JP2011183459A - Industrial robot - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To reduce a failure occurrence probability of a falling prevention mechanism, and to easily notice failure even if the failure is caused. <P>SOLUTION: A first slider 8 can move in the vertical direction to a fixed base 7, and a second slider 10 can move in the vertical direction to this first slider 8. The second slider 10 is moved ahead of this to the first slider 8 by a moving mechanism 11 for the second slider having pulleys 22A and 22B and a belt 23 when the first slider 8 is moved. The falling prevention mechanism 24 has a lever 25 rotatably supported by a support shaft 26 in an intermediate part between both pulleys 22A and 22B in the first slider 8 and having a first long hole part 27A and a second long hole part 27B, a first pin 29A arranged on the fixed base 7 and a second pin 29B arranged in the second slider 10, and the first pin 29A and the second pin 29B are arranged in point symmetry with the support shaft 26 as the center. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to an industrial robot having a multi-stage slider and a vertical multi-stage expansion / contraction device that expands and contracts the sliders.

  Some industrial robots are equipped with a multistage expansion / contraction device with a small installation space for a target stroke length. In this industrial robot, a first slider that is moved by a first slider moving mechanism is provided on a fixed base, and a second slider is provided on the first slider so as to be movable in the same direction, and further includes a pulley and a belt. A second slider moving mechanism for moving the second slider as the first slider moves, and when the first slider is moved by the first slider moving mechanism, the second slider moving mechanism is provided. The moving mechanism further moves the second slider in the same direction with respect to the first slider (Patent Document 1, Patent Document 2).

  When the above-described multistage expansion / contraction apparatus is used for vertical conveyance, the schematic configuration of the multistage expansion / contraction apparatus is as shown in FIG. FIG. 12A shows a state in which a second slider 104 described later is at the uppermost position in the set movement stroke St, and FIG. 12B shows a state in the lowermost position in the movement stroke St. Yes. The multistage telescopic device 101 includes a fixed base 102, a first slider 103 that can move in the vertical direction to the fixed base 102, a second slider 104 that can move in the vertical direction on the first slider 103, And a second slider moving mechanism 105. A first slider moving mechanism for moving the first slider 103 is not shown.

  The second slider moving mechanism 105 includes pulleys 105a and 105b provided at both ends in the vertical direction of the first slider 103 and a belt 105c provided between the pulleys 105a and 105b. A part 105h of one of the two opposite sides is connected to the fixed base 102, and a part 105i on the other side opposite to the part 105h is connected to the second slider 104. Become.

  When the first slider 103 is moved downward (in the direction of arrow A) from the state shown in FIG. 12A by a first slider moving mechanism (not shown), a portion 105 h is fixed to the belt 105 c fixed to the fixed base 102. Since the pulleys 105a and 105b move in the direction of arrow A, the one side 105ca side of the belt 105c further moves in the direction of arrow A ′ (the same direction as arrow A) with respect to the first slider 103, and the second The slider 104 moves with a stroke St longer than the stroke of the first slider 103.

  By the way, in the configuration in which the second slider 104 is moved by the second slider moving mechanism 105 provided with the belt 105c as described above, the belt 105c may be subject to fatigue cutting over time. The belt 105c is no longer supported on the slider 104, and the second slider 105 falls.

As a countermeasure for preventing this, there is a fall prevention mechanism described in Patent Document 3.
This fall prevention mechanism transmits the rotational force of the motor to the ball screw via a belt transmission mechanism (consisting of a motor-side pulley, a ball screw-side pulley and a belt) and rotates the ball screw, and has a screw receiver for this ball screw. In the lifting and lowering device for moving the slider up and down, one end of a lever pivotally supported in the middle is brought into contact with the belt of the belt transmission mechanism, and the other end of the lever is engaged with the ball screw side pulley. A latching portion that can be stopped is formed, and a spring that biases the lever in a direction in which one end portion of the lever always contacts the belt is provided.

  In this fall prevention mechanism, in a normal state where the belt is not cut, the locking portion of the lever is not locked with the ball screw side pulley, and when the belt is cut for some reason, The spring is actively actuated to lock the lever on the ball screw side pulley and lock the free rotation of the ball screw side pulley. This prevents free rotation of the ball screw and prevents the slider from dropping.

