KR20150105901A - Cleaning Tools - Google Patents

Abstract

The present invention relates to a cleaning tool mounted on a machining center which can widely and efficiently clean and wash a cutting chip and a foreign substance which are generated in a process of cutting an object to be cut by the machining center without limiting a cleaning range. The cleaning tool mounted on a main shaft of the multi-axial drive type machining center comprises: a connection unit having a flow path connected to a coolant supply path arranged in the main shaft; and a spray nozzle which rotates in the perpendicular direction of a shaft of the main shaft in a front end side of the connection unit.

Description

Cleaning Tools

The present invention relates to a cleaning tool mounted on a machining center for cutting applications.

Conventionally, a machining center is used for cutting a workpiece.

The machining center is configured to automatically exchange tools mounted on the main spindle, and the main spindle is configured to be able to perform the movement control in the X-axis, Y-axis, and Z-axis directions orthogonal to each other.

When the workpiece is cut by the machining center operating as described above, a large amount of cutting chips are attached to the inner wall of the machine or the workpiece.

Therefore, conventionally, a cutting gun is used separately from the machining center, or the cutting chips are cleaned using the shower cutting oil installed in the machine.

In addition to the machining center, a shower gun installed outside the machine was cumbersome and complicated to perform a cleaning operation by the operator holding a shower gun.

There is also a so-called "ceiling shower coolant" in the shower coolant.

The ceiling shower coolant is mounted on the upper part of the machining center so that the cutting oil is sprayed toward the lower side. However, since the cutting chips are fine and piled up in very narrow places and the cutting oil is a sticky liquid, The cutting oil hardens together with the cutting chips, so that the cleaning operation is often difficult and can not be removed.

The shower coolant also has a spindle center through coolant for the spindle.

The spindle centrifugal cutting fluid is configured to discharge the cleaning liquid through a hole formed in the tip of the tool through a cutting oil supply passage formed along the main axis of the machining center and the inner axis of the tool to remove the cutting chip.

However, since the conventional spindle center through cutting oil can move the main axis in the three-dimensional direction, it is impossible to form the main axis and the cleaning tool in the form of a slope, so that the cleaning range is limited. There was a defect due to the chip because it was not possible.

In order to solve the above-described problems, the technology described in Patent Document 1 has been proposed.

The technique disclosed in Patent Document 1 is equipped with a side through coolant holder and is equipped with a spray nozzle for cutting oil mounted on the main shaft of the machining center and rotatable in the vertical direction.

However, in Patent Document 1, the spindle rotational driving force of the machining center is converted into the up-and-down rotation of the tip of the nozzle, but it can not be turned in the left-right direction.

Therefore, the cleaning range is still limited, and there is a problem in that it is impossible to efficiently remove foreign matter (chips) such as chips adhered to the inner wall of the machine.

Japanese Patent Application Laid-Open No. 4-315545

The present invention has been made in order to solve the above-mentioned problems of the related art, and it is an object of the present invention to solve the problem that the cleaning range of the cutting chips generated in the cutting process of the workpiece by the machining center is limited, And to provide a cleaning tool that is mounted on the apparatus.

In order to solve the above-described problems, the present invention provides a cleaning tool mounted on a main shaft of a machining center, the cleaning tool comprising: a joint portion that incorporates a flow passage joined to a coolant supply passage provided in the main shaft; And a spray nozzle unit formed to be rotatable along the spray nozzle.

Therefore, the jetting nozzle unit can be rotated in the diametrical direction, and the cleaning operation can be performed in conjunction with the moving function of the multiple axes of the machining center itself.

In other words, it is possible to perform cleaning in accordance with the rotation angle in the shaft radial direction, for example, the X-axis direction, in addition to the cleaning range in accordance with the axial movement in the three axial directions of the X, Y and Z axes of the machining center.

At the same time, the injection nozzle unit can be cleaned in a tilted state at a predetermined angle in the direction perpendicular to the main axis (tilted in the X-axis direction) and at a predetermined angle in the Y-axis direction.

