and 2 (a) and 2 (b) show a first embodiment of the present invention having a structure in which a main shaft is supported by a hydrostatic air bearing. In the air turbine spindle according to the first embodiment, compressed air is blown to a plurality of recesses 43 provided on the outer periphery of a thrust plate 42b of a main shaft 41 from a turbine nozzle 44 disposed at a portion facing the recesses 43. Thus, the main shaft 41 is rotated.
[0025]
The main shaft 41 includes a shaft portion 42a and a thrust plate 42b provided at an end portion thereof, and is rotatably supported with respect to the housing 48 by a journal bearing portion and a thrust bearing portion described later. The housing 48 includes a substantially cylindrical first housing portion 48a, a circular lid-shaped second housing portion 48b integrally coupled to an end portion of the first housing portion 48a, and an inner diameter of the first housing portion 48a. The bearing sleeve 49 is fixed, and the bearing plate 58 is fixed to the inner end surface of the second housing portion 48b.
[0026]
A bearing sleeve 49 is fixed to the inner diameter of the first housing portion 48a by appropriate means such as shrink fitting, press fitting, or adhesion. The bearing sleeve 49 is formed with a journal bearing portion 52 having a journal bearing surface 51 facing the outer diameter surface of the shaft portion 42a of the main shaft 41 with a minute journal bearing gap 50 therebetween, and the end surface of the thrust plate 42b is minute. A thrust bearing portion 55 having a thrust bearing surface 54 facing each other through a thrust bearing gap 53 is formed. The bearing sleeve 49 is provided with a plurality of fine bearing nozzles 56 and 57 that are open to the journal bearing surface 51 and the thrust bearing surface 54.
[0027]
A bearing plate 58 is fixed to the inner end surface of the second housing portion 48b by appropriate means such as shrink fitting, press fitting, or adhesion. The bearing plate 58 is formed with a thrust bearing portion 61 having a thrust bearing surface 60 facing the end surface of the thrust plate 42b with a minute thrust bearing gap 59 therebetween. The bearing plate 58 is provided with a plurality of fine bearing nozzles 62 opened to the thrust bearing surface 60.
[0028]
A fixing ring 63 is fixed to the inner diameter of the end of the first housing portion 48a by appropriate means such as shrink fitting, press fitting, or adhesion. The fixing ring 63 is formed with a plurality of turbine nozzles 44 penetratingly formed at portions facing the concave portions 43 of the thrust plate 42b. The turbine nozzle 44 opens substantially tangentially along the outer periphery of the fixing ring 63 and communicates with the turbine air inlet 45 via an annular groove 46 formed in the first housing portion 48a.
[0029]
On the other hand, an annular groove 64 serving as a pressure chamber is formed on the end face of the thrust plate 42b. A brake is applied to the main shaft 41 during normal rotation from the annular groove 64 in the outer circumferential direction of the thrust plate 42b in the direction opposite to the turbine nozzle 44. A plurality of brake nozzles 65 for applying force are formed through. The brake nozzle 65 opens substantially tangentially along the outer periphery of the thrust plate 42 b and communicates with a brake air supply port 66 formed in the second housing portion 48 b through an annular groove 64. Further, the fixed ring 63 is provided with a fixed wing 67 for enhancing the brake effect at a portion facing the brake nozzle 65. The fixed wing 67 has an end face 69 at a position facing the brake nozzle 65 and perpendicular to the tangential direction in which the brake nozzle 65 opens.
[0030]
Here, on both sides of the annular groove 64, a gap seal 68 consisting of a minute gap is formed as a seal mechanism for preventing leakage of compressed air from the annular groove 64. The interior is maintained at a high pressure. Since this gap seal 68 can be formed simultaneously with the thrust bearing surface 60, it is desirable to form it on the same surface as the thrust bearing surface 60. Further, since the gap seal 68 is non-contact, the air turbine spindle is a particularly suitable seal structure without deteriorating characteristics such as high speed and high accuracy.
