JP2008279570A - Machine tool - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a machine tool capable of preventing any inconvenient stripe from being formed in a machined surface of a workpiece by preventing any stop-feed phenomenon of a moving body which is moved via an inclined or vertical sliding part. <P>SOLUTION: A moving body 5 of a machine tool 1 is supported by a saddle 7 via an inclined sliding part 6, and a tool is mounted thereon. Since the center of gravity G of the moving body is deviated from the sliding part in plan view, the downward pressure FL is applied at the lower part position PL of the sliding part while the upward floating force FH is applied at the upper part position PH, and the moving body is supported in an unbalanced state. At the upper position of the sliding part, a roller 15 is subjected to rolling contact with a lower side 13 on a supporting part side, a slide member 10 is pressed in the separating direction from a lower surface 13 on the supporting part side by the reaction force on the roller, and the slide member is slidably brought into contact with the saddle with a very small space therebetween. <P>COPYRIGHT: (C)2009,JPO&INPIT

Description

  The present invention relates to a machine tool in which a moving body is supported in an unbalanced state on a moving body support portion via a sliding portion that is inclined or perpendicular to a horizontal plane.

Regarding a machine tool in which a moving body is supported by a moving body support section through an inclined sliding section, Patent Document 1 (Japanese Patent Laid-Open No. 4-283003) proposes a carriage structure in an NC lathe. .
In this NC lathe, a balancing cylinder is attached in order to balance a moving body attached to an inclined guide surface (paragraph 0016 of Patent Document 1).
Japanese Patent Laid-Open No. 4-283003

  However, in the NC lathe described in Patent Document 1, since the center of gravity of the moving body is out of the sliding portion in plan view, the moving body is supported in an unbalanced state by the moving body support portion. As a result, a force acts in a direction in which the moving body bends forward and falls due to its own weight, but there is no description regarding a configuration for suppressing this.

FIG. 11 is a diagram showing a conventional technique, FIG. 11A is a schematic configuration diagram of a conventional machine tool, FIG. 11B is an enlarged cross-sectional view of a portion B of FIG. 11A, and FIG. It is explanatory drawing which shows a finished workpiece.
A machine tool 101 shown in FIG. The moving body 105 includes a tool post 103 to which a tool (a turning tool in this case) 102 is attached, and a feed base 104 that supports the tool post 103 to be movable.
The slide member 110 of the moving body 105 is supported by a saddle 107 as a moving body support portion via a sliding portion 106 inclined with respect to the horizontal plane L0, and is relatively movable in the X-axis direction. Yes. A plurality of tools 102 are attached to the tool post 103.
Since the center of gravity G of the moving body 105 deviates from the sliding portion 106 in a plan view, a downward pressing force FL acts at the lower position PL of the sliding portion 106, and upward at the upper position PH of the sliding portion 106. Floating force FH is applied. As a result, the moving body 105 is bent forward by its own weight W and supported by the saddle 107 in an unbalanced state.

Since the sliding portion 106 is inclined with respect to the horizontal plane L0, the sliding member 110 of the moving body 105 is not smooth and discontinuous when the moving body 105 moves in the X-axis direction via the sliding portion 106. There is a case where a so-called “accumulated feed phenomenon” in which an operation is performed occurs.
The “accumulation feed phenomenon” of the moving body 105 is caused by the first cause that the moving body 105 is supported in an unbalanced state on an inclined surface, and a portion with a high surface pressure (in particular, the upper portion of the sliding portion 106). When the coolant (cutting fluid) La enters the gap d at the position PH or the lower position PL), the lubricating oil film disappears and the sliding resistance of the sliding portion 106 increases, resulting in a synergistic effect. It is considered.
When the accumulation feed phenomenon occurs, the movement operation of the tool 102 is not smooth, and therefore a large number of inconvenient streaks 112 have entered the processed surface (here, the surface that has been turned) 109 of the workpiece 108. There is a risk of reducing the quality of the processed workpiece. The streak 112 is a minute one having an extremely small step having a height dimension of, for example, about 1 μm, and may be confirmed visually or by touching a finger.
Therefore, even when the sliding portion 106 is inclined and the moving body 105 is supported in an unbalanced state, a processing technique that does not include such inconvenient lines 112 on the processed surface 109 of the workpiece 108 is required. It was done. Further, since the sliding contact surface of the sliding portion 106 is in partial contact, there is a tendency that the wear of the sliding contact surface advances and the life is shortened.