JP-A-9-285899 Japanese Patent Laid-Open No. 11-245189 Japanese Utility Model Publication No. 5-71510

  It is conceivable to divert the technique of the above-described fall prevention mechanism to a vertical multistage expansion / contraction device provided with a slider moving mechanism having the pulley and belt. Specifically, it can be considered that when the belt is cut, the lever is locked to the second slider by the active operation of the spring to prevent the second slider from dropping. However, in the case of this configuration, even if the spring is broken, it can operate without any trouble as a vertical multi-stage telescopic device. For this reason, the multistage telescopic device may be operated without noticing the failure of the fall prevention mechanism (for example, the failure of the spring or the lever being fixed). There is a possibility that a situation may occur in which the spring is not actively operated and the second slider cannot be prevented from falling. Furthermore, by having an active member such as a spring, the probability of failure of the fall prevention mechanism itself is high.

  Especially in robots, when the vertical multistage expansion / contraction device is stopped and the operator performs robot maintenance, hand attachment, etc., the second slider may drop unexpectedly if he / she does not notice the failure of the fall prevention mechanism. Such a situation must be avoided.

  The present invention has been made in view of the above-described circumstances, and the purpose thereof is to reduce the probability of failure of the fall prevention mechanism and to ensure that even if a failure occurs, the failure can be easily noticed. It is to provide an industrial robot with high cost.

  The industrial robot according to claim 1 is provided with a fixed base, a first slider which is provided on the fixed base so as to be movable in the vertical direction and is moved by a first slider moving mechanism, and is movable in the vertical direction with respect to the first slider. A second slider provided on each of the first sliders, pulleys provided at both ends in the vertical direction of the first slider, and a belt provided between the pulleys, and a part of the belt is connected to the fixed base. A second slider moving mechanism in which a portion that forms a counter electrode with the part is connected to the second slider, and the second slider is moved in the same direction as the first slider as the first slider moves. And an anti-fall mechanism for preventing the second slider from falling, wherein the anti-fall mechanism comprises the first slider. A lever having a longitudinally intermediate portion rotatably supported by a support shaft at a middle portion between the two pulleys of the slider, and a first linearly extending from the vicinity of the support shaft to one end direction on the lever. A first groove portion, a second groove portion formed on the lever so as to extend linearly from the vicinity of the support shaft toward the other end, and a first groove portion provided on the fixed base and movably inserted into the first groove portion; A pin and a second pin that is provided on the second slider and is movably inserted into the second groove. The first pin and the second pin are arranged symmetrically with respect to the support shaft. Has characteristics.

  According to the first aspect of the present invention, when the first slider moves in the vertical direction in a normal state where the belt is not cut, the slider moving mechanism together with the first slider with respect to the belt partially fixed to the fixed base. Since both the pulleys also move, the side part on the second slider side of the belt further moves in the same direction with respect to the moving first slide. As a result, the second slider receives a moving force from the belt and moves relatively ahead of the first slider. And the 2nd pin which moves with this 2nd slider pushes one 1st groove part inner surface of a lever, and, thereby, a lever rotates. In this case, since the second pin is always point-symmetrically arranged with respect to the first pin about the support shaft, the second pin is relatively opposite to the first pin about the support shaft of the intermediate portion of the lever. The lever moves in the second groove of the lever in synchronism with the direction, so that the lever rotates without hindrance. As described above, the fall prevention mechanism only passively operates in accordance with the operation of the vertical multistage vertical apparatus, and the configuration itself is a simple configuration in which the lever is supported by the support shaft. There is almost no failure such as sticking at the shaft.

When the vertical multistage vertical apparatus is operating normally as described above, the lever of the fall prevention mechanism also follows and rotates without any problem.
If it is assumed that a failure has occurred due to the lever sticking or the like, when the vertical multistage telescopic device is operated, the movement of the first slider is locked by the fixed lever and the vertical multistage telescopic device is operated. Thus, it can be recognized that a failure has occurred in the fall prevention mechanism, so that the operator immediately notices the failure of the fall prevention mechanism.