[0031]
The radial displacement and thrust displacement of the main shaft 41 are regulated by the compressed air flowing into the journal bearing gap 50 and the thrust bearing gaps 53 and 59 from the bearing nozzles 56, 57 and 62 of the bearing sleeve 49 and the bearing plate 58. The compressed air that has flowed into the journal bearing gap 50 and the thrust bearing gaps 53 and 59 is discharged directly from the end of the shaft portion 42a to the outside of the housing and also from the exhaust port 58.
[0032]
During forward rotation of the main shaft 41, the compressed air supplied from the turbine air supply port 45 is jetted from the turbine nozzle 44 of the fixed ring 63 toward the recess 43 of the thrust plate 42b via the annular groove 46. The recess 43 has a radial wall surface 47 at a position facing the turbine nozzle 44 and perpendicular to the tangential direction in which the turbine nozzle 44 opens. The jetted compressed air is blown to the radial wall surface 47 of the recess 43 to apply a rotational force to the main shaft 41 and is discharged from the exhaust port 58 to the outside of the housing.
[0033]
On the other hand, when the main shaft 41 is braked, the compressed air supplied from the brake air supply port 66 is ejected from the brake nozzle 65 through the annular groove 64 in the direction opposite to the normal rotation to apply a braking force to the main shaft 41. The jetted compressed air is blown to the end surface 69 of the fixed wing 67 of the fixed ring 63 to further enhance the braking effect, and the housing is opened from the exhaust port 58 via the circumferential groove 70 and the exhaust hole 71 of the fixed ring 63. It is discharged outside. At this time, the supply of compressed air that rotates the main shaft 41 in the forward direction is interrupted.
[0034]
In the first embodiment, the same number of exhaust holes 71 and exhaust ports 58 and the same number of fixed blades 67 are provided for braking as the number of turbine nozzles necessary for forward rotation, and the brake nozzle 65 Is set so as to be relatively prime to the number of the fixed blades 67 within a range where sufficient performance can be obtained, thereby exhibiting effects such as vibration suppression. In this embodiment, compressed air for braking is supplied from one end face side of the thrust plate 42b, but the present invention is not limited to this, and the other end face side of the thrust plate 42b, Or the structure supplied from the outer peripheral surface side of the axial part 42a is also possible. The air turbine spindle of the first embodiment is suitable for applications such as electrostatic coating that require acceleration and deceleration in a short time.
[0035]
3 and 4 (a) and 4 (b) show a second embodiment of the present invention, and its basic configuration is the same as that of the first embodiment described above (FIGS. 1 and 2 (a) and (b)). Since they are the same, the same parts are denoted by the same reference numerals, and redundant description is omitted. The only difference from the first embodiment is that there is no fixed wing 67. Even when there is no fixed blade 67 in this way, when the main shaft 41 is braked, the compressed air supplied from the brake air supply port 66 is jetted from the brake nozzle 65 in the reverse direction to the forward rotation via the annular groove 64. A braking force is applied to the main shaft 41.
[0036]
5 and 6 show a third embodiment of the present invention. The same parts as those in the first embodiment are denoted by the same reference numerals, and redundant description is omitted. In the third embodiment, a pressure chamber 72 that opens to the end surface side of the thrust plate 42b of the main shaft 41 is provided, and the pressure chamber 72 faces away from the turbine nozzle 44 in the outer peripheral direction of the shaft portion 42a of the main shaft 41. In addition, a plurality of brake nozzles 73 for penetrating the main shaft 41 during normal rotation are formed penetratingly. The brake nozzle 73 communicates with a brake air supply port 74 formed in the second housing portion 48 b via the pressure chamber 72. As in the case of the first and second embodiments, a gap seal 68 including a minute gap is formed around the pressure chamber 72, and the inside of the pressure chamber 72 is maintained at a high pressure.