As described above, when the main spindle is rotated in a state in which the injection nozzle portion is rotated at a predetermined angle (inclined with respect to the X-axis direction) in the direction perpendicular to the main axis, the coolant is radially radiated in the Y-axis direction In addition, it is also possible to set the main axis so that the jetting nozzle unit is directly located at the cleaning target, and to partially jet the jetting nozzle unit directly to the cleaning target.

The injection nozzle unit includes a rotation unit for fixing the injection nozzle unit main body and the injection nozzle unit main body to the joint so as to be rotatable, and a braking unit for stopping the rotation unit at a predetermined position.

Therefore, the injection nozzle unit can be rotated in a state where the rotation speed is reduced by the braking unit, and can be fixed at a predetermined angular position.

Further, the injection nozzle portion is in close contact with the control portion provided in the machining center, thereby limiting the rotation angle.

Therefore, the injection nozzle unit can change the angle with respect to the main axis by bringing the injection nozzle unit into close contact with the control unit using the multi-axis operation control function of the machining center.

And the control section is a shaft section provided in a vertical direction.

And the pivoting portion is constituted by a pivoting shaft portion which passes through the pivoting portion and which rotatably fixes the pivoting portion with respect to the joining portion.

Thus, the injection nozzle portion rotates around the rotation shaft portion.

The flow path includes a main flow path and a branch flow path branched from the main flow path.

At the same time, the pivot shaft portion is formed in a hollow state, and is communicated with the branch passage and communicated with the injection nozzle portion.

Therefore, the cutting oil flows from the cutting oil supply passage of the main shaft to the branch flow passage through the main oil passage and is supplied to the injection nozzle portion through the flow passage in the rotation shaft portion.

The braking portion of the present invention is constituted by a plate spring which is mounted on the pivot shaft portion and urges the pivot shaft support portion in a press contact manner.

Therefore, the braking portion attenuates the rotating speed by fixing the dish springs to the rotating shaft support portion by pressure contact, and fixes the braking portion at a desired angular position.

And the jetting nozzle unit is rotated 240 degrees along the direction perpendicular to the axis of the main shaft.

Therefore, the jetting nozzle unit can be cleaned not only forward of the jetting nozzle unit but also to the rear of the jetting nozzle unit, that is, to the direction of the main axis.

The cleaning tool of the present invention as described above has a joint portion having a built-in flow passage joined to a coolant supply passage provided in a main shaft of a machining center and an injection nozzle portion rotatably provided at the tip side of the joint portion, It is possible to perform a wide range of cleaning operations from the leading end of the main shaft in various directions.

That is, in addition to the cleaning range in accordance with the moving directions of the three axes on the X axis, Y axis, and Z axis of the machining center, cleaning is performed over a predetermined rotation angle (inclination angle) in the direction perpendicular to the axis of the main axis, It becomes possible.

At the same time, when the injection nozzle portion is rotated in a predetermined angle of rotation in a state in which the injection nozzle portion is rotated at a predetermined angle in a direction perpendicular to the main axis, cleaning can be performed in a state of being inclined at a predetermined angle in the Y axis direction.

As described above, when the main spindle is continuously rotated in a state in which the injection nozzle unit is rotated at a predetermined angle in the direction perpendicular to the main spindle, the coolant may be radiated in the radial direction in the Y-axis direction, It is possible to spray the cutting oil in various changed forms unlike the prior art since it is possible to select and directly spray the cleaning position by setting the position of the nozzle part so that it is possible to perform a wide range of cleaning so that various positions of the workpiece and the machine wall can be cleaned It is possible to efficiently remove the cutting chips.

Further, the injection nozzle unit is controlled by the rotation angle of the control unit provided in the machining center, so that the multi-axis operation control function of the machining center is used, and by bringing the injection nozzle unit into close contact with the control unit, It is possible to carry out a wide range of cleaning while reducing the manufacturing cost of the apparatus for controlling the rotation of the jet nozzle unit since the rotation driving mechanism of the jet nozzle unit is not required separately.

The cutting oil is supplied from the cutting oil supply passage of the main shaft to the branch flow passage through the main oil passage and is supplied to the injection nozzle portion through the flow passage in the rotary shaft portion. The cutting oil is supplied with a predetermined pressure from the cutting oil supply passage of the main shaft, Is supplied to the injection nozzle portion through the passage in the rotary shaft portion so that the supply pressure of the cutting oil is prevented from decreasing in the flow path of the rotary shaft portion and the coolant pressure is reduced by changing the rotation angle of the injection nozzle portion by the coolant supply pressure It is possible to maintain the spraying angle of the cutting oil in the required spray nozzle part.