  In addition, if the operator unexpectedly breaks the belt when carrying out robot maintenance or hand attachment while stopping the vertical multistage telescopic device while the fall prevention mechanism is functioning normally, the second slider will The support force by the belt is lost and it tries to fall vertically, but since the vertical multistage telescopic device is stopped and the lever is also stopped, the second pin of the second slider that is going to fall vertically The movement is blocked by the second groove portion of the lever that is inclined or horizontal, and thus the second slider is prevented from falling.

  In addition, when the belt breaks with the vertical multistage telescopic device moving the first slider downward (the other end of the lever is pivoting downward), the belt moves against the second slider. Although the support is lost, since the pivoting posture of the lever is restricted by the support shaft and the first pin, the second slider is received by the lever and the second slider is prevented from falling. After this, the other end of the lever rotates downward, but the lever in a form intersecting the second slider that can only move vertically always receives this second slider, so it does not fall. .

  After this, when the first slider of the vertical multistage vertical device is switched upward after reaching the lowest position, the other end of the lever tries to rotate upward, but the second slider moves downward. The rotation is prevented by the second pin receiving the load, and eventually the first slider moving mechanism does not function, that is, the vertical multistage vertical device stops. By this stop operation, the occurrence of cutting of the belt is immediately recognized by the operator.

  If the belt is broken while the vertical multistage telescopic device is moving the first slider and the second slider upward, the belt is not supported by the second slider, and the second slider is moved by its own weight. Although it tries to move (drop) downward, since the other end of the lever rotates upward, the second slider is supported by the lever, and the second slider can be prevented from falling. At the same time, for a vertical multistage vertical device, the lever can be pushed up against the load when a downward load on the second slide is applied (this includes the weight of the hand, workpiece, etc.). Accordingly, the first slider moving mechanism immediately stops functioning, that is, the vertical multistage vertical device is immediately stopped. As a result, the worker immediately notices that the belt is cut.

The perspective view of the vertical multistage expansion-contraction apparatus which showed 1st Embodiment of this invention and abbreviate | omitted the moving mechanism for 1st sliders Perspective view of the entire industrial robot Perspective view of vertical multistage telescopic device 1 is a perspective view of a vertical multistage telescopic device in which a lever for the first slider moving mechanism and a fall prevention mechanism is omitted. Sectional drawing which follows the cutting line SS of FIG.8 (b) Sectional drawing which follows the cutting line TT of FIG.8 (b) Sectional drawing which follows the cutting line UU of FIG.8 (b) (A)-(d) is a side view of schematic structure from which the operation state of a vertical multistage expansion-contraction apparatus differs, respectively. (A)-(d) is a side view of schematic structure of the vertical multistage expansion-contraction apparatus for showing the mode of belt cutting | disconnection The perspective view of the lever which shows 2nd Embodiment of this invention FIG. 6 equivalent view showing a third embodiment of the present invention. It shows a reference example, (a) is a side view of a schematic configuration of a vertical multistage telescopic device in a state where the second slider is in the uppermost position, (b) is a state in which the second slider is in the lowermost position. Side view of schematic configuration of vertical multistage telescopic device

  A first embodiment of the present invention will be described below with reference to FIGS. In FIG. 2, an industrial robot 1 (hereinafter simply referred to as a robot 1) includes a horizontal moving mechanism 2 and a vertical multistage expansion / contraction device 3 that can move horizontally. The horizontal moving mechanism 2 has a moving member 5 on a horizontal rail 4 and a ball screw 6 for moving the moving member 5. The ball screw 6 is driven to rotate in one direction and in the opposite direction by a drive motor (not shown). A fixed base 7 of the vertical multistage telescopic device 3 is attached to the moving member 5.

The vertical multistage expansion / contraction device 3 will be described. The vertical multistage telescopic device 3 includes a fixed base 7, a first slider 8, a first slider moving mechanism 9, a second slider 10, a second slider moving mechanism 11, and a fall prevention mechanism 24. Configured.
As shown in FIGS. 4 and 5, the fixed base 7 includes a base body 12 and a pair of rail sliding bodies 13 </ b> L and 13 </ b> R attached to one surface thereof. The fixed base 7 has the other surface of the base body 12 attached to the base attachment plate 5 a of the moving member 5.