[0037]
During braking of the main shaft 41, compressed air supplied from the brake air supply port 74 is ejected from the brake nozzle 73 in the reverse direction to the normal rotation via the pressure chamber 72, thereby applying a braking force to the main shaft 41. The jetted compressed air is discharged from the exhaust port 58 of the first housing portion 48 a to the outside of the housing via the exhaust port 76 provided in the bearing sleeve 49. At this time, the supply of compressed air that rotates the main shaft 41 in the forward direction is interrupted.
[0038]
In the third embodiment, the fixed blade 67 for braking is not provided, but a surface that receives the blowing force of the compressed air ejected from the brake nozzle 73 is formed on the portion of the bearing sleeve 49 that faces the brake nozzle 73. You may make it provide the unevenness | corrugation which exhibits the same function as the formed structure, for example, the fixed wing | blade 67 in 1st Embodiment. Further, the position where the brake nozzle 73 is formed may be any position other than the third embodiment, for example, the axial center of the main shaft 41.
[0039]
7 and 8 show a fourth embodiment of the present invention. The same parts as those of the third embodiment are denoted by the same reference numerals, and the duplicate description is omitted. The spindle of the fourth embodiment has a structure for supplying compressed air for brake to the main shaft 41 from the radial direction. That is, a pressure chamber 77 is provided inside the main shaft 41, and a braking force is applied from the pressure chamber 77 to the main shaft 41 during normal rotation in the direction opposite to the turbine nozzle 44 in the outer peripheral direction of the shaft portion 42 a of the main shaft 41. A plurality of brake nozzles 73 are formed through.
[0040]
A brake air supply hole 78 communicating with the pressure chamber 77 is opened in the main shaft 41, and an annular groove 79 is formed in the inner diameter surface of the bearing sleeve 49. The brake nozzle 73 communicates with the brake air supply port 80 of the first housing portion 48a through the pressure chamber 77, the brake air supply hole 78, and the annular groove 79. The position where the brake air inlet 80 is formed may be an arbitrary position of the shaft portion 42a of the main shaft 41 as long as it is in the radial direction. As in the case of the first to third embodiments, gap seals 81 composed of minute gaps are formed on both sides of the annular groove 79, and the inside of the pressure chamber 77 is maintained at a high pressure.
[0041]
When the main shaft 41 is braked, the compressed air supplied from the brake air supply port 80 is introduced into the pressure chamber 77 via the annular groove 79 and the brake air supply hole 78 and is ejected from the brake nozzle 73 in the direction opposite to the normal rotation. Thus, a braking force is applied to the main shaft 41. The jetted compressed air is discharged from the exhaust port 58 of the first housing portion 48 a to the outside of the housing via the exhaust port 76 of the bearing sleeve 49. At this time, the supply of compressed air that rotates the main shaft 41 in the forward direction is interrupted.
[0042]
In the first to third embodiments described above, since the compressed air for braking is supplied from the axial direction, the main shaft 41 may receive an axial force by the compressed air. When the influence of this axial force cannot be ignored due to the specifications of the air turbine spindle, a structure for supplying compressed air for braking from the radial direction as in the fourth embodiment is preferable.
[0043]
Even in the case of the first to third embodiments, the thrust bearing portion 55 located on the opposite side of the thrust bearing portion 61 to which the compressed air for braking is supplied is designed to have a large load capacity. The influence of contact and wear at the thrust bearing portion 55 can be suppressed against the axial force. As a design for increasing the load capacity of the thrust bearing portion 55, for example, (1) the area of the thrust bearing portion 55 is made larger than that of the thrust bearing portion 61, (2) the inner diameter of the bearing nozzle 57 is made larger, 3) Increasing the number of bearing nozzles 57, 4) providing only a thrust bearing surface 54 of the thrust bearing portion 55 with a shallow groove that allows the bearing nozzles 57 to communicate with each other.
