JP6415591B2 - Autoloader - Google Patents

Description

  The present invention relates to an autoloader for delivering a workpiece to a processing machine mounted on a base.

  A processing machine such as a machine tool may be provided with an autoloader for delivering and transferring a workpiece to and from the processing unit in order to send the workpiece to the processing unit. The autoloader is provided with a robot that actually delivers a workpiece and a traveling device that moves the robot to a predetermined position. When there are a plurality of processing parts, the work is transported to each processing part by the autoloader, and the work loader carries in and out the work by the autoloader. On the other hand, Patent Document 1 below discloses a machine tool in which a headstock itself moves to a work stocker without providing an autoloader. In this machine tool, the extension rail is fixed to the machine main body, and the head stock moves to the position of the extension rail so that the workpiece can be grasped from the workpiece stocker. And the workpiece | work hold | gripped by the headstock is carried in to a process part, and after a process is performed, it returns to a workpiece | work stocker again.

Japanese Patent Laid-Open No. 10-138002

In processing machines, an autoloader is mounted for transporting workpieces, and the headstock itself is moved. However, the movement range is limited to the range in which the robot and the headstock deliver the workpiece to the machining unit. For this reason, in a processing machine in which an autoloader is arranged at the front part, the positions of the robot and the processing part overlap each other, which hinders maintenance work and the like. That is, when the worker performs work in front of the processing machine, the robot located in the front part of the worker gets in the way. On the other hand, the same problem does not occur in the processing machine of Patent Document 1 that does not have an autoloader. However, in the configuration in which the headstock travels for each processing unit, the traveling platform and the drive mechanism must be made robust. In addition, another problem such as enlargement occurs.

  SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide an autoloader that does not hinder the work in the front portion in order to solve such a problem.

An autoloader according to an aspect of the present invention delivers a workpiece from a front portion of the base to a processing machine mounted on the base, and includes a robot for handling the workpiece and the robot. A traveling table that moves, and a rail member that guides the movement of the traveling table, wherein the rail member is fixed to a front portion of the base and is positioned at a workpiece delivery position that overlaps the processing machine when viewed from the front-rear direction. A standard rail member for guiding the robot, and a width of the width corresponding to the robot, and the standard rail member to guide the robot to a position that does not overlap the processing machine when viewed from the front-rear direction. And an extension rail member supported by a leg portion that can be adjusted in height.

  According to the present invention, by connecting the extension rail member to the standard rail member fixed to the base, the robot moves to a position deviating from the workpiece delivery position with the processing machine, so that a work space is provided in front of the processing machine. The autoloader does not interfere with the work on the processing machine.

It is the perspective view which showed the machine tool carrying the autoloader of one Embodiment. It is the perspective view which showed the machine tool carrying the autoloader of one Embodiment. It is the perspective view which showed one Embodiment of the autoloader. It is the perspective view which showed two bases with which the rail member was mounted | worn. It is the front view which showed the standard rail member and the extension rail member. It is the front view which showed one Embodiment of the autoloader. It is the perspective view which showed the machine tool which applied the extension rail member to the carrying-out of a workpiece | work.

  Next, an autoloader according to an embodiment of the present invention will be described below with reference to the drawings. 1 and 2 are perspective views showing a machine tool equipped with the autoloader of the present embodiment. In particular, FIG. 1 shows the machining state and FIG. 2 shows the non-machining state. The machine tool 5 is entirely covered with an exterior cover 3, and a machining portion is provided inside the machine tool 5. A front cover 4 is provided on the front surface of the exterior cover 3, and an autoloader 10 is disposed therein. The front cover 4 can be opened upward, and can be opened when performing maintenance work on a processing portion in the exterior cover 3. And the operation panel 6 is attached to the upper part of the front cover 4 according to the height of an operator's eyes.

  The machine tool 5 is mounted on a movable bed 501 so that it can move on the base 2. As shown in FIG. 4, the base 2 is provided with four rails 201 in the front-rear direction. In other words, two units can be mounted on one base 2 if the machine tool is narrow. The machine tool 5 includes a movable bed 501 on which wheels can be mounted in accordance with the width of two rails 201 positioned on the outside. Therefore, the machine tool 5 is capable of moving in the front-rear direction, and can be moved between a machining position where the workpiece machining shown in FIG. 1 can be performed and a non-machining position where maintenance or the like moved forward can be performed.