  The pair of rail slide bodies 13L and 13R are arranged in a direction (arrow Y direction in FIGS. 4 and 5) perpendicular to the moving direction of the first slider 8 and the second slider 10 (arrow A direction in FIGS. 3 and 4). It is located in both ends and attached in parallel along the direction of arrow A. The pair of rail slide bodies 13L and 13R have the same configuration.

  As shown in FIG. 5, one rail sliding body 13L is formed with a recess 13La opening in one surface so as to extend in the direction of arrow A, and on both inner side surfaces of the recess 13La, the arrow A direction is provided. Ball-shaped first guide portions 13Lb and 13Lb extending in a straight line are formed. Similarly, a recess 13Ra and first guide portions 13Rb and 13Rb are formed in the other rail sliding body 13R.

  Further, as shown in FIG. 4, the first slider 8 has a pair of parallel rails 14L and 14R, and screwed onto each end surface in a state of being addressed to each end surface of the pair of rails 14L and 14R. A frame having a first connecting end plate 15A stopped and a second connecting end plate 15B screwed to each other end face in a state of being addressed to each other end face of the pair of rails 14L and 14R. Configured.

  As shown in FIGS. 5 and 6, arc-shaped groove-shaped guide portions 14La and 14La are formed so as to extend in the longitudinal direction near one side portion on both side surfaces of the one rail 14L. Arc groove-shaped guide portions 14Lb and 14Lb are formed so as to extend in the longitudinal direction near the other side portion.

The other rail 14R is also formed in the same manner as the one rail 14L, and therefore has arcuate groove-shaped guide portions 14Ra, 14Ra, 14Rb, 14Rb.
The guide portion 14La is slidably engaged with the first guide portion 13Lb of the one rail slide body 13L, and the guide portion 14Ra is engaged with the first guide portion 13Rb of the other rail slide body 13R. It is slidably engaged. As a result, the first slider 8 moves to the rail sliding bodies 13L and 13R of the fixed base 7 in the direction of arrow A (see FIGS. 4 and 8A) and in the direction of arrow B opposite to this (see FIGS. 2 and 8D). It is provided to be movable to (see).

  As shown in FIGS. 2 and 3, the first slider moving mechanism 9 includes a driving motor 16 provided on the fixed base 7 and a ball rotated by the driving motor 16 via a belt transmission mechanism 17. A nut case 19 having a screw nut (not shown) inside, and a ball screw 18 meshing with the ball screw nut are provided. One end of the ball screw 18 is connected to the first connecting end plate 15A so that the first connecting end plate 15A can be pushed and pulled. From the uppermost position shown in FIG. 3 and FIG. When the motor 16 is driven to rotate in one direction, the first connecting end plate 15A and then the first slider 8 and the second slider 10 are moved in the direction of arrow A to reach the longest stroke position shown in FIG. Then, when the drive motor 16 is rotationally driven in the other direction from the longest stroke state in FIG. 8D, the second slider 10 is moved in the arrow B direction.

  Further, as shown in FIG. 7, the second slider 10 has a second slider body 20 formed with a dimension shorter than the length in the moving direction of the first slider 8, and a state parallel to the second slider body 20. And a pair of guided bodies 21L and 21R having dimensions shorter than the length of the first slider 8 respectively. Of the pair of guided bodies 21L and 21R, one guided body 21L is formed with a recess 21La extending in the same direction as the direction in which the first slider 8 should be moved (directions of arrows A and B). Further, ball-shaped second guide portions 21Lb that extend in the same direction as the extending direction of the concave portion 21La and slidably engage with the guide portion 14Lb of the rail 14L are formed on both inner side surfaces of the concave portion 21La. Has been.