  The present invention has been made to solve such a problem, and prevents the occurrence of a reservoir feed phenomenon in a movable body that is movable through an inclined or vertical sliding portion, thereby processing a workpiece. It is an object of the present invention to provide a machine tool capable of processing so that a finished surface becomes a smooth surface without inconvenient lines.

In order to achieve the above-described object, a machine tool according to the present invention is supported by a movable body support portion through a sliding portion that is inclined or perpendicular to a horizontal plane and is relatively movable, and a tool. Since the center of gravity of the moving body deviates from the sliding part in plan view, a downward pressing force acts at the lower position of the sliding part, and the upper part moves upward. A lifting force acts, and the moving body is supported by the moving body support portion in an unbalanced state, and the sliding portion includes a sliding upper surface of a slide member provided on the moving body, The sliding lower surface is in sliding contact with the lower surface on the support portion side and the upper surface on the support portion side formed on the movable body support portion, and is supported by the movable body so as to be rotatable at the upper position of the slide portion. The roller on which the force acts Rolling contact is made with the lower surface of the moving body support portion on the support portion side, and the slide member is pressed in a direction away from the lower surface of the support portion side by a reaction force applied to the roller, whereby the slide member is moved to the movable body. The support portion is in sliding contact with the support portion side lower surface and the support portion side upper surface with a small gap.
The roller is rotatably supported by a roller support member that is detachably attached to the movable body, and the roller support member can adjust the position of the roller with respect to the slide member. preferable.
The movable body support portion is a saddle that can move on a bed, and the movable body is supported by the saddle through the sliding portion so as to be movable, and can be moved to the feed base. And the sliding lower surface of the slide member of the feed base is in sliding contact with the upper surface of the support portion formed on the saddle, and the sliding upper surface of the slide member is the saddle. It is preferable that the sliding plate is slidably in contact with the lower surface of the fastening plate attached to the saddle plate, and the sliding member is regulated by the saddle so as not to move relative to the saddle in the left-right direction.
The machine tool according to another preferred embodiment is a movable body that is supported by a movable body support portion through a sliding portion that is inclined with respect to a horizontal plane or that is perpendicular to the horizontal plane, is relatively movable, and has a tool attached thereto. Since the center of gravity of the moving body deviates from the sliding portion in plan view, a downward pressing force acts at the lower position of the sliding portion, and an upward lifting force acts at the upper position. The moving body is a machine tool supported in an unbalanced state on the moving body support portion, and in the sliding portion, a sliding upper surface and a sliding lower surface of a sliding member provided on the moving body are The support part side lower surface and the support part side upper surface formed on the moving body support part are respectively slidably contacted, and at the upper position of the slide part, the lift force is attached to the slide member movably through a compression spring. Acting pressure The slide member is slidably brought into contact with the lower surface of the movable body support portion and the slide member is biased in a direction away from the lower surface of the support portion by the spring force of the compression spring. However, the movable body support portion is in sliding contact with the support portion side lower surface and the support portion side upper surface with a small gap.
Preferably, the machine tool is a lathe having the inclined sliding portion, a multi-tasking machine or a turning center, or a vertical machining center having the vertical sliding portion.

  Since the machine tool according to the present invention is configured as described above, it is possible to prevent the occurrence of the accumulation feeding phenomenon in the movable body that is movable through the inclined or vertical sliding portion, and the processed workpiece has been processed. The surface can be processed to be a smooth surface that does not contain inconvenient lines.

In the machine tool according to the present invention, the moving body to which the tool is attached is supported by the moving body support portion via a sliding portion that is inclined or perpendicular to the horizontal plane, and is relatively movable. Since the center of gravity of the moving body is disengaged from the sliding portion in plan view, a downward pressing force acts at the lower position of the sliding portion, and an upward lifting force acts at the upper position, so that the moving body Is supported in an unbalanced state on the moving body support.
At the upper position of the sliding portion, a roller that is rotatably supported by the movable body and acts as a lifting force is brought into rolling contact with the lower surface of the movable body supporting portion. Since the slide member of the moving body is pressed in a direction away from the lower surface of the support portion due to the reaction force applied to the roller, the slide member contacts the support portion side lower surface and the support portion side upper surface of the moving body support portion with a minute gap. It will be.
In this way, the occurrence of the accumulation feed phenomenon in the moving body is prevented, and when the workpiece is machined with the tool attached to the moving body, the machined surface of the workpiece is made a smooth surface without any inconvenient lines. The purpose is realized.

