KR20080054893A - Compensation unit structure for a boring machine - Google Patents

Abstract

A structure for compensating a tool of a boring machine is provided to prevent a hydraulic oil necessary for the operation of a tool compensation unit from being mixed with a coolant necessary for a boring operation. A booster body(3) is formed with a coolant introducing passage(1). A main shaft(7) is formed at the central portion thereof with a hydraulic oil passage(5). A hydraulic oil supplying nipple(9) is coupled to one end of the main shaft such that the hydraulic oil supplying nipple relatively rotates. A coolant passage(11) is provided in the main shaft. The coolant passage is spaced apart from the hydraulic oil passage. A coolant transmitting unit connects the coolant introducing passage to the coolant passage.

Description

Compensation unit structure for boring machine

1 is a view illustrating a state in which a tool compensation unit is installed in a general boring machine,

2 is a view for explaining the internal structure of the oil booster,

3 is a view showing the internal structure of the oil booster according to the present invention.

<Brief description of symbols for the main parts of the drawings>

One; Coolant inlet flow path 3; Booster Body

5; Oil pressure line 7; Main shaft

9; Hydraulic oil supply nipple 11; Coolant flow path

13; Connecting flange 15; Protruding pipe

17; Connecting groove 19; Air plug

21; Drain plug

The present invention relates to a tool compensating unit structure of a boring machine, and more particularly to a technique for preventing the mixing of the pressure oil required for the operation of the tool compensating unit and the coolant required for the boring operation.

1 is a view illustrating a structure in which a tool compensation unit is mounted on a boring machine, and converts pneumatic pressure supplied from a hydraulic pressure converter 500 into hydraulic pressure to supply pressure oil to an oil booster 502, and the oil booster 502. The connecting flange 504 provided at the right end of the () is connected to the spindle 508 through the adapter flange 506, the spindle 508 is rotatably supported by the fixed body 510 pulley ( The rotational force is transmitted through 512.

The right end of the spindle 508 is provided with a boring holder 516 through a radial setting head 514, the boring holder 516 is mounted with a boring insert to rotate the rotational force transmitted from the spindle 508 It is intended to boring the actual workpiece.

The tool compensation unit is composed of the oil pressure transducer 500, the oil booster 502 and the radial setting head 514, the oil booster 502 and the radial setting head 514 is a hydraulic capillary tube (hydraulic capillary tube; 518), the radial setting head 514 is moved radially in the range of up to several hundred micrometers by the hydraulic pressure supplied from the oil booster 502, the wear of the boring insert, etc. It is supposed to compensate.

Meanwhile, in the boring operation as described above, chips and heat are generated during the operation, and a cooling liquid must be supplied for cooling and removing foreign substances. As shown in FIG. 1, an oil booster 502 is provided. Cooling water is supplied through the cooling water to the boring holder 516.

Inside the oil booster 502, the pressure oil supplied from the pneumatic pressure transducer 500 must be passed to the hydraulic capillary tube 518 inside the spindle 508, and at the same time, the coolant flows into the oil booster 502. The hydraulic capillary tube 518 inside the spindle 508 should be supplied to the boring holder 516 through a hollow portion.

Figure 2 shows the internal structure of the oil booster 502, the direction is shown in the opposite direction to FIG.

Looking at the pipeline through which the pressure oil passes, the pressure oil supplied to the end cap 520 of the pneumatic pressure transducer 500 is supplied to the connection pipe 524 through a fixed pipe 522 fixed to the end cap 520. The connection pipe 524 is connected to the hydraulic capillary tube 518 and rotates to transfer the pressure oil, so that the fixed side seal 526 and the fixed pipe 522 and the connection pipe 524 are connected to each other. Relative rotation is achieved while maintaining a closed state by the rotation side seal 528.

On the other hand, when looking at the passage through which the coolant passes, the coolant flows into the fixed block 530 to which the end cap 520 is fixed and passes through a portion where the fixed pipe 522 and the connection pipe 524 are connected. It is to be supplied to the inside of the spindle 508 through the connection pipe 524 outside.

By the way, the portion where the fixed side seal 526 and the rotating side seal 528 is installed is likely to generate a gap in the contact portion due to the relative rotation between each other, if such a gap occurs, a problem that the coolant is mixed into the pressure oil occurs When the coolant and the pressurized oil are mixed as described above, the radial setting head 514 may not operate properly.

The present invention has been made to solve the problems as described above, by essentially blocking the mixture of the coolant and the pressurized oil, thereby improving the durability of the tool compensation unit, it is possible to achieve a more stable and accurate boring operation The object is to provide a tool compensation unit structure of a boring machine.