Similarly, the other guided body 21R is also formed with a concave portion 21Ra and a second guide portion 21Rb slidably engaged with the guide portion 14Rb of the rail 14R.
As shown in FIG. 4, the second slider moving mechanism 11 is positioned between the pair of rails 14L and 14R on the first connecting end plate 15A of the first slider 8 via a shaft support 22i. A first pulley 22A provided, and a second pulley provided on the second connecting end plate 15B of the first slider 8 between the pair of rails 14L and 17R via a shaft support 22j. 22B and a belt 23 installed on the first pulley 22A and the second pulley 22B. Then, a part of the belt 23 is fixed to the fixing base 7 by a fixing tool 23a, and another part at a position opposite to the part (fixing tool 23a part) is a second slider body of the second slider 10. 20 is fixed by a fixing portion 23b.

  In the second slider moving mechanism 11, when the first slider 8 moves in the direction of arrow A from the state shown in FIG. 8A, the pulleys 22A and 22B also move accordingly. At this time, since a part of the belt 23 is fixed to the fixed base 7, the side 23 </ b> Q opposite to the fixed base 7 of the belt 23 further moves in the arrow A direction with respect to the moving first slider 8. As a result, the second slider 10 further moves in the direction of the arrow A with respect to the first slider 8, and after the states of FIGS. 8B and 8C, the longest stroke position (lowest position) of FIG. ).

For example, a hand or a camera is attached to the second slider 10 although not shown.
Now, the fall prevention mechanism 24 will be described with reference to FIGS. 1, 3, and 5 to 8. FIG. The fall prevention mechanism 24 includes a lever 25, and the lever 25 is composed of a long and narrow plate member. A support shaft 26 is integrally attached to the middle portion of the lever 25 in the longitudinal direction. The lever 25 is formed with a first long hole portion 27A corresponding to the first groove portion so as to extend in the one end direction from the vicinity of the support shaft 26, which is in the vicinity of the intermediate portion, and extends from the vicinity of the support shaft 26 in the other end direction. Thus, the second long hole portion 27B corresponding to the second groove portion is formed.

  A shaft hole 28 is formed in a direction perpendicular to the side surface of the rail 14 in the intermediate portion of the rail 14R, which is an intermediate portion between the pulleys 22A and 22B in the first slider 8 (a point equidistant from each pulley). .

  A first pin 29A and a second pin 29B are attached to the base body 12 in the fixed base 7 and the second slider body 20 in the second slider 10 in a protruding state at point-symmetric positions with the support shaft 26 as a center point. It has been. These outer diameter dimensions are set to dimensions that can be inserted movably into the first long hole portion 27A and the second long hole portion 27B with little play.

The lever 25 is pivotally supported at an intermediate portion of the first slider 8 between the pulleys 22A and 22B by the support shaft 26 being rotatably inserted into the shaft hole 28. ing. In this case, the first pin 29A is movably inserted into the first long hole portion 27A, and the second pin 29B is movably inserted into the second long hole portion 27B.
The lengths of the first long hole portion 27A and the second long hole portion 27B are set longer than the moving region of the first pin 27A and the second pin 27B determined by the setting stroke of the second slider 10.

  The operation of the above configuration will be described. Now, the belt is not in a normal state (the state shown in FIG. 8A), and the fall prevention mechanism 24 is broken (for example, the support shaft 26 is fixed to the shaft hole 28). It is assumed that it is not in a state of malfunction. In this state, when the first slider moving mechanism 9 (not shown in FIG. 8, see FIGS. 2 and 3) moves the first slider 8 in the vertical downward direction (arrow A direction), a part is fixed. The pair of pulleys 22 </ b> A and 22 </ b> B of the first slider 8 also move with respect to the belt 23 fixed to the base 7, so that the side portion 23 </ b> Q (see FIG. 8A) of the belt 23 becomes the first slider 8. On the other hand, it further moves in the direction of arrow A.

  As a result, the second slider 10 connected to the belt 23 by the fixing tool 23b in the side portion 23Q receives the moving force from the belt 23 and moves relatively ahead of the first slider 8. In this case, the moving speed of the second slider 10 is twice the moving speed of the first slider 8. The moving state is shown in FIGS. 8B and 8C. Then, as shown in FIG. 8D, the second slider 10 reaches a preset lowermost position.