As a machine tool having a configuration in which the sliding portion of the moving body is inclined (or perpendicular) with respect to the horizontal plane and can be machined, in the following embodiments, the moving body (feeding) is performed via the inclined sliding portion. This shows the case of an NC lathe where the platform and the tool post) move.
The machine tool in the present invention may be a multi-task machine or a turning center having an inclined sliding portion, and may be a vertical machining center as another example. In the case of an inclined sliding part in an NC lathe or a multi-task machine, a moving tool is a tool post or a headstock that is attached to a movable body support such as a bed so as to be relatively movable. In the case of a vertical machining center, the spindle head (moving body) is supported by a column (moving body supporting portion) so as to be relatively movable via a sliding portion perpendicular to the horizontal plane, and the workpiece is cut. To do.
Moreover, the tool attached to the moving body of the present invention may be a cutting tool in addition to a turning tool.

Embodiments according to the present invention will be described below with reference to FIGS.
FIG. 1A is a schematic configuration diagram of a machine tool according to the present embodiment, FIG. 1B is an enlarged sectional view of a portion B of FIG. 1A, and FIG. 1C is an explanatory diagram showing a processed workpiece. It is.
2 is a perspective view of the machine tool, FIG. 3 is a perspective view showing a part of the machine tool, FIG. 4 is a left side view of the machine tool, and FIG. 5 is a perspective view showing a part of the machine tool. 6 is a perspective view of a feed base of the machine tool, and FIG. 7 is a partially enlarged perspective view of the feed base. 8 is a cross-sectional view taken along line VIII-VIII in FIG. 1A, and FIG. 9 is a cross-sectional view taken along line IX-IX in FIG.

As shown in FIG. 1, the machine tool 1 is an NC lathe provided with a moving body 5 to which a tool (here, a tool for turning) 2 is attached, and a Z axis on a bed 22 (FIG. 2). The saddle 7 that can move in the direction is a moving body support.
The moving body 5 is supported by a saddle 7 as a moving body supporting portion via a sliding portion 6 inclined with respect to the horizontal plane L0, and can be relatively moved on the saddle 7 in the X-axis direction. Yes. The moving body 5 is supported by the saddle 7 via the sliding portion 6 so as to be movable in the X-axis direction, and is supported by the feeding base 4 so as to be movable in the Yc-axis direction. And a tool post 3. The Yc axis is a so-called composite Y-axis.

The upper surface of the saddle 7 is inclined so that the front side is lowered, and the feed base 4 is supported on the upper surface of the saddle 7 so as to be relatively movable in the X-axis direction. The tool post 3 is supported by the feed base 4 and is relatively movable in the Yc axis direction. A plurality of tools for turning are attached to the tool post 3. The X-axis direction is inclined with a gentle inclination angle with respect to the horizontal plane L0 so that the front side is lower, and the Yc-axis direction is inclined with a larger inclination angle than the X-axis direction so that the front side is lower.
Since the center of gravity G of the moving body 5 is disengaged from the sliding portion 6 in plan view, a downward pressing force FL acts at the lower position PL of the sliding portion 6 and upward at the upper position PH of the sliding portion 6. The lifting force FH acts.
As a result, a moment is applied to the moving body 5 as shown by an arrow M by its own weight W, and the moving body 5 is in a forward bending posture, so that it is supported by the saddle 7 in an unbalanced state. .

A slide member 10 constituting the sliding portion 6 is provided on the moving body 5 and constitutes a part of the feed base 4. In the sliding portion 6, the sliding upper surface 11 and the sliding lower surface 12 of the sliding member 10 are in sliding contact with the supporting portion side lower surface 13 and the supporting portion side upper surface 14 formed on the saddle 7, respectively.
At the upper position PH of the sliding portion 6, the roller 15 that is rotatably supported by the moving body 5 and acts on the lifting force FH is in rolling contact with the support portion side lower surface 13 of the saddle 7. In the sliding portion 6, both the sliding contact surface and the roller 15 bear the load of the moving body 5.
The slide member 10 is pressed in a direction away from the support portion side lower surface 13 by the reaction force FH1 applied to the roller 15. As a result, the upward lifting force FH and the reaction force FH1 are balanced, and the slide member 10 is in sliding contact with the support portion side lower surface 13 and the support portion side upper surface 14 of the saddle 7 with minute gaps d1 and d2. Therefore, since the lubricant film is satisfactorily formed in the minute gaps d1 and d2 without entering the coolant, the sliding resistance of the sliding portion 6 is reduced.
By doing so, the occurrence of the “reservoir feeding phenomenon” in the movable body 5 movable in the X-axis direction via the sliding portion 6 inclined with respect to the horizontal plane L0 is prevented, and the movable body 5 is smoothly moved in the X-axis. Move in the direction.
When the workpiece 8 is machined with the tool 2 attached to the movable body 5 (here, turning), the processed surface (here, the surface that has been turned) 9 of the workpiece 8 becomes a conventional reservoir feed phenomenon. It becomes a smooth surface where the inconvenient streak (the streak 112 shown in FIG.