Boring machine tool compensation unit structure of the present invention for achieving the object as described above

A booster body in which a coolant inflow passage is formed in the circumferential direction;

A main shaft rotatably mounted while penetrating the booster body and having a pressure oil passage in the center;

A hydraulic oil supply nipple connected to one end of the main shaft to be supplied with a hydraulic oil and supplied to the hydraulic oil pipe;

A cooling liquid flow path formed spaced apart from the pressure oil pipe path in the main shaft;

Coolant connection means for connecting a coolant inflow channel formed in the fixed booster body and a coolant channel of the rotating main shaft to enable delivery of a coolant;

Characterized in that configured to include.

Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings.

The present invention is made by changing the internal structure of the oil booster constituting the tool compensation unit, referring to Figure 3, the embodiment of the present invention includes a booster body (3) formed with a coolant inlet flow path (1) in the circumferential direction; A main shaft 7 rotatably mounted while penetrating the booster body 3 and having a pressure oil passage 5 in the center thereof; A hydraulic oil supply nipple 9 connected to one end of the main shaft 7 so as to be supplied with a hydraulic oil and supplied to the hydraulic oil pipe line 5; A coolant flow path 11 formed spaced apart from the pressure oil pipe path 5 in the main shaft 7; It comprises a coolant inlet flow path (1) formed in the fixed booster body (3) and a coolant connection means for connecting the coolant flow path (11) of the rotating main shaft (7) to enable the transfer of the coolant.

In addition, the other end of the main shaft (7) is connected to the connecting flange 13, the structure of the pressure oil pipe (5) is communicated through the central portion and the coolant flow passage (11) and the central portion By communicating through the spaced apart portion, the pressure oil pipe (5) can be connected to the hydraulic capillary tube inside the spindle, the coolant flow path (11) is to be connected to the hollow inside the spindle. have.

In the present embodiment, the coolant connecting means is provided on the protruding pipe 15 protruding toward the main shaft 7 from the coolant inflow passage 1 of the booster body 3 and the circumferential surface of the main shaft 7. It is formed to include the connecting pipe 17 is inserted into the protruding pipe 15 and communicated with the coolant flow path (11).

On the other hand, the booster body 3 is connected to the air plug 19 for supplying the air purge air on the upper side, the lower side is provided with a drain plug 21 for draining the coolant that may leak.

As shown in the tool compensation unit structure of the boring machine of the present invention configured as described above, the coolant is introduced into the coolant inlet flow path 1 of the booster body 3, the protruding pipe 15, the connecting groove 17 And the cooling liquid flow path 11 of the main shaft 7 are supplied to the inner hollow part of the spindle.

Meanwhile, the pressurized oil is supplied to the pressurized oil supply nipple 9 and supplied to the hydraulic capillary tube installed inside the spindle through the pressurized oil line 5 of the main shaft 7. It has a completely isolated flow path.

Therefore, the pressurized oil and the coolant supplied through the oil booster of the tool compensation unit operate without mixing or interference with each other to ensure the precision and stability of the boring operation. By eliminating the seal structure, the effect of greatly improving durability can be obtained.

According to the present invention as described above, by providing a pressure oil and coolant supply structure that can essentially block the mixing of the coolant and the pressurized oil, to improve the durability of the tool compensation unit, it is possible to achieve a more stable and accurate boring operation.

Claims (3)

A booster body in which a coolant inflow passage is formed in the circumferential direction; A main shaft rotatably mounted while penetrating the booster body and having a pressure oil passage in the center; A hydraulic oil supply nipple connected to one end of the main shaft to be supplied with a hydraulic oil and supplied to the hydraulic oil pipe; A cooling liquid flow path formed spaced apart from the pressure oil pipe path in the main shaft; Coolant connection means for connecting a coolant inflow channel formed in the fixed booster body and a coolant channel of the rotating main shaft to enable delivery of a coolant; Boring machine tool compensation unit structure, characterized in that comprising a. The method according to claim 1, It is connected to the other end of the main shaft and the pressure oil pipe passage communicates through the center portion and the coolant flow passage communicates through the portion spaced from the central portion, the pressure oil pipe passage to the hydraulic capillary tube inside the spindle Boring machine tool compensation unit structure characterized in that it further comprises a connection flange to be connected, and the coolant flow path to be connected to the hollow inside the spindle. The method of claim 1, wherein the coolant connecting means A protruding pipe protruding toward the main shaft from the coolant inflow passage of the booster body; A connection groove formed on a circumferential surface of the main shaft and into which the protruding pipe is inserted and in communication with the coolant flow path; Boring machine tool compensation unit structure, characterized in that comprising a.

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