JPH0343174A - Automatic tool exchange device - Google Patents

Abstract

PURPOSE:To enable a bonding of a large tolerance even when the alignment prior to bending is defective by composing a locking pin which advances and retreates by perpendicularly intersecting to the attaching and detaching directions of a fixed plate and a tool plate so as to fit into a lock hole by a taper engaging style. CONSTITUTION:When a cylinder 4 is worked and an actuator 5 is descended after fitting a fixed plate 1 into a tool plate 2, the actuator spreads the base end part of a locking pin 3, inserting the tip of the locking pin 3 into a lock hole 6. At this time, the locking pin 3 and lock hole 6 perform a taper engagement, so even in the case of these axes being slipped the locking pin 3 is aligned at slightly upper part from the lock hole 6 and if the tip thereof is included in the opening of the lock hole 6, the lock pin 3 proceeds while lifting the tool plate 2 according to the progress of the engagement and the lock hole 6 is fitted in by profiling to the lock pin 3 corresponding thereto. Both plates 1 and 2 are thus linked by pulling close each other.

Description

DETAILED DESCRIPTION OF THE INVENTION [Field of Industrial Application] The present invention relates to an automatic tool changer that is used in a robot hand or the like and is capable of automatically changing tools.

[Conventional technology]

An automatic tool changer for changing machining tools is attached to the arm of the industrial robot. This automatic tool changer is capable of aligning and connecting a tool plate with integrated tools to a fixed plate connected to a robot arm.

FIG. 6 is a schematic diagram showing a structure for attaching and detaching the fixing plate 50 and the tool plate 51, which has been conventionally adopted. In the example shown in FIG. 5A, a mounting hole 52 is formed in a fixed plate 50, and a shaft 53 that fits into the mounting hole 52 is provided in a tool plate 51. These mounting holes 52 and shafts 53
has an axis parallel to the attachment/detachment direction of the fixed plate 50 and the tool plate 51, and by providing a plurality of sets, the position of the tool plate 51 relative to the fixed plate 50 can be determined. Then, after aligning the mounting hole 52 and the shaft 53 and fitting them, these plates 50 and 51 are integrated by a mechanism that restrains the tool plate 51 to the fixed plate 50 side. In addition, the same figure (b) shows the tool 5.
In this example, the shank 54a of No. 4 is inserted into the shank receiver 50a of the fixed plate 50, and the tool 54 is aligned and mounted on the fixed plate 50 by the pair of mounting holes 52 and shafts 53.

[Problem to be solved by the invention]

In this way, in order to attach and detach the tool plate and the tool itself to the fixed plate on the robot hand side, the attachment hole 52 and the shaft 53 are used.
Since the fitting between the mounting hole 52 and the shaft 53 is utilized, it is necessary to align each mounting hole 52 and the shaft 53 before coupling them. However, if the alignment is insufficient, a large load will be applied to the mounting hole 52 and the shaft 53 during connection, and there is a risk that the fixing plate 50, the tool plate 51, and the tool 54 themselves will be damaged. As described above, in the conventional structure, the quality of alignment before joining with the tool side has become an important issue.

On the other hand, in an automatic tool changer, in order to use various tools interchangeably, it is important to have a coupling function with the tool side and a positioning function to accurately position the tool after coupling.

Among these functions, in the positioning function, a considerably large load is applied to the positioning element during connection with the tool side and during machining. Further, since it is generally preferable for the coupling function to be miniaturized, the positioning function and the coupling function are each constituted by separate component elements. This results in an increase in the number of parts, a complicated structure, and an increase in weight.

Furthermore, the purpose of positioning the fixed side and tool side in an automatic tool changer is to accurately connect the axial direction of the fixed side and the plane coordinates with the origin on this axis in a three-dimensional manner. .

In order to improve the accuracy of such three-dimensional coupling, conventionally it has been common to provide a positioning member corresponding to each positioning axis. Therefore, the structure becomes quite complex and, including the separate provision of coupling and positioning functions, further increases the weight.

SUMMARY OF THE INVENTION Therefore, an object of the present invention is to provide a simple structure that can absorb the misalignment between the tool side and the stationary side and combine them, while also allowing highly accurate positioning.

[Means to solve the problem]

In order to achieve the above object, the present invention is an automatic tool changer in which a fixed plate connected to an arm of a robot hand, etc., and a tool plate equipped with a tool are detachably attached, The fixing plate is provided with a lock pin that moves forward and backward in a direction perpendicular to the attachment/detachment direction, the tool plate is provided with a lock hole into which the lock pin is fitted, and the lock pin and the lock hole are of a tapered fitting type. shall be.