As shown in FIGS. 2 to 5, the machine tool 1 is a turning tool 2 attached to a tool post 3, and performs turning such as outer diameter machining, drilling, inner diameter machining, and inner diameter thread machining on a workpiece 8. Has the function of processing.
The machine tool 1 includes a base 20, a spindle base 21 that supports a spindle, a moving body 5 having a tool post 3, a feed base 4, and the like, a tool magazine (not shown) that stores a plurality of tools, and these tools. And an automatic tool changer (not shown). The machine tool 1 is controlled by a control device having an NC (numerical control) device and a PLC (programmable logic controller).
The bed 22 constitutes the base body 20 and is installed on the floor surface 23. The main shaft has a central axis line that is substantially horizontal with respect to the floor surface 23, and a chuck 24 is provided at the tip.
The headstock 21 is provided on the base body 20 on one side (here, the left side) in the left-right direction of the machine tool 1 and rotatably supports the main shaft. The direction parallel to the axis of the main axis is defined as the Z-axis direction (here, the left-right direction).

The tool post 3 of the movable body 5 can be mounted with at least a turning tool 2, and includes a Z-axis direction, an X-axis direction (here, an inclined direction) orthogonal to the Z-axis direction, and X It is movable in three directions, ie, the Yc axis direction (here, the further inclined direction) that is further inclined from the axial direction.
The machine tool 1 moves the tool 2 of the tool rest 3 against the workpiece 8 held by the chuck 24 in at least two directions (two directions of Z-axis direction and X-axis direction, or Z-axis direction and X-axis direction). The workpiece 8 can be turned by moving in three directions (Yc axis direction).

In addition, if a rotary tool (tool for cutting) is attached to the tool post 3 and rotated to make the workpiece 8 gripped by the chuck 24 non-rotated, the workpiece can be rotated with the rotary tool in the same manner as the machining center. 8 can be cut.
Thus, if the machine tool 1 is a multi-tasking machine that has a function of a machining center in addition to the function of a normal lathe, it is possible to perform various types of machining while holding the workpiece 8 with the chuck 24. Integrated processing from material workpiece to finished product is possible.

The machining area of the machine tool 1 is covered with a splash guard, an opening / closing cover, and the like so that chips, coolant, and the like are not scattered outside the machining area.
The base body 20 includes a bed 22 and a saddle 7 supported on the bed 22 so as to be movable in the Z-axis direction. The saddle 7 supports the movable body 5 so as to be movable in the X-axis direction and moves in the Z-axis direction. The feed table 4 supports the tool post 3 so as to be movable in the Yc axis direction, and moves on the saddle 7 in the X axis direction.

The upper surface of the bed 22 is inclined so that the front is lowered, and a pair of parallel Z-axis guide rails 30 are provided on the inclined upper surface of the bed 22 in the Z-axis direction (left-right direction). The slide body 31 is fixed. The Z-axis guide rail 30 and the slide main body 31 constitute a linear motion rolling guide. The saddle 7 is disposed so as to be movable along the Z-axis guide rail 30 so as to be movable in the Z-axis direction.
Between the two Z-axis guide rails 30, a screw shaft of a Z-axis ball screw is arranged in parallel with the Z-axis guide rail 30. A ball nut fixed to the saddle 7 is screwed into the screw shaft. A Z-axis servomotor is attached to the base 20, and the Z-axis servomotor rotates the screw shaft in the forward and reverse directions.
When the screw shaft rotates by being driven by the Z-axis servomotor, the saddle 7 to which the ball nut is fixed is guided and supported by the pair of Z-axis guide rails 30 and reciprocates in the Z-axis direction. The movement of the saddle 7 and the moving body 5 is the movement of the tool post 3 relative to the workpiece 8 in the Z-axis direction.

The saddle 7 is provided with a pair of parallel X-axis guide rails 28 in the X-axis direction, and a slide body 29 is fixed to the feed base 4. The X-axis guide rail 28 and the slide main body 29 constitute a linear motion rolling guide. The feed base 4 is disposed so as to be movable along the X-axis guide rail 28 so as to be movable in the X-axis direction.
Between the two X-axis guide rails 28, the screw shaft of the X-axis ball screw is arranged in parallel with the X-axis guide rail 28. A ball nut fixed to the feed base 4 is screwed into the screw shaft. An X-axis servomotor 32 is attached to the saddle 7, and the X-axis servomotor 32 rotationally drives the screw shaft in the forward and reverse directions.
When the screw shaft is rotated by being driven by the X-axis servomotor 32, the feed base 4 on which the ball nut is fixed is guided and supported by the pair of X-axis guide rails 28 and reciprocates in the X-axis direction. The moving operation of the moving body 5 including the feed base 4 and the tool rest 3 is the movement of the tool rest 3 with respect to the workpiece 8 in the X-axis direction.