  By the way, the machine tool 5 of this embodiment is a turret lathe including a turret holding a rotary tool such as an end mill or a drill or a cutting tool such as a cutting tool. Therefore, the headstock with a chuck for gripping a workpiece, a turret device to which a tool is attached, a Z-axis drive device, an X-axis drive device, and a drive unit that move the turret device along the Z-axis and X-axis are controlled. A processing control device and the like are provided. However, the machine tool is not particularly limited to a lathe, and may be a drilling machine, a boring machine, a milling machine, a gear cutting machine, a cutting machine, or the like.

  Next, FIG. 3 is a perspective view showing the autoloader 10. In particular, a state in which the robot arm 11 extends to the side of the machine tool 5 (not shown) mounted on the base 2 is shown. FIG. 2 shows the autoloader 10 in a state where the robot arm 11 is folded and can travel and turn. The robot arm 11 is mounted on the gantry block 12, and the upper arm member 111 and the forearm member 112 form a multi-joint structure via joint mechanisms 115 and 116. The robot arm 11 can be deformed into a state in which the upper arm member 111 and the forearm member 112 are folded and in a forward inclined state by driving the joint mechanisms 115 and 116. A robot hand 13 is provided at the distal end of the forearm member 112 so that the workpiece can be grasped and released.

  A gantry block 12 that supports the robot arm 11 is mounted on a traveling table 16 via a turning table 15. Therefore, the direction of the robot arm 11 can be changed by driving the turntable 15, and the position can be changed by moving the traveling platform 16. The traveling platform 16 is attached to a rail member 18 fixed to the base 2 so as to travel. Here, FIG. 4 is a perspective view showing the base 2, and particularly shows two bases 2 to which the rail members 18 are attached.

  The base 2 is integrally formed with a rail member 18 attached to the front portion thereof. The rail member 18 has a plate-like rail base 21 fixed to the front portion of the base 2, and a rack 22 and two traveling rails 23 are fixed to the rail base 21 side by side. Two traveling sliders 25 that slide while holding the traveling rail 23 are attached to the traveling rail 23, and a traveling platform 16 (see FIG. 3) is fixed to the traveling slider 25. The traveling table 16 is provided with a pinion 26 that meshes with the rack 22 and a traveling motor 27 that rotates the pinion 26. Therefore, when the driving motor 27 is driven, the pinion 26 rolls on the rack 22 and the traveling slider 25 slides on the traveling rail 23, so that the traveling platform 16 and the robot arm 11 move the front portion of the base 2 in the left-right width direction. Will be moved to.

  Incidentally, as described above, the machine tool 5 can move in the front-rear direction on the base 2 (see FIG. 2). Therefore, the machine tool 5 moves with respect to the operator located in the front, and operations such as maintenance can be performed at that position. However, in the case of the present embodiment, the autoloader 10 is positioned in front of the machine tool 5, and in particular, the robot arm 11 is disposed upright. For this reason, when the machine tool 5 is moved in front of the base 2, the robot arm 11 becomes an obstacle to the movement. Therefore, in this embodiment, a configuration for retracting the robot arm so as not to hinder the movement of the machine tool 5 is employed.

  By the way, as shown in FIG. 4, the base 2 is normally handled integrally with a rail member 18 attached to the front portion. Although only one base 2 is shown in FIGS. 1 and 2, the machine tool 5 of the present embodiment has a plurality of machine tools 5 arranged side by side by arranging the bases 2 close to each other in the width direction. It is possible to arrange. In that case, since the bases 2 are arranged at positions very close to each other, the rail members 18 mounted on the bases 2 are directly connected to each other. Therefore, the rail member 18 is formed with a length substantially corresponding to the width dimension of the base 2. The two rail members 18 shown in FIG. 4 are substantially the same as the base 2 as described above, although there is a slight difference in configuration between the reference (the left side in the drawing) and the connecting member (the right side in the drawing). It is formed with a length corresponding to the width dimension. Therefore, the rail member 18 that is handled integrally with the base 2 is hereinafter referred to as a “standard rail member 18”.