[0044]
Further, the influence of contact and wear at the thrust bearing portion 55 can also be suppressed by reducing the axial force. As a design for reducing the axial force, a structure is provided in which an exhaust passage for opening to the atmosphere is provided between the thrust bearing 61 and the brake air supply port 66 where the annular groove 64 is located on the side communicating with the brake air supply port 66. can do.
[0045]
Specifically, FIG. 9 shows a case where means for reducing the axial force received by the main shaft 41 is provided in the air turbine spindle of the first embodiment (see FIG. 1). The same parts as those in FIG. The means for reducing the axial force is also provided in the second embodiment shown in FIGS. 3 and 4 (a) and 4 (b) and the third embodiment shown in FIGS. 5 and 6. Is possible.
[0046]
In the air turbine spindle shown in FIG. 9, an exhaust passage 84 for opening to the atmosphere comprising an exhaust circumferential groove 82 opened in the thrust bearing gap 59 of the thrust bearing portion 61 and an exhaust port 83 communicating with the circumferential groove 82 is provided. It is provided in the second housing part 48b. The exhaust passage 84 for opening to the atmosphere needs to be disposed between the thrust bearing portion 61 and the gap seal 68 and between the bearing nozzle 62 of the thrust bearing portion 61 and the brake air supply port 66.
[0047]
During braking of the main shaft 41, compressed air flows into the annular groove 64 from the brake air supply port 66, and the inside of the annular groove 64 becomes high pressure by the gap seal 68. A small amount of air leaking from the outer peripheral side of the gap seal 68 formed on both the inner and outer peripheral sides of the annular groove 64 is discharged from the exhaust port 58 to the outside of the housing. On the other hand, a small amount of air leaking from the inner peripheral side of the gap seal 68 is discharged from the exhaust port 83 to the outside of the housing through the circumferential groove 82.
[0048]
Here, when there is no exhaust passage 84 for opening to the atmosphere as in the first embodiment shown in FIG. 1, a small amount of air leaking from the inner peripheral side of the gap seal 68 is between the thrust bearing portion 61. Therefore, the pressure distribution as shown in FIG. On the other hand, when there is an exhaust passage 84 for opening to the atmosphere as shown in FIG. 9, a small amount of air leaking from the inner peripheral side of the gap seal 68 does not collect between the thrust bearing portion 61 and the circumference. Since the gas is discharged from the exhaust port 83 through the groove 82, the pressure distribution as shown in FIG.
[0049]
The hatched portions shown in FIGS. 4A and 4B correspond to the axial force received by the main shaft 41 by the compressed air. That is, by providing the exhaust passage 84 for opening to the atmosphere between the thrust bearing portion 61 and the gap seal 68, the axial force received by the main shaft 41 by the compressed air supplied for braking can be reduced. The influence of contact and wear at the thrust bearing portion 55 can be suppressed.
[0050]
【The invention's effect】
According to the present invention, the brake nozzle is provided on the main shaft, and the brake performance is exhibited by ejecting compressed air from the brake nozzle on the outer periphery of the main shaft in the direction opposite to the normal rotation. As a result, it is not necessary to consider interference with the turbine nozzle when arranging the brake nozzle, so that a strong braking force can be secured without reducing the efficiency at the time of forward rotation of the main shaft, and the brake nozzle rotates. Compared to a structure in which a concave portion is provided on the main shaft, a structure having a smaller resistance when the main shaft is rotated forward can be realized.
[Brief description of the drawings]
FIG. 1 is a cross-sectional view showing a first embodiment of an air turbine spindle according to the present invention.
FIG. 2A is a cross-sectional view taken along the line AA of FIG.
(B) is sectional drawing which follows the BB line of FIG.
FIG. 3 is a cross-sectional view showing a second embodiment of the present invention.
4A is a cross-sectional view taken along the line CC in FIG. 3;
(B) is sectional drawing which follows the DD line | wire of FIG.
FIG. 5 is a cross-sectional view showing a third embodiment of the present invention.