The upper surface of the feed base 4 is inclined so that the front becomes lower, and the tool post 3 is supported on the upper face of the feed base 4 so as to be movable in the Yc axis direction. A pair of parallel Yc-axis guide rails 40 are provided on the upper surface of the feed base 4 in the Yc-axis direction. The Yc axis (generation Y axis) is inclined with respect to the horizontal plane L0 at a larger inclination angle than the X axis.
A slide body is fixed to the tool post 3. The Yc-axis guide rail 40 and the slide body constitute a linear motion rolling guide. The tool post 3 is disposed so as to be inclined along the Yc axis guide rail 40 so as to be movable in the Yc axis direction.
Between the two Yc-axis guide rails 40, a screw shaft of a Yc-axis ball screw is arranged in parallel with the Yc-axis guide rail 40. A ball nut fixed to the tool post 3 is screwed into the screw shaft. A Yc-axis servomotor 41 is attached to the top of the feed base 4. The Yc-axis servomotor 41 rotationally drives the screw shaft in the forward and reverse directions.
When the screw shaft rotates by being driven by the Yc axis servo motor 41, the tool post 3 to which the ball nut is fixed is guided and supported by the pair of Yc axis guide rails 40 and reciprocates in the Yc axis direction. The moving operation of the tool rest 3 is the movement of the tool rest 3 in the Yc axis direction with respect to the workpiece 8.
The tool post 3 has a turret 42 that performs a turning indexing operation. A plurality of tools such as the tool 2 are radially attached around the turret 42. When the turret 42 performs the turning indexing operation, a desired tool is indexed at the indexing position.

A spindle motor 46 is provided on the spindle stock 21. The spindle supported rotatably on the spindle stock 21 is rotated by a spindle motor while the workpiece 8 is gripped by the chuck 24.
When turning with the tool 2, the workpiece 8 held by the chuck 24 is rotated at a predetermined rotational speed by the main shaft. Then, the work 8 is turned by relatively moving the tool 2 provided on the tool post 3 in the Z-axis direction, the X-axis direction, and the Yc-axis direction.

As shown in FIGS. 1, 4 to 9, the sliding lower surface 12 of the sliding member 10 constituting a part of the feed base 4 is in sliding contact with the support portion side upper surface 14 of the saddle 7. Further, the sliding upper surface 11 of the sliding member 10 is in sliding contact with the support portion side lower surface 13 of the fastening plate 16 attached to the saddle 7.
A pair of rollers 15 is disposed on the feed base 4 so as to be rotatable at predetermined positions on the left and right. The roller 15 is supported by a roller support member 50 that is detachably attached to the feed base 4 that constitutes the moving body 5, and is rotatable about an axis CL.
The roller support member 50 is detachably fixed to the feed base 4 by a plurality of (here, two) tightening bolts 51, and a pair of left and right rollers are provided on the feed base 4. Since the roller support member 50 can slightly change the attachment position of the roller 15 with respect to the feed base 4 in the direction indicated by the arrow E, the position of the roller 15 with respect to the slide member 10 can be adjusted.
Therefore, the pressure acting between the lower surface of the fastening plate 16 (that is, the support portion side lower surface 13) and the roller 15 can be adjusted. As a result, the reaction force FH1 received by the roller 15 can be adjusted, and the upper and lower minute gaps d1 and d2 of the slide member 10 can be set to favorable dimensions.
Thus, since the roller support member 50 can accurately adjust the dimensions of the minute gaps d1, d2 between the slide member 10 and the saddle 7 in the sliding portion 6, the coolant does not enter the gaps d1, d2, and the lubricating oil film is formed. Thus, the sliding resistance in the sliding portion 6 can be reduced.
Further, since the roller support member 50 that supports the roller 15 can be attached to and detached from the feed base 4, if the roller 15 is worn or deformed, the roller support member 50 can be removed from the feed base 4 so that the roller 15 can be easily removed. Can be replaced.

