Gas bearing pad

Abstract

The gas bearing pad includes a main body portion including a recess portion, a porous body fitted into the recess portion of the main body portion, and a bolt inserted into a bolt insertion hole provided in the porous body and fixing the porous body to the main body portion. A gas bearing is formed between the porous body and the base by blowing compressed gas from the main body portion through the porous body toward the base. A counterbore hole that accommodates a head portion of the bolt is provided in the bolt insertion hole. In the counterbore hole, a space is provided between a top surface that faces the guide surface in the head portion of the bolt and a bearing surface that faces the guide surface of the porous body.

Claims

1. A gas bearing pad comprising: a main body portion disposed on a base including a guide surface and including a recess portion on a facing surface that faces the guide surface; a porous body fitted into the recess portion of the main body portion; and a bolt inserted into a bolt insertion hole provided in the porous body to fix the porous body to the main body portion, wherein a gas bearing is formed between the porous body and the base by blowing compressed gas from the main body portion through the porous body toward the base, a counterbore hole that accommodates a head portion of the bolt is provided in the bolt insertion hole, and in the counterbore hole, a space is provided between a top surface of the head portion of the bolt that faces the guide surface and a bearing surface of the porous body that faces the guide surface.

2. A gas bearing pad according to claim 1, wherein when the gas bearing is formed, a clearance dimension from the bearing surface of the porous body to the top surface of the head portion of the bolt is greater than a clearance dimension from the guide surface to the bearing surface of the porous body.

Description

BRIEF DESCRIPTION OF DRAWINGS

(1) FIG. 1 is a cross-sectional view for describing one embodiment of a gas bearing pad according to the present invention.

(2) FIG. 2 is a bottom view of the gas bearing pad shown in FIG. 1.

DESCRIPTION OF EMBODIMENTS

(3) One embodiment of a gas bearing pad according to the present invention will be described in detail below with reference to the drawings.

(4) As shown in FIGS. 1 and 2, a gas bearing pad 10 of the present embodiment includes a main body portion 20 disposed on a base 11 including a guide surface 11a, and including a recess portion 21 on a facing surface 20a that faces the guide surface 11a; a porous body 30 fitted into the recess portion 21 of the main body portion 20; and a bolt 40 inserted into a bolt insertion hole 31 provided in the porous body 30 to fix the porous body 30 to the main body portion 20. The main body portion 20 is formed of ceramic or the like, the porous body 30 is formed of graphite or the like, and the bolt 40 is formed of a ferrous material such as steel.

(5) The main body portion 20 has a rectangular parallelepiped shape, and the circular recess portion 21 is formed on the facing surface 20a that faces the guide surface 11a. The main body portion 20 is formed with a gas flow path 22 for supplying compressed gas supplied from a compressed gas pipe (not shown) to the porous body 30 inside the recess portion 21.

(6) The porous body 30 is disk-shaped. A bearing surface 30a that faces the guide surface 11a of the porous body 30 is formed to be flush with the facing surface 20a of the main body portion 20. The bolt insertion hole 31 is formed in the central portion of the porous body 30. A counterbore hole 32 for accommodating a head portion 41 of the bolt 40 is formed on the bearing surface 30a side of the bolt insertion hole 31. An annular groove 33 serving as a flow path for compressed gas is formed around the bolt insertion hole 31 on the surface of the porous body 30 opposite to the bearing surface 30a (upper surface in FIG. 1). The porous body 30 is a porous material having an appropriate air permeability.

(7) In the present embodiment, the counterbore hole 32 of the bolt insertion hole 31 is formed with a depth greater than the thickness of the head portion 41 of the bolt 40. Therefore, in the counterbore hole 32, a space SP is formed between a top surface 41a that faces the guide surface 11a in the head portion 41 of the bolt 40 and the bearing surface 30a of the porous body 30.

(8) In the present embodiment, when the gas bearing is formed, a clearance dimension S1 from the bearing surface 30a of the porous body 30 to the top surface 41a of the head portion 41 of the bolt 40 is set to be greater than a clearance dimension S2 from the guide surface 11a of the base 11 to the bearing surface 30a of the porous body 30.

(9) In the gas bearing pad 10 configured as described above, the compressed gas is blown out from the gas flow path 22 of the main body portion 20 through the porous body 30 toward the guide surface 11a of the base 11, and accordingly, a gas bearing is formed between the porous body 30 and the base 11. Accordingly, the gas bearing pad 10 can move in a non-contact state with respect to the guide surface 11a of the base 11.

(10) As described above, according to the gas bearing pad 10 of the present embodiment, in the counterbore hole 32, the space SP is formed between the top surface 41a of the head portion 41 of the bolt 40 and the bearing surface 30a of the porous body 30. As a result, even when foreign matter enters between the gas bearing pad 10 in drive and the base 11, the intruded foreign matter will not enter the space SP and be caught between the head portion 41 of the bolt 40 and the base 11, and thus seizure of the head portion 41 of the bolt 40 to the base 11 can be prevented. Even when there is no air supply due to power failure or the like, the head portion 41 of the bolt 40 is not grounded to the base 11, and thus seizure of the head portion 41 of the bolt 40 to the base 11 can be prevented.

(11) According to the gas bearing pad 10 of the present embodiment, the clearance dimension S1 from the bearing surface 30a of the porous body 30 to the top surface 41a of the head portion 41 of the bolt 40 is set to be greater than the clearance dimension S2 from the guide surface 11a of the base 11 to the bearing surface 30a of the porous body 30. Therefore, even when the gas bearing pad 10 stops driving while foreign matter entered between the gas bearing pad 10 and the base 11, the intruded foreign matter is not caught between the head portion 41 of the bolt 40 and the base 11, and thus, the seizure of the head portion 41 of the bolt 40 to the base 11 can be prevented.

(12) According to the gas bearing pad 10 of the present embodiment, the space SP of the counterbore hole 32 becomes an air pocket, and thus constant pressure is accumulated in the space SP, and self-excited vibration caused by an air film can be reduced.

(13) Note that the present invention is not limited to those illustrated in the above embodiments, and can be modified as appropriate without departing from the gist of the present invention.

(14) For example, the shape of the main body portion and the porous body, whether an annular groove is provided in the porous body, the shape of the gas flow path, and the like can be freely set.

REFERENCE SIGNS LIST

(15) 10 Gas bearing pad 11 Base 11a Guide surface 20 Main body portion 20a Facing surface 21 Recess portion 22 Gas flow path 30 Porous body 30a Bearing surface 31 Bolt insertion hole 32 Counterbore hole 33 Groove 40 Bolt 41 Head portion 41a Top surface SP Space S1 Clearance dimension from bearing surface of porous body to top surface of head portion of bolt S2 Clearance dimension from guide surface of base to bearing surface of porous body