[Effect]

FIG. 1 is a longitudinal cross-sectional view of a main part showing the fastening of the automatic tool changer of the present invention, and FIG. 2 is a cross-sectional view, and the present invention will be explained in detail using these figures.

In the figure, a fixed plate 1 is connected to the tip of an arm A of a robot hand, and a tool plate 2 is detachably attached to the fixed plate 1.

As shown in FIG. 2, the fixed plate 1 has a circular cross section and has three lock pins 3 that can move forward and backward in the radial direction from the center.
It is equipped with The tips of these lock pins 3 are formed into a tapered shape and are biased toward the center by elastic means, and when the tool plate 2 is not attached, the tips are as shown in Fig. 2 (
As shown in a), the tip is set at a position where it does not protrude. Furthermore, a cylinder 4 for pushing out the lock pin 3 is formed inside the fixed plate 1, and an actuator 5 for the cylinder 4 is formed for pushing out the lock pin 3.
The tapered portion at the tip fits into the base end portions of the three lock pins 3. This operation of the actuator 5 pushes the lock pin 3 outward as shown in FIGS. 1 and 2) and FIG. 2(b).

On the other hand, the tool plate 2 has necessary tools 2a attached to one side, and has a concave cross-sectional shape into which the fixed plate 1 is fitted. A lock hole 6 into which a lock pin 3 is fitted is provided in the peripheral wall 2b. This lock hole 6 is a taper hole that matches the taper portion of the lock pin 3, and the tool plate 2 is connected and held to the fixed plate 1 by the lock pin 3 and the lock hole 6 having a tapered fit.

After fitting the fixing plate 1 into the tool plate 2, actuate the cylinder 4 to lower the actuator 5 as shown in the figure, which will push the base end of the lock pin 3 apart, causing the locking pin 3 to spread out. Insert the tip of the lock pin 3 into the lock hole 6 as shown in (b).

At this time, the lock pin 3 and the lock hole 6 are fitted with a taber, so even if their axes are misaligned, the lock pin 3 can be positioned slightly above the lock hole 6 so that its tip is inside the opening of the lock hole 6. If the lock pin 3 is included in the tool plate 2, as the fitting progresses, the lock pin 3 advances while lifting the tool plate 2,
Correspondingly, the lock hole 6 follows the lock pin 3 and fits into it.

Therefore, even if the alignment is not sufficient, the lock pin 3
The connection between the lock hole 6 and the lock hole 6 is easily performed. Further, the tool plate 2 and the fixing plate 1 are drawn toward each other by the taper fitting between the lock pin 3 and the lock hole 6, so that positioning and connection can be performed simultaneously and reliably even without a mechanism for restraining in the attachment/detachment direction.

〔Example〕

The outline of the automatic tool changer of the present invention is as shown in FIGS. 1 and 2, and FIG. 3 shows the specific structure of the main parts.

An actuating hole 7 is formed in the fixed plate 1 coaxially with the cylinder 4, and the actinator 5 moves therein. Also,
A holding hole 8 for the lock pin 3 extends radially through the operating hole 7 . The holding hole 8 is formed by coaxially disposing a guide portion 8a at the tip and a spring storage portion 8b having a larger diameter than the guide portion 8a.

The lock pin 3 has seven flange 3a formed on the base end side that slides on the inner circumferential wall of the spring housing portion 8b, and has a tapered tip portion 3b. 7 The back surface of the flange 3a is formed into a pointed conical surface 3C as shown in the figure, so that forward and backward movement perpendicular to the movement of the actuator 5 is smooth. Further, the spring storage portion 8b has a flange 3a.
A spring 8C is arranged, one end of which abuts against, and the lock pin 3 is urged toward the center. This spring 8C
Due to the biasing force, when the actuator 5 is in the position shown by the dashed-dotted line in FIG. 3, the lock pin 3 is retracted to the position shown by the dashed-dotted line in the figure, and its tip is housed in the holding hole.

The cylinder 4 is incorporated inside the fixed plate 1 and includes ports 4a and 4b for supplying and discharging working fluid.

A piston 5a with an actuator 5 integrated therein is provided inside, and the actinator 5 is driven up and down in the figure by supplying and discharging working fluid.