Regarding the member that moves in the X axis direction and the member that does not move in the sliding portion 6, the saddle 7 on which the support portion side upper surface 14 is formed and the fastening plate 16 on which the support portion side lower surface 13 is formed are arranged in the X axis direction. Does not move. On the other hand, the slide member 10 on which the sliding lower surface 12 and the sliding upper surface 11 are formed, the feed base 4 to which the slide member 10 is attached, the roller support member 50 attached to the feed base 4, and the roller support member 50 The roller 15 attached to is moved in the X-axis direction.
The tool post 3 moves in the Yc-axis direction relative to the feed table 4, but if the feed table 4 moves in the X-axis direction, the tool post 3 also moves in the X-axis direction integrally with the feed table 4. .

The slide member 10 is regulated by the saddle 7 so as not to move relative to the saddle 7 in the left-right direction (Z-axis direction). As a result, the slide member 10 moves in the X-axis direction relative to the saddle 7 in a state where movement in the left-right direction (Z-axis direction) and the vertical direction (direction orthogonal to the X-axis direction) is restricted. To do.
As a result, the feed base 4 to which the slide member 10 is attached and the tool post 3 supported by the feed base 4 can also move relative to the saddle 7 in the X-axis direction.

Next, the operation of the machine tool 1 will be described.
When performing the turning process, the turret 42 of the tool post 3 is turned, and the desired tool 2 is indexed and positioned. In a state where the workpiece 8 is gripped by the chuck 24, the spindle is rotated by the spindle motor 46 at a predetermined rotational speed.
If the saddle 7 is moved in the Z-axis direction on the bed 22, the feed base 4 is moved in the X-axis direction on the saddle 7, and the tool post 3 is moved in the Yc-axis direction on the feed base 4, the tool rest 3 The workpiece 8 is turned with the tool 2.
As for the control for moving the tool 2 in the X-axis direction and the Yc-axis direction, the movement in both the X-axis direction and the Yc-axis direction, the movement in the X-axis direction, or the movement in the Yc-axis direction only. The desired axial direction is controlled as necessary.

When the feed base 4 moves in the X-axis direction, the roller 15 attached to the slide member 10 in the inclined sliding portion 6 is in contact with the support portion side lower surface 13 of the fastening plate 16 and is centered on the axis CL. As shown by arrow B.
Since the roller 15 receives the reaction force FH1 from the clamping plate 16, minute gaps d1 and d2 are formed on the upper and lower sliding surfaces of the slide member 10 to which the roller 15 is attached, and a lubricating oil film is formed in the gaps d1 and d2. It is formed well.
As a result, the accumulation feeding phenomenon does not occur in the inclined sliding portion 6, and the moving body 5 moves smoothly in the X-axis direction. Therefore, when the workpiece 8 is turned with the tool 2 of the moving body 5, the surface 9 on which the workpiece 8 has been turned has an inconvenient line (the line shown in FIG. 112), the surface becomes smooth and a high quality processed workpiece is obtained.

Since there is always a lubricant film in the gaps d1, d2 between the upper and lower sliding surfaces of the slide member 10, the amount of lubricant supplied to the sliding portion 6 can be reduced. Further, since the gaps d1 and d2 are very small, there is no possibility that coolant or dust enters the gaps d1 and d2.
Since the roller 15 that is in rolling contact is provided so that the slide member 10 is in sliding contact with the saddle 7, wear in the sliding portion 6 is concentrated on the roller 15 that is in rolling contact while receiving the reaction force FH1 from the fastening plate 16. To do. That is, the roller 15 takes over most of the wear phenomenon in the sliding portion 6.
As a result, wear of the sliding contact surface in the sliding portion 6 is reduced, and the life of the sliding contact surface is extended. In addition, when the wear of the roller 15 has progressed, if only the roller 15 is replaced with a new one, the sliding portion 6 can be easily restored to the original state, so that the maintenance of the sliding portion 6 is facilitated.
When adjusting the gaps d1 and d2 of the sliding part 6, it is only necessary to adjust the position of the roller 15 without adjusting the entire gap of the sliding part 6, so that the adjustment work of the gaps d1 and d2 is easy. It is.