Further, the diaphragm spring is press-fitted to the rotation shaft support portion so as to attenuate the rotation speed and fix it at a predetermined angle. When the injection nozzle unit is set at an arbitrary rotation angle position by the control unit, It is possible to perform a cleaning operation by fixing it to the position of the rotation angle so that a stable cleaning operation can be performed at a predetermined angular position.

Further, since the spray nozzle unit can be cleaned not only forward of the spray nozzle unit but also backward of the spray nozzle unit, that is, in the direction of the main axis, it can be cleaned remarkably wider than the conventional cleaning tool.

Fig. 1 is a conceptual diagram showing an embodiment of the inventive cleaning tool. Fig. 1 is an example showing a case where the injection nozzle unit is tilted by rotating at a predetermined angle in the X-axis direction of the machining center.
Fig. 2 is a view showing an embodiment of the present cleaning tool, and is an example of a state in which it is installed on a main shaft of a machining center as shown in Fig. 1. Fig.
3 is a longitudinal sectional view showing a state in which the angle of the spray nozzle is adjusted so that the spray nozzle and the joint are arranged on the same axis.
Fig. 4 is a plan view showing an embodiment of the present design cleaning tool, showing a state of being mounted on a main shaft of a machining center, and showing a rotation range of the injection nozzle portion by a dotted line.

Hereinafter, the cleaning tool of the present invention will be described in detail with reference to the accompanying drawings.

As shown in Figs. 1 to 4, the cleaning tool 10 of the present invention is mounted on the main shaft 11 of the machining center.

The cleaning tool 10 is provided with a bonding portion 14 incorporating a flow path 12 joined to a cutting oil supply path (not shown) provided in the main shaft 11 shown in Figs. 2 and 3, And a jetting nozzle unit 16 rotatably disposed on the leading end side 15 of the main shaft 11 in a direction perpendicular to the axis of the main shaft 11, that is, in the X axis plane, the Y axis plane and the Z axis plane direction.

The joining portion 14 includes a main body portion 41 formed in the cleaning mouth main body and a joining portion main body 13 formed at the rear end portion of the main body portion 41 by the same axial projections. And a protruded nozzle holding portion 42. [

3, the joint body 13 is formed of a tapered body made of a cylindrical body with its outer peripheral surface being rearwardly directed toward the rear, a large-diameter cutting oil passage 43 is formed therein, and a joint hole portion 31 Is provided.

Although the HSK type, the BT shank type, the NT type, or the like can be selected depending on the tapering method, the bonding method of the cleaning tool 10 and the main shaft 11 can be all selected. However, in the embodiment of the present invention, The HSK type is used in many cases.

A coolant passage 44 communicating with the coolant passage 43 is formed in the main body 41 and a coolant passage 12 is formed by the coolant passage 43 and the coolant passage 44.

The base end portion of the nozzle holding portion 42 has a cylindrical shape. A core (concave) portion is formed on the side surface portion and a pair of nozzle holding portions 47 constituting the rotation axis support portion 21 are provided at the tip end portion.

1 and 2 show a state in which the injection nozzle unit 16 is coupled to a machining center and rotated in the X-axis direction at a rotation angle of an angle? In the axial direction of the main shaft 11. [

3, the injection nozzle unit 16 includes an injection nozzle unit main body 17, a rotation unit 18 for fixing the injection nozzle unit main body 17 to the joint unit 14 in a rotatable manner, And a braking unit 19 capable of stopping the turning unit 18 at a predetermined position.

The rotary part 18 has a guide surface 49 at the rear end and is formed in a generally cuboid shape so as to penetrate the rotary part 18 and rotate the rotary part 18 with respect to the joint part 14 And is rotatably fixed to the nozzle holding piece 47 by a pivot shaft portion 20 which is fixed as much as possible.

The injection nozzle unit main body 17 has a nozzle shaft portion 50 and a nozzle 51 having a minute hole protruded from the tip end portion of the nozzle shaft portion 50. The nozzle shaft portion 50 An outflow path 52 is formed, and a nozzle hole 54 is provided at the tip end.