  When the first slider 8 and the second slider 10 move as described above, the second pin 29B provided on the second slider 10 also moves vertically downward, so that the second pin 29B becomes the second second of the lever 25. The inner surface of the long hole portion 27B is pushed downward. Since the moving speed of the second pin 29B is twice as fast as the support shaft 26 of the first slider 8, the lever 25 rotates about the support shaft 26 in the direction of arrow K (see FIG. 8A). To do. In this case, the first pin 29A is inserted and arranged in one first long hole portion 27A of the lever 25. The first pin 29A and the second pin 29B are arranged in a point-symmetric arrangement with the support shaft 26 as the center. Therefore, the lever 25 rotates without hindrance.

  Thereafter, when the first slider 8 is moved upward (in the direction of arrow B) by the first slider moving mechanism 9 from the state shown in FIG. 8D, the state shown in FIGS. ) To reach the uppermost position in FIG. In this case, since the first slider 8 and the second slider 10 move upward, the lever 25 is also rotated in the opposite direction to that described above and returns to the state shown in FIG.

  As described above, the fall prevention mechanism 24 only operates passively in accordance with the operation of the vertical multistage vertical device 3, and the configuration itself is as simple as the lever 25 is supported by the support shaft 26. Since it is a structure, failures such as sticking at the support shaft 26 hardly occur.

  Here, for example, assuming that the lever 25 is fixed at the above-described support shaft 26 and the fall prevention mechanism 24 is broken, the operation of the vertical multistage vertical device 3 will be described as follows. When the first slider moving mechanism 9 attempts to move the first slider 8 downward or upward (to operate the vertical multistage telescopic device 3), the lever 25 of the fall prevention mechanism 24 may move. In this case, the movement of the second pin 29B is blocked (locked), and as a result, the first slider 8 does not operate after all, that is, the vertical multistage telescopic device 3 does not operate. With this, it can be recognized that a failure has occurred in the fall prevention mechanism 24.

  Thus, even if a failure occurs in the fall prevention mechanism 24, the failure of the fall prevention mechanism 24 can be confirmed immediately by the inability of the vertical multistage telescopic device 3 to operate. Therefore, the vertical multistage vertical device 3 is not operated while the fall prevention mechanism 24 is out of order.

  Next, the case where the belt 23 of the first slider moving mechanism 9 is cut due to fatigue deterioration will be described. If the belt 23 of the first slider moving mechanism 9 is used for a long time, the belt 23 may be cut due to fatigue deterioration. In this case, the cutting timing is determined by the operator as a vertical multistage vertical device. 3 is stopped, each part is being inspected or under maintenance, or the vertical multistage vertical apparatus 3 is in operation.

  First, a description will be given of a case where the belt is unexpectedly cut when an operator stops the vertical multistage telescopic device with the fall prevention mechanism 24 in a normal state to perform robot maintenance or hand attachment. In this case, since the vertical multistage vertical device 3 is stopped, the first slider 8 and thus the support shaft 26 do not move, and the first pin 29A does not move originally, so that the lever 25 does not move. Yes. If the belt 23 is cut in this state, the support force to the second slider 10 by the belt 23 is lost, and the second slider 10 tries to fall vertically, but the lever 25 cannot move as described above. Since the second slider 29 is about to fall vertically, the second slider 29 is prevented from moving right below the second pin 29B by the second elongated hole 27B of the lever 25 having an oblique or horizontal shape. (2) The slider 10 is prevented from falling.

  Here, “the fall of the second slider 10” means that the restraint is released by cutting the belt 23 and the second slider 10 falls freely without receiving any drag from below. Therefore, in the present embodiment, it is predicted that the presence of the first connecting end plate 15A causes the first connecting end plate 15A to function as a stopper against dropping of the second slider 10, but the first connecting end plate 15A does not prevent free fall of the second slider 10 when the belt 23 is cut. In this embodiment, since the second slider 10 can be prevented from falling (free fall), if the second slider 10 does not hit the first connecting end plate 15A, the first connecting end has a lot of momentum. It does not fall off the plate 15A.

In the present embodiment, since the fall prevention mechanism 24 is provided, no other stopper or the like is inherently necessary. For this reason, for example, the first connecting end plate 15A is connected to the end surfaces of the rails 14L and 14R. It is good also as a structure which connects between the mutually opposing side surfaces instead of between connection.
Next, the case where the belt 23 is broken while the vertical multistage expansion / contraction device 3 is operating will be described. First, the belt 23 is broken while the second slider 10 is moved downward. The case will be described with reference to FIG.