FIG. 10A is a schematic configuration diagram of a machine tool 1 according to a modified example of the present embodiment. FIG. 10A is an equivalent view of FIG. 1A, and FIG. FIG. 1B and FIG. 10C are perspective views of the compression spring 60. In addition, the same code | symbol is attached | subjected to the same or equivalent part as the said Example, the description is abbreviate | omitted, and only a different part is demonstrated.
The machine tool 1 shown in FIG. 10 has a moving body 5 supported by a saddle 7 as a moving body support portion via a sliding portion 6 inclined (or perpendicular) to the horizontal plane L0. NC lathe. The moving body 5 can move in the X-axis direction relative to the saddle 7, and a tool (also a turning tool) is attached to the moving body 5.
The moving body 5 has a feed base 4 and a tool post 3 supported by the feed base 4 and relatively movable in the Yc axis direction. Since the center of gravity G of the moving body 5 deviates from the sliding portion 6 in plan view, a downward pressing force FL acts at the lower position PL of the sliding portion 6, and an upward lifting force FH is generated at the upper position PH. Works.
As a result, moment is applied to the moving body 5 by its own weight W as shown by the arrow M, and the moving body 5 is in a posture that bends forward, so that it is supported by the saddle 7 in an unbalanced state.
In the sliding portion 6, the sliding upper surface 11 and the sliding lower surface 12 of the sliding member 10 provided on the moving body 5 are in sliding contact with the supporting portion side lower surface 13 and the supporting portion side upper surface 14 formed on the saddle 7, respectively.
A pressing member 61 is movably attached to the slide member 10 via a compression spring 60 at an upper position PH of the sliding contact portion 6. An upward lifting force FH acts on the pressing member 61, and the pressing member 61 is in sliding contact with the lower surface 13 on the support portion side of the saddle 7.

A taper surface 62 is formed on the slide member 10. The pressing member 61 is attached to the slide member 10 by a bolt 63 or the like so that the position can be adjusted. The pressing member 61 includes a sliding contact surface 64 that is in sliding contact with the support portion-side lower surface 13, and an inclined surface 65 that is inclined with respect to the sliding contact surface 64, substantially parallel to the tapered surface 62, and opposed to the tapered surface 62. Yes.
The compression spring 60 is arrange | positioned between the taper surface 62 and the inclined surface 65, and the compression spring 60 has comprised the corrugated plate shape, for example. Since the surface of the sliding contact surface 64 is a smooth surface sprayed with a ceramic impregnated with fluorine, the pressing member 61 can smoothly slide with respect to the lower surface 13 on the support portion side.
At the upper position PH of the sliding portion 6, an upward lifting force FH acts on the moving body 5. The lifting force FH is transmitted to the pressing member 61 via the compression spring 60, and the pressing member 61 presses the feed base 4 with the lifting force FH. As a result, a moment as indicated by an arrow M is applied to the moving body 5, and the moving body 5 enters an unbalanced state so as to move away from the saddle 7.
As a result, a reaction force FH1 is applied to the pressing member 61 from the fastening plate 16, and the reaction force FH1 presses the slide member 10 toward the support portion side upper surface 14 of the saddle 7 via the compression spring 60. As a result, the upward lifting force FH and the reaction force FH1 from the moving body 5 are balanced, and minute gaps d1 and d2 are formed above and below the slide member 10, respectively. Since the lubricating oil film is formed in the gaps d1 and d2, the sliding resistance at the sliding portion 6 is reduced, and the occurrence of the accumulation feed phenomenon is prevented.

Since the slide member 10 is urged in a direction away from the support portion side lower surface 13 by the spring force of the compression spring 60, the slide member 10 has a minute gap between the support portion side lower surface 13 and the support portion side upper surface 14 of the saddle 7. The sliding contact is made with d1 and d2. Thereby, the movable body 5 movable via the sliding portion 6 inclined with respect to the horizontal plane moves in the X-axis direction without causing a reservoir feeding phenomenon.
When the workpiece 8 is machined with the tool 2 attached to the movable body 5 (here, turning), the processed surface (here, the surface that has been turned) 9 of the workpiece 8 becomes a conventional reservoir feed phenomenon. Thus, the surface becomes smooth without any inconvenient streaks (streaks 112 shown in FIG. 11C), and the quality of the processed workpiece is improved. Also in this modified example, the same operational effects as the above-described operational effects in the above-described embodiment are achieved.

Although the embodiments (including modifications) of the present invention have been described above, the present invention is not limited to the above-described embodiments, and various modifications and additions are possible within the scope of the gist of the present invention. .
In the drawings, the same reference numerals denote the same or corresponding parts.

  The machine tool of the present invention can be applied to a vertical machining center having a vertical sliding portion in addition to a lathe having a sliding portion inclined, a multi-task machine, and a turning center.