  When the plurality of bases 2 are arranged in the width direction, a so-called machining line in which a plurality of machine tools 5 are arranged side by side is formed thereon. In this machining line, the standard rail members 18 are connected to each other so that the rack 22 and the traveling rail 23 are continuous, so that the robot arm 11 can move back and forth between the workpiece delivery positions of the machine tools 5. Further, in the machining line, since the machine tool 5 can move in the front-rear direction with respect to the base 2, even if the machine tools 5 are close to each other, there is no problem in maintenance work or the like. At that time, the robot arm 11 can move to a position of the base 2 different from the machine tool 5 moving forward.

  However, in this embodiment, as shown in FIGS. 1 and 2, the machine tool 5 is mounted on one base 2. In such a configuration, since the standard rail member 18 has only the width of the base 2, the movement of the machine tool 5 on the base 2 is limited. Therefore, an autoloader 10 capable of extending the movement range of the robot arm 11 is configured so as not to hinder the function of the machine tool 5 movable in the front-rear direction. That is, as shown in FIGS. 1 and 2, the robot arm 11 can move beyond the width of the base 2 by connecting the extension rail member 19 to the standard rail member 18.

FIG. 5 is a front view showing the standard rail member 18 and the extended rail member 19. FIG. 6 is a front view showing the autoloader 10 to which the extension rail member 19 is added. As described above, the standard rail member 18 has the rack 22 and the two traveling rails 23 extending in the longitudinal direction fixed to the front surface of the rail base 21 which is a plate material in parallel in the vertical direction. The rack 22 and the traveling rail 23 are formed shorter than the length of the rail base 21 in the longitudinal direction. That is, attachment portions 211 and 212 where the rack 22 and the traveling rail 23 do not exist are formed at the left and right ends of the rail base 21.

  On the other hand, the extended rail member 19 has a rack 32 and two traveling rails 33 extending in the longitudinal direction and fixed in parallel in the vertical direction on the front surface of a rail base 31 that is also a plate material. The rack 32 and the running rail 33 are formed with protruding portions 321 and 331 protruding from one end of the rail base 31 on the standard rail member 18 side. The extension rail member 19 is provided with a leg portion 35 that supports the rail base 31 so that the height can be adjusted with respect to the standard rail member 18.

  In the extended rail member 19, the end of the rail base 31 is abutted against the end of the rail base 21 of the standard rail member 18, and the protrusions 321 and 331 are overlapped with the mounting portion 212 and screwed. A connecting plate 36 is fixed to the extension rail member 19. The connecting plate 36 is overlapped with the mounting portion 211 of the standard rail member 19 and fastened with fixing bolts, whereby the rail bases 21 and 31 are more firmly connected. The standard rail member 18 and the extended rail member 19 have their racks 22 and 32 and running rails 23 and 33 continuous, and each has one rack or running rail.

  As described above, the extension rail member 19 is for securing a retreat place that does not prevent the machine tool 5 from moving forward. Therefore, as shown in FIG. 6, it is only necessary that the robot arm 11 is laterally removed so as not to overlap the position of the machine tool 5 when viewed from the front-rear direction. Therefore, the dimension of the extension rail member 19 (the dimension of the rail base 31) may be a length corresponding to the width dimension of the robot arm 11. In the present embodiment, the length is approximately half that of the standard rail member 18.

  By the way, the standard rail member 18 is provided with a mounting portion 211 that enables the extension rail member 19 to be connected on the left side of the drawing. If it is only for retracting the robot arm 11, only one of the extension rail members 19 is sufficient as shown in FIG. There is no need to connect the extension rail member 19 to the left side of the drawing. However, the point that the robot arm 11 can be moved to the position where the robot arm 11 is detached from the machine tool 5 by the extension rail member 19 has an advantageous effect for loading and unloading workpieces. Therefore, if it is considered to be used for loading and unloading workpieces, the extension rail members 19 are required on the left and right. Here, FIG. 7 is a perspective view showing a machine tool in which the extension rail member is applied to carry out the workpiece.