  If the belt 23 is cut at the timing shown in FIG. 9B (the timing at which the first slider 8 moves downward (in the direction of arrow A)), the second slider 10 is no longer supported by the belt 23. The weight of the second slider 10 (the weight of the hand attached to the second slider 10 in addition to the weight of the second slider 10 is applied) acts on the lever 25 vertically downward. Since the lever 25 is passively rotated (rotation in the direction of arrow K about the support shaft 26) as the first slider 8 moves in the direction of arrow A, the second pin 29B is inclined. The movement is restricted by the second long hole portion 27 </ b> B forming the structure, and it does not fall at a stretch.

  Then, the second pin 29B and thus the second slider 10 moves downward following the rotation of the lever 25 in the direction of the arrow K, and the first slider 8 is moved to the lower limit position shown in FIG. For the lever 25, the rotation of the lever 25 stops in a form that intersects the second slider 10 that can move only directly below the rotation limit position in the direction of the arrow K). The vertical downward movement of the second pin 29B is stopped by the hole 27B. Therefore, the second slider 10 does not fall even at this lower limit position.

  When the first slider 8 receives a force in the upward direction, which is the reverse direction, from the lowest position, the lever 25 also moves in the direction indicated by the arrow H (the direction opposite to the arrow K, FIG. 9D). The second pin 29B receiving the downward load of the second slider 10 prevents the rotation in the direction of the arrow H, so that the first slider moving mechanism 9 functions as a result. In other words, the vertical multistage vertical device 3 is stopped. By this stop operation, the occurrence of cutting of the belt 23 is immediately recognized by the operator.

  In addition, when the belt 23 is cut at the timing when the second slider 10 is moved upward (the timing when the other end of the lever 25 is rotated in the direction of the arrow H), the belt 23 is cut. As a result, the second slider 10 tries to move downward (fall) due to its own weight, but the lever 25 is passively moved in the direction of the arrow H in accordance with the operation of the first slider moving mechanism 9, that is, the operation of the vertical multistage expansion / contraction device 3. Since it is rotating, the second slider 10 is supported by the lever 25 and does not fall. That is, also in this case, the second slider 10 can be prevented from dropping. At the same time, for the vertical multistage vertical device 3, when the downward load is applied to the second slide 10, the lever 25 cannot be pushed up against the load, and the first slider moving mechanism 9 is immediately The function is stopped, that is, the vertical multistage vertical device 3 is abnormally stopped. As a result, the operator immediately notices that the belt 23 has been cut.

  Thus, according to the present embodiment, the fall prevention mechanism 24 is pivotally supported by the support shaft 26 at the intermediate portion between the pulleys 22A and 22B in the first slider 8, and the support shaft 26 A lever 25 having a first long hole portion 27A and a second long hole portion 27B extending from one end to the other end side, and a lever 25 provided on the fixed base 7 and slidably inserted into the first long hole portion 27A. A first pin 29A, and a second pin 29B provided on the second slide 10 and slidably inserted into the second long hole portion 27B. The first pin 29A and the second pin 29b are provided. A point-symmetric arrangement is made around the support shaft 26. Thereby, the passive fall prevention mechanism 24 linked with the active vertical multistage expansion / contraction device 3 without an active member such as a conventional spring can be realized. In addition, in this case, the configuration of the fall prevention mechanism 24 is such that the lever 29, the first pin 29A, and the second pin 29B are included, so that the configuration is very simple, and the failure occurrence probability of the fall prevention mechanism 24 itself can be lowered.

  Furthermore, since the fall prevention mechanism 24 is configured as described above, the lever 25 linked to the vertical multistage telescopic device 3 immediately resists the fall of the second slider 10 when the belt 23 is cut. Even when the belt 23 is cut off when the multistage expansion / contraction device 3 is stopped operating, or even when the belt 23 is cut off while the vertical multistage expansion / contraction device 3 is operating, the second slider is surely provided. 10 can be prevented, and the operation of the vertical multi-stage telescopic device 3 can be stopped quickly.