1 to 10 show an embodiment of the present invention. FIG. 1A is a schematic configuration diagram of a machine tool according to the present embodiment, FIG. 1B is an enlarged sectional view of a portion B of FIG. 1A, and FIG. 1C is an explanatory diagram showing a processed workpiece. It is. It is a perspective view of the machine tool. It is a perspective view which shows a part of said machine tool. It is a left view of the machine tool. It is a perspective view which shows a part of said machine tool. It is a perspective view of the feed stand of the machine tool. It is a partial expansion perspective view of the said feed stand. It is the XIII-XIII sectional view taken on the line in FIG. It is the IX-IX sectional view taken on the line in FIG. FIG. 10A is a schematic configuration diagram of a machine tool according to a modification of the present embodiment, and is a view corresponding to FIG. 1A, and FIG. 10B is an enlarged cross-sectional view of a portion B of FIG. FIG. 1C is a perspective view of the compression spring. 11A is a schematic configuration diagram of a conventional machine tool and is a diagram corresponding to FIG. 1A, and FIG. 11B is an enlarged sectional view of a portion B of FIG. 11A and is a diagram corresponding to FIG. FIG. 11 (C) is an explanatory view showing the machined workpiece and is equivalent to FIG. 1 (C).

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Machine tool 2 Tool 4 Feed stand (turret support)
5 Moving body 6 Sliding part 7 Saddle (moving body support part)
DESCRIPTION OF SYMBOLS 10 Slide member 11 Sliding upper surface 12 Sliding lower surface 13 Support part side lower surface 14 Support part side upper surface 15 Roller 16 Clamping plate 22 Bed 50 Roller support member 60 Compression spring d1, d2 Minute clearance FL Downward pressing force FH Uplift force FH1 reaction force G center of gravity L0 horizontal plane PL lower position PH upper position

Claims (5)

A movable body that is supported by the movable body support portion through a sliding portion that is inclined with respect to the horizontal plane or that is perpendicular to the horizontal plane, is relatively movable, and has a tool attached thereto;
Since the center of gravity of the moving body is disengaged from the sliding portion in plan view, a downward pressing force acts on the lower position of the sliding portion and an upward lifting force acts on the upper position, so that the movement The body is a machine tool supported in an unbalanced state on the movable body support part,
In the sliding portion, the sliding upper surface and the sliding lower surface of the sliding member provided in the moving body are in sliding contact with the supporting portion side lower surface and the supporting portion side upper surface formed in the moving body support portion, respectively.
In the upper position of the sliding portion, a roller that is rotatably supported by the moving body and acts on the lifting force is brought into rolling contact with the lower surface of the moving body supporting portion on the supporting portion side, and the sliding member Is pressed in a direction away from the lower surface on the support portion side by a reaction force applied to the roller,
A machine tool, wherein the sliding member is in sliding contact with the support unit side lower surface and the support unit side upper surface of the movable body support unit with a minute gap. The roller is rotatably supported by a roller support member that is detachably attached to the movable body,
The machine tool according to claim 1, wherein the roller support member is capable of adjusting a position of the roller with respect to the slide member. The moving body support portion is a saddle that can move on a bed,
The movable body has a feed base supported by the saddle through the sliding portion so as to be movable, and a tool post supported by the feed base so as to be movable.
The sliding lower surface of the sliding member of the feed base is in sliding contact with the upper surface of the support portion formed on the saddle,
The sliding upper surface of the sliding member is in sliding contact with the lower surface of the supporting portion side of the fastening plate attached to the saddle,
3. The machine tool according to claim 1, wherein the slide member is regulated by the saddle so as not to move in the left-right direction relative to the saddle. 4. A movable body that is supported by the movable body support portion through a sliding portion that is inclined with respect to the horizontal plane or that is perpendicular to the horizontal plane, is relatively movable, and has a tool attached thereto;
Since the center of gravity of the moving body is out of the sliding portion in plan view, a downward pressing force acts at the lower position of the sliding portion, and an upward lifting force acts at the upper position, The moving body is a machine tool supported in an unbalanced state on the moving body support portion,
In the sliding portion, the sliding upper surface and the sliding lower surface of the sliding member provided in the moving body are in sliding contact with the supporting portion side lower surface and the supporting portion side upper surface formed in the moving body support portion, respectively.
At the upper position of the sliding portion, a pressing member which is attached to the sliding member via a compression spring and is acted on by the lifting force is brought into sliding contact with the lower surface of the moving body supporting portion on the supporting portion side. The slide member is biased in a direction away from the lower surface of the support portion by the spring force of the compression spring,
A machine tool, wherein the sliding member is in sliding contact with the support unit side lower surface and the support unit side upper surface of the movable body support unit with a minute gap.   5. The machine tool according to claim 1, wherein the machine tool is a lathe having the inclined sliding portion, a multi-tasking machine or a turning center, or a vertical machining center having the vertical sliding portion. The machine tool according to the item.

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