The circumferential surface of the actuator 5 includes a tapered portion 5b from the lower end,
A straight portion 5C and a retightening tapered portion 5d are respectively formed. The inclinations of the tapered portion 5b and the retightening tapered portion 5d are set approximately equal to the inclination of the conical surface on the back surface of the flange 3a.

Further, the lock holes 6 provided in the tool plate 2 are provided in accordance with the positions of the lock pins 3, and the fixing plate 1 and the tool plate 2 are positioned using the restraint provided by these holes. The lock hole 6 is located at the tapered portion 3b of the lock pin 3.
It is formed as a tapered hole matching the inclination of the lock pin 3, and is fitted with a taper together with the lock pin 3.

In the above configuration, the fixed plate 1 and the tool plate 2
The connection is performed as follows. First, after approximately aligning the three lock pins 3 with the lock holes 6 of the tool plate 2, the fixing plate 1 is inserted into the tool plate 2 as shown in FIG. 1(a). Thereafter, the actuator 5 is lowered by feeding the working fluid from the port 4a using an external hydraulic oil supply system. Due to this movement of the actuator 5, the back surface of the flange 3a collides with the tapered part 5b, the straight part 5C, and the retightened tapered part 5d in this order, and the lock pin 3 is pushed outward. The tapered portion 3b at the tip of the lock pin 3 protrudes from the circumferential surface of the fixed plate 1 and fits into the lock hole 6 in the inner circumferential wall of the tool plate 2.

Here, as shown in FIGS. 5(a) and 5(b), the axis of the lock pin 3 at the initial stage of fitting with respect to the center of the lock hole 6 is
Even if the lock pin 3 is deviated horizontally by e and vertically by E, the lock pin 3 can be fitted into the lock hole 6 tightly in the end. That is, since the lock pin 3 and the lock hole 6 taper fit, if the tip of the lock pin 3 is included in the opening of the lock hole 6 and the lock hole 6 is in a position where the lock pin 3 can be lifted, the tapered surface As a result, the lock hole 6 gradually fits into the lock pin 3 while being aligned. Therefore, even if the positioning of the lock pin 3 and the lock hole 6 is not accurate, they can be fitted smoothly and well.

When the locking pin 3 is fitted into the locking hole 6, the positioning of the fixed plate 1 and the tool plate 2 is completed, and at the same time these plates 1.2 are restrained to each other. That is, since the lock pin 3 and the lock hole 6 are fitted with a Taber, as the degree of fitting becomes stronger, a force that attracts the fixing plate 1 and the tool plate 2 acts in a direction perpendicular to the Taber axis in which they are connected. Therefore, even if a fitting shaft is not provided in the attachment/detachment direction between the fixed plate 1 and the tool plate 2, these members can be firmly connected by taper fitting, and machining using the tool 2a can be performed well. be exposed.

Further, even if the working fluid supply system to the cylinder 4 breaks down and the pressure cannot be maintained by the working fluid, the lock pin 3 and the lock hole 6 can remain fitted in the lock pin 3 and the lock hole 6. That is, in FIG. 3, when the working pressure of the working fluid supplied from port 4a decreases, the piston 5a moves upward when an external force acts on it. On the other hand, since the conical surface 3C of the plunger 3a is in contact with the retightening tapered portion 5d as shown in the figure, a component force is exerted to move the actuator 5 upward. As a result, the actuator 5 starts to move upward, but the apex 3 of the conical surface 3C of the flange 3a
When d leaves the retightening tapered portion 5d and hits the straight portion 5C, the lock pin 3 applies a pressing force only in the direction orthogonal to the axis of the actuator 5. Therefore, the component force that tries to move the actuator 5 upward is eliminated, and the actuator 5 is held at the position where the apex 3d of the conical surface 3C is in contact with its straight portion 5C. Therefore, if the dimensions are set so that the tapered part 3b at the tip remains in the lock hole 6 when the apex 3d moves until it touches the straight part 5C, even if the working fluid supply system or the cylinder 4 itself breaks down,
The fixed plate 1 and the tool plate 2 remain locked. Once locked in this way, the tool plate 2 will not separate from the fixed plate 1 unless it is released by operating the cylinder 4, and the tool plate 2 will fall even if the working fluid supply system etc. breaks down during machining. Work can be done safely without any accidents.

FIG. 4 is a sectional view showing another embodiment.

In the figure, the holding hole 8 is a hole of equal diameter, and a lock pin 3 having a tapered portion 3b at its tip is slidably housed therein. - The actuator 5 and the lock pin 3 are connected by a connecting rod 9. This connecting rod 9 has a pin 11
．． 12 to connect the actuator 5 and lock pin 3 to 2.
It connects as a joint and locks using a toggle mechanism.