  And since the fall prevention mechanism 24 is passively operated by the vertical multistage expansion / contraction device 3 that is actively operated, if the fall prevention mechanism 24 breaks down for some reason, the vertical multistage expansion / contraction is performed as described above. The operation of the device 3 itself stops, and the operator can easily and immediately notice that the fall prevention mechanism 24 has failed. As a result, it is possible to prevent a worker from approaching the robot 1 without noticing the failure of the fall prevention mechanism 24, and the safety aspect can be remarkably enhanced when using the robot 1.

  Since the vertical multistage telescopic device 3 always operates on the condition that the fall prevention mechanism 24 has not failed, the vertical multistage telescopic device 3 and thus the robot 1 operates without causing the fall prevention mechanism 24 to malfunction. Can be eliminated.

  As can be seen from the above-described embodiments, the fall prevention mechanism of the present invention reliably prevents the member (second slider) holding the workpiece or the like from dropping in the robot in which the safety of the worker is pursued, and the fall. It is a quick reminder of the failure of the prevention mechanism itself, and is different from a lever mechanism or a link mechanism that operates simply as a seesaw.

  The present invention is not limited to the first embodiment described above, and may be modified as follows. The shape of the lever may be the shape of the lever 31 shown in FIG. 10 in addition to the shape of the lever 25 of the first embodiment. That is, in the first embodiment, the first and second groove portions of the lever 25 are opened to the first long hole portion 27A in which the insertion tip end side of the first pin 29A and the second pin 22B is opened and both ends are ends. Although comprised from the 2nd long hole part 27B, in the lever 31, as the 1st groove part and the 2nd groove part, the 1st groove part 32A and the 2nd groove part 32B of the cross-sectional U shape which the insertion tip side of the 1st pin and the 2nd pin obstruct | occluded The first groove 32A and the second groove 32B are open at the distal end side of the lever 31.

As shown in FIG. 11, the first pin 29 </ b> A may be attached to the rail sliding body 13 </ b> R of the fixed base 7, and the second pin 29 </ b> B may be attached to the guided body 21 </ b> R of the second slider 10.
Further, the fixed base of the vertical multistage telescopic device may not be configured to be attached to the horizontal moving mechanism, but may be attached to a moving mechanism that can move in an arbitrary direction, or may be attached to a fixed wall or a fixed frame.

  In the drawings, 1 is a robot, 2 is a horizontal movement mechanism, 3 is a vertical multistage telescopic device, 7 is a fixed base, 8 is a first slider, 9 is a movement mechanism for a first slider, 10 is a second slider, and 11 is a first slider. 2 Slider moving mechanism, 14L and 14R are rails, 15A is a first connecting end plate, 15B is a second connecting end plate, 22A and 22B are pulleys, 23 is a belt, 24 is a fall prevention mechanism, 25 is a lever, and 26 is The support shaft, 27A is a first long hole (first groove), 27B is a second long hole (second groove), 29A is a first pin, and 29B is a second pin.

Claims (1)

A fixed base, a first slider provided on the fixed base so as to be movable in the vertical direction and moved by a moving mechanism for the first slider, a second slider provided on the first slider so as to be movable in the vertical direction, The first slider has pulleys respectively provided at both ends in the vertical direction and belts installed between the pulleys, and a part of the belt is connected to the fixed base and forms a counter electrode with the part. A vertical multistage telescopic device connected to the second slider and comprising a second slider moving mechanism for moving the second slider in the same direction as the first slider as the first slider moves. And an industrial robot equipped with a fall prevention mechanism for preventing the second slider from dropping,
The fall prevention mechanism,
A lever having a longitudinally intermediate portion rotatably supported by a support shaft at an intermediate portion between the pulleys of the first slider;
A first groove formed on the lever so as to extend linearly from the vicinity of the support shaft toward one end;
A second groove formed in the lever so as to extend linearly from the vicinity of the support shaft toward the other end;
A first pin provided on the fixed base and movably inserted into the first groove,
A second pin provided on the second slider and movably inserted into the second groove,
The industrial robot according to claim 1, wherein the first pin and the second pin are arranged symmetrically with respect to the support shaft.

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