The braking portion 19 is attached to the axial end edge portion of the rotating shaft portion 20 and includes a disc spring 22 and a disc spring 22 for pressing and contacting the inner surface portion of the nozzle holding piece 47 And a washer 23 for suppressing abrasion.

In the embodiment of the present invention, the diaphragm spring 22 applies a pressure capable of stopping at the position of the angle at which the injection nozzle unit 16 is aimed at the rotation in the X-axis direction to the rotation unit 18 By the spring constant in design.

The injection nozzle unit 16 shown in Fig. 4 is provided with a spindle 11 (not shown) on the side of the control unit 25, which has the shaft portion 24 provided in the machining center and has no angle adjusting mechanism, And the rotation is controlled by fixing the rotation angle at a rotation angle when the contact is broken.

In the present embodiment, it is rotatable at an angle of 120 degrees at both sides in the axial direction of the main shaft 11 along the plane directions of the X axis, the Y axis and the Z axis,

The oil passage 12 is formed in the lower portion of the main oil passage 26 and branched into two in the Y axis direction from the main oil passage 26, And a branch flow path 27 connected to both sides of the shaft portion 20 in the axial direction.

The diverging flow passage 27 is divided into the above-mentioned portions formed in the right angle direction and the holes communicating with the outside formed at the portions located at the tip side 15 of the joining portion 14 by the clogging stoppers 36, Is sealed to prevent leakage.

The rotary shaft portion 20 is located at a lower portion of the branch passage 27 and a hollow portion 46 is formed in the hollow portion of the rotary shaft portion 20 so that the leg portions 40 in the axial direction are prevented from leaking So that it is not sealed.

The pivot shaft portion 20 has a narrow flow path 28 formed in the axial direction opposite to the flow path 27 at a position of engagement with the branch flow path 27 so that the narrow flow path 28 is provided with a branch flow path 27 An inflow hole portion 29 that serves as a flow passage of the pivot shaft portion 20 is formed through the pivot shaft portion 20.

Two outflow hole portions 30 are formed on both sides of the hollow portion of the pivot shaft portion 20 through the pivot shaft portion 20 in the axial center of the pivot shaft portion 20, A cylindrical gap portion 45 that is larger than the diameter of the rotation shaft portion 20 is formed at a portion corresponding to the rotation shaft portion 30 to form a flow path of the injection nozzle portion 16 from the rotation shaft portion 20.

The cutting oil flowing into the rotating shaft portion 20 from the inlet hole portion 29 flows into the outlet hole portion 30 through the gap portion 46 and is supplied to the outlet passage 52 through the cylindrical gap portion 45.

3, the nozzle holding portion 42 is provided with a fixed support portion 33 at an intermediate portion of the branch flow path 27 divided on both sides.

The stationary support portion 33 is formed by a spring 34 disposed in the spring device groove 48 and formed by a ball 35 positioned outwardly of the spring device groove 48 and a guide groove 48 formed on the guide surface 49 of the pivot portion 18 And a hole 53 into which the ball 35 is inserted.

The rotary shaft portion 20 is fixed to the rotary shaft portion 20 by a conical fixing screw 32 at the axial center so that the rotary shaft portion 20 and the jet nozzle portion 16 rotate integrally.

Hereinafter, preferred embodiments of the present invention will be described with reference to Figs. 1 to 4. Fig.

When the cleaning tool 10 of the present invention is used to clean a workpiece or a machine wall, a cutting tool mounted by an ATC (Auto Tool Changer) from the main shaft 11 is cleaned by the cleaning tool 10, So that the cleaning tool 10 is mounted on the main shaft 11.

In the above, the jetting nozzle unit 16 performs the alignment operation of the jetting nozzle unit 16 first.

The joint portion 14 is provided with the fixed support portion 33 composed of the spring 34 and the ball 35 so that the axial direction of the joint portion 14 and the axial direction of the injection nozzle portion 16 are aligned The injection nozzle portion 16 is aligned with the joint portion 14 when the injection nozzle portion 16 and the joint portion 14 are arranged on the same line in the axial direction.