6 is a cross-sectional view taken along line EE of FIG.
FIG. 7 is a cross-sectional view showing a fourth embodiment of the present invention.
8 is a cross-sectional view taken along line FF in FIG.
9 is a cross-sectional view showing an air turbine spindle provided with means for reducing the axial force received by the main shaft 41 in the first embodiment of FIG.
FIG. 10A is an explanatory diagram showing a pressure distribution according to a bearing nozzle outlet pressure and a brake supply air pressure in the first embodiment shown in FIG. 1;
(B) is an explanatory view showing the pressure distribution by the bearing nozzle outlet pressure and the brake supply air pressure in the air turbine spindle of FIG. 9.
FIG. 11 is a cross-sectional view showing an example of a conventional air turbine spindle.
12 is a cross-sectional view taken along the line GG of FIG.
FIG. 13 is a cross-sectional view showing another example of a conventional air turbine spindle.
14A is a cross-sectional view taken along line HH in FIG.
(B) is sectional drawing which follows the II line | wire of FIG.
[Explanation of symbols]
41 Spindle
42b Thrust plate
43 recess
44 Turbine nozzle
48 housing
50 Journal bearing clearance
53 Thrust bearing clearance
54 Thrust bearing surface
55 Thrust bearing
56 Bearing nozzle
57 Bearing nozzle
59 Thrust bearing clearance
60 Thrust bearing surface
61 Thrust bearing
62 Bearing nozzle
64 Pressure chamber (annular groove)
65 Brake nozzle
66 Brake inlet
68 Clearance seal
84 Exhaust passage for opening to the atmosphere

Claims (9)

In an air turbine spindle that rotates a main shaft by blowing compressed air from a plurality of turbine nozzles disposed in a portion of a housing facing the concave portion to a plurality of concave portions provided on the outer periphery of the main shaft.
An air turbine spindle characterized in that a plurality of brake nozzles are provided on a main shaft in a direction opposite to the turbine nozzles, and a brake air supply port communicating with the brake nozzles is provided in the housing. A journal bearing surface facing the outer diameter surface of the main shaft with a journal bearing gap, and a housing having a plurality of bearing nozzles each opened to a thrust bearing surface facing the end surface of the thrust plate of the main shaft with a thrust bearing clearance; 2. The air turbine spindle according to claim 1, wherein the main shaft is supported in a non-contact manner by flowing compressed air from each bearing nozzle into the bearing gap. The air turbine spindle according to claim 1, wherein the brake nozzle is disposed in the vicinity of a recess provided in the main shaft. The air turbine spindle according to any one of claims 1 to 3, wherein a surface that receives a blowing force of compressed air ejected from the brake nozzle is formed at a portion facing the brake nozzle. The air turbine spindle according to any one of claims 1 to 4, wherein a pressure chamber is provided in the main shaft, and a brake nozzle and a brake air supply port are communicated with each other through the pressure chamber. The thrust chamber is provided on the thrust plate of the main shaft, and among the thrust bearing portions respectively formed on both end surfaces of the thrust plate, the thrust bearing portion located on the opposite side to the side communicating with the brake air supply port. 6. The air turbine spindle according to claim 5, wherein at least one of a means for increasing a load capacity and a means for reducing an axial force applied to the main shaft by the compressed air for braking is provided. The means for reducing the axial force received by the main shaft by the brake compressed air is an air release provided between a thrust bearing portion located on the side where the pressure chamber communicates with the brake air supply port and the brake air supply port. The air turbine spindle according to claim 6, wherein the air turbine spindle is an exhaust passage. The air turbine according to any one of claims 5 to 7, wherein a seal mechanism for preventing leakage of compressed air from the pressure chamber is provided between the pressure chamber and a brake air supply port of the housing. spindle. The air turbine spindle according to claim 8, wherein the seal mechanism is a gap seal formed between the main shaft and the housing.

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