  When the extension rail member 19 is connected, the robot arm 11 can come out of the front cover 4. Therefore, as shown in the figure, by disposing the work stocker 40 beside the machine tool 5, the processed work can be disposed thereon. The extension rail member 19 is provided with a bracket 38 on the rail base 31, and the work stocker 40 is fixed to the bracket 38 and positioned.

  In FIG. 7, the extension rail member 19 and the work stocker 40 are arranged only on the right side of the machine tool 5. Similarly, the extension rail member 19 and the work stocker 40 can be arranged on the left side of the machine tool. is there. In this case, if the work flows from the left side to the right side of the drawing, the autoloader 10 causes the robot arm 11 to move to the machine tool 5 by grasping the work placed on the left work stocker 40, and to the machining unit. After the delivery, the workpiece received from the processing unit is grasped and moved to the right workpiece stocker 40 and arranged there. During this time, although the posture of the robot arm 11 is changed due to an expansion / contraction operation or the like, the direction of the robot arm 11 is not changed by turning.

  Therefore, according to the present embodiment, the robot arm 11 can be retracted by connecting the extension rail member 19 to the standard rail member 18. That is, as shown in FIG. 2, when the robot arm 11 moves to the extension rail member 19 located outside the front cover 4, it does not hinder the machine tool 5 from moving forward on the base 2. In addition, by arranging the work stocker 40 next to the base 2, the robot arm 11 can carry in and carry out the work as it is without changing the direction at the time of traveling from the front cover 4. Can do.

  Since the extension rail member 19 is configured to be easily attached to and detached from the standard rail member 18, it can be easily attached when necessary. That is, normally, the autoloader 10 is configured by the standard rail member 18 that is handled integrally with the base 2, but the extension rail member 19 can be easily attached if necessary, and a retreat place for the robot arm 11 is secured. The autoloader 10 can be made. Since the extension rail member 19 has a length corresponding to the width dimension of the robot arm 11, it does not take more space than necessary, and if the work stocker 40 is disposed, no space is wasted. And even if it is removed, it is not too big to store.

As mentioned above, although one Embodiment of this invention was described, this invention is not limited to these, A various change is possible in the range which does not deviate from the meaning.
For example, in the above-described embodiment, the robot arm 11 is retracted to the extension rail member 19 side while paying attention to the point that the machine tool 5 moves forward. However, the present invention is for moving the machine tool 5. It is not just composed. That is, as described in the problem column, when the worker performs an operation on the front part of the machine tool 5, the problem is that the robot arm 11 is arranged in front of the processing unit.

Therefore, even when the machine tool 5 is in the normal position of the base 2 as shown in FIG. 1, the robot arm 11 needs to be moved to the retracted position when the front cover 4 is opened and the work is performed. There is. Therefore, the object on which the autoloader according to the present invention is mounted is not limited to the machine tool 5 movable in the front-rear direction, and may be another processing machine.
Further, the configuration of the autoloader is not limited to the robot arm 11 shown in the embodiment.

DESCRIPTION OF SYMBOLS 2 ... Base 3 ... Exterior cover 4 ... Front cover 5 ... Machine tool 10 ... Autoloader 11 ... Robot arm 16 ... Running stand 18 ... Standard rail member 19 ... Extension rail member

Claims (3)

An autoloader that delivers workpieces from the front of the base to a processing machine mounted on the base ,
A robot for handling a workpiece; a traveling platform on which the robot is mounted; and a rail member that guides the movement of the traveling platform;
The rail member is
A standard rail member that is fixed to the front portion of the base and guides the robot to a workpiece delivery position that overlaps the processing machine when viewed from the front-rear direction ;
A leg whose width dimension is a length corresponding to the robot and is connected to the standard rail member so as to guide the robot to a position where it does not overlap the processing machine when viewed from the front-rear direction and is adjustable in height. An autoloader comprising an extension rail member supported by the section.   The autoloader according to claim 1, wherein the extension rail member constitutes a retracted position of the robot. The autoloader according to claim 2, wherein the extension rail member includes a bracket for fixing and positioning the work stocker.

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