Therefore, in the alignment operation of the injection nozzle unit 16, when the ball 35 of the fixed support unit 33 is inserted into the hole 53 by manually adjusting the injection nozzle unit 16, And the alignment operation of the injection nozzle unit 16 can be controlled more precisely.

The cleaning tool 10 arranged as described above is engaged with the main shaft 11.

In this case, the steel balls formed on the main shaft 11 of the machining center are pulled outward in the direction perpendicular to the shaft and fixed to the pair of joining hole portions 31 formed in the direction perpendicular to the axis of the joining portion 14, Is fixed to the main shaft 11.

As described above, the cleaning tool 10 fixed to the main shaft 11 rotates in conjunction with the rotation of the main shaft 11.

As described above, the injection nozzle unit 16 is arranged on the same axis as the joining portion 14 and the main shaft 11 by the alignment operation, and the cleaning tool 10 is moved in the X-, Y-, and Z- Is registered as a reference position in the control unit of the machining center and the angle of rotation and the position of the nozzle are corrected by the control unit of the machining center with respect to the rotation angle when the injection nozzle unit 16 is rotated, have.

Accordingly, when the cutting oil is supplied to the main shaft 11 of the machining center, the cutting oil flows from the oil passage (43), (44) provided in the joint portion (14) To the branch flow path 27.

The cutting oil is sequentially introduced into the gap portion 46 in the inflow hole portion 29 and the turning shaft portion 20 of the pivot shaft portion 20 from the tip end portion of the branch flow path 27, Is supplied to the nozzle hole 54 through the gap portion 45 through the outflow passage 52 of the injection nozzle portion 16 and is injected outside the injection nozzle portion 16.

Therefore, the injection nozzle unit 16 is disposed on the same axis as the main shaft 11, and the cutting oil is supplied straight to the tip of the nozzle unit 17 along the axial direction of the main shaft 11. [

In this state, the injection nozzle unit 16 for spraying the cutting oil on the same axis as the main shaft 11 is driven in the X-axis direction, the Y-axis direction and the Z-axis direction by the drive control by the control unit of the machining center, So that the cleaning tool 10 can also be moved to efficiently clean the required portion to be cleaned.

The cutting oil flows from the cutting oil supply passage of the main shaft 11 to the branch flow passage 27 through the main oil passage 26 and flows through the gap portion 46 in the pivot shaft portion 20, And is supplied to the outflow path 52 of the first part 16.

The cutting oil supplied at a predetermined pressure from the cutting oil supply passage of the main spindle 11 is supplied to the spray nozzle portion 16 through the gap portion 46 in the rotating shaft portion 20, It is possible to prevent the rotation angle of the injection nozzle unit 16 from being changed by the cutting oil supply pressure and to maintain the cutting oil injection angle of the target injection nozzle unit 16 .

On the other hand, the above-mentioned action is also the same when the jetting nozzle unit 16 is inclined at a predetermined angle in the X-axis direction.

Next, when it is desired to change the spraying direction of the cutting oil in the X-axis direction (horizontal direction), the main spindle 11 is moved in the X-axis direction by the control of the machining center so that the tip end of the spray nozzle unit 16 is controlled by the control unit 25 To the shaft portion 24,

By the contact operation as described above, the rotary portion 18 rotates around the rotary shaft portion 20 and rotates at the predetermined target angle in the upward and downward directions as shown in FIG.

The ball 35 constituting the fixed support portion 33 is pressed by the guide surface 49 so as to press the spring 34 against the pressing surface of the rotary shaft portion 20, And is released into the spring device groove 48, so that the state of engagement with the hole portion 53 is released, so that the injection nozzle portion 16 rotates smoothly.

In the present embodiment, the rotary shaft portion 20 is provided with the braking portion 19, so that the rotation speed is attenuated by the disc spring 22 constituting the braking portion 19 at the same time, 16 at the target angle.

Therefore, in this embodiment, it is possible to place the main shaft 11 at an inclination along the transverse direction of the angle? In the axial direction of the main shaft 11 shown in Figs. 1 and 2. As a result, it is possible to spray the cutting oil in the &thetas; direction to perform cleaning.

In this case, the angle setting of the injection nozzle unit 16 can be appropriately adjusted in accordance with the moving distance of the main shaft 11 in the X-axis direction from the initial position.

4, in the X-axis direction, the injection nozzle unit 16 is configured to rotate in the X-axis direction by 240 degrees in the axial direction of the main shaft 11 , And in the machining center, by controlling the amount of movement of the main shaft 11 in the X-axis direction, it is possible to pivot an angle of 120 degrees to one side in the axial direction of the main shaft 11. Therefore, The cutting oil can be sprayed to the proximal end of the cutting tool 11 so that a very wide range of cleaning can be performed.

When the main spindle 11 is rotated at an angle in a direction perpendicular to a predetermined axis by driving control of the machining center in a state where the injection nozzle unit 16 is rotated at a predetermined angle in the X axis direction, 16 can be cleaned in a state of being inclined at a predetermined angle in the Y-axis direction, and the cutting oil can be sprayed toward the upper side and the lower side of the main shaft 11 for cleaning.

      When the injection nozzle unit 16 is rotated at a predetermined angle in the X axis direction of the main shaft 11 and the main shaft 11 is continuously rotated by the driving control of the machining center, It is possible to spray the cutting oil in the radial direction, so that it is possible to perform three-dimensionally efficient cleaning work.

Therefore, since the cleaning tool 10 according to the present embodiment can spray the cutting oil in various deformed directions, it is possible to carry out a wide range of cleaning, so that cleaning is carried out to every corner of the workpiece and the machine wall, The cutting chips can be efficiently removed.

On the other hand, in the above-described embodiment, the shaft portion 24 provided at a predetermined interval in the vertical direction of the machining center has been described as an example, but the present invention is not limited to this but the shaft portion provided in the horizontal direction Do.

The specific configuration of the cleaning tool 10 is not limited to the above embodiment.

Industrial Applicability The cleaning tool according to the present invention has industrial applicability because it can be used widely in machining centers because it is possible to clean workpieces and machine inner walls that can not be cleaned in the past.

10: Cleaning tool 11: Spindle
12: flow path 13:
14: joint portion 15: distal end side
16: jet nozzle unit 17: jet nozzle unit main body
18: Rotating part 19:
20: pivot shaft portion 21: pivot shaft pivot portion
22: disc spring 23: washer
24: shaft portion 25:
26: Oil line 27:
28: narrow channel 29: inlet hole portion
30: Outflow hole part 31:
32: fixing screw 33:
34: Spring 35: Ball
36: stopping stopper 40:
41: main body portion 43, 44:
45: Cylindrical gap portion 46:
47: nozzle holding piece 48: spring device groove
49: main surface portion 50: nozzle shaft portion
51: nozzle 52:
53: hole portion 54: nozzle hole

Claims (8)

A cleaning tool mounted on a main shaft of a machining center of a multi-axle movable type, comprising: a joint portion for accommodating a flow passage to be connected to a coolant supply passage provided in the main shaft; And a spray nozzle part provided so as to be capable of spraying.
The method according to claim 1,
The injection nozzle unit includes an injection nozzle unit main body, a turning unit for fixing the injection nozzle unit main body to the joint unit so as to be rotatable,
And a braking unit capable of stopping the rotation unit at a predetermined position.
3. The method of claim 2,
And the jetting nozzle portion is brought into close contact with the control portion provided in the machining center to adjust the rotation angle.
3. The method of claim 2,
The cleaning tool according to claim 2, wherein the control portion is a shaft portion provided in a vertical direction.
3. The method of claim 2,
Wherein the pivoting portion constitutes a pivoting shaft portion which passes through the pivoting portion and which rotatably fixes the pivoting portion with respect to the abutment portion.
The method according to claim 1,
The flow path is constituted by a main oil path and a branch flow path branched from the main oil path and formed in the lower part of the main oil path. The rotation axis part communicates with the branch path formed in the hollow part, Wherein the cleaning means communicates with the cleaning means.
3. The method of claim 2,
Wherein the braking portion is constituted by a dish spring which is mounted on the rotating shaft and press-fitted to the rotating shaft portion protecting portion.
The method according to claim 1,
And the jetting nozzle unit is rotated by 240 degrees along the direction perpendicular to the axis of the main shaft.

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