That is, when the actuator 5 descends, the lock pin 3 sliding in the holding hole 8 moves outward by the slider crank mechanism, and when the pins 11 and 12 are aligned in a straight line as shown in the figure, the lock pin 3 slides into the lock hole. 6, allowing for strong locking using the toggle mechanism.

Furthermore, when the working fluid supply system fails, the actuator 5 attempts to rise, but this is also prevented by the connecting rod 9. In other words, in the lock shown in FIG. 4, the pins 11 and 12, which correspond to the joints, are in the dead center state where they are lined up in a straight line, so the restraint reaction force on the lock hole 3 acts in a direction perpendicular to the axis of the actuator 5. . and,
This acting force is quite large because a toggle mechanism is used, and the movement of the actuator 5 in the axial direction is also restrained, thereby suppressing the movement. Therefore, once locked, the lock will not be released as in the case of FIG. 3 unless the actuator 5 is operated, and machining can be performed while the tool plate 2 is held on the fixed plate 1.

Incidentally, if a spring IO is provided in the cylinder 4 to urge the actuator 5 downward, it is possible to approximate the state of the dead center.

In this way, by using the taper structure shown in Fig. 3 or the toggle mechanism shown in Fig. 4, even if a failure occurs in the working fluid supply system or cylinder 4, the tool plate 2 will not be unlocked. , safe processing can be performed.

Note that the tip of the lock pin 3 may have a spherical shape instead of being tapered. Even in the case of a spherical shape, it goes without saying that its outer diameter should be smaller than the diameter of the open end of the lock hole 6 so that it can be sufficiently fitted into the lock hole 6.

〔Effect of the invention〕

As described above, in the present invention, the lock pin, which moves back and forth orthogonally to the attachment/detachment direction of the fixed plate and the tool plate, is fitted into the lock hole using a tapered fitting type. Therefore, unlike the conventional structure, there is no shaft in the attachment/detachment direction between the tool side and the fixed side, and there is no fitting part with the coupling hole, so even if the alignment before coupling is poor, coupling with a large tolerance is possible. Become. Therefore, the joining operation can be performed quickly without wasting time on positioning, and the time required for teaching the robot can be significantly shortened.

In addition, since the fixed plate and tool plate can be connected and positioned only by a combination of lock pins and lock holes, the structure is simpler and the weight is reduced compared to the conventional case where the connection and positioning functions are provided separately. At the same time, it is also advantageous in terms of cost.

Furthermore, even if the actuator that moves the lock pin after locking or the working fluid supply system breaks down, the combination of the pointed shape of the lock pin and the provision of a straight part midway through the taper part of the actuator, and the connection that forms the toggle mechanism By using the rod, the lock will not be released unless the actuator is driven. Therefore, even if the working fluid supply system breaks down during machining work, the tool plate will not separate from the fixed plate, and safe work can be achieved.

[Brief explanation of drawings]

FIG. 1(a) is a schematic cross-sectional view showing the fixing plate and tool plate before they are combined, FIG. 1(a) is a schematic cross-sectional view showing them after they are combined, and FIG. Figure 2(b)
3 is a schematic cross-sectional view after coupling, FIG. 3 is a cross-sectional view of the main part showing the drive structure of the lock pin by an actuator, FIG. 4 is a cross-sectional view of the main part showing an example using a toggle mechanism, and FIG. 6 is a diagram for explaining how a lock pin is fitted by the taper fitting method, and FIG. 6 is a schematic diagram of a conventional example. 1: Fixed plate 2: Tool plate 2a: Tool
2b Two peripheral walls 3: Lock pin 3a: Flange 3b: Tapered part 3C: Conical surface 3d: Vertex 4 Niji cylinder 4a, 4b: Port 5: Actuator 5a: Piston 5b: Tapered part 5C: Straight part 5d: Retightening taper part 6: Lock Hole 7: Operating hole 8: Holding hole 8a = Mini guide b Nispring storage section 8C Nispring 9: Connecting rod

Claims (1)

[Claims] 1. An automatic tool changer in which a fixed plate connected to an arm of a robot hand or the like and a tool plate equipped with a tool are detachably attached, the tool changer being orthogonal to the direction of attaching and detaching the tool to and from the tool plate. An automatic tool exchange characterized in that a lock pin that moves forward and backward in the direction is provided on a fixed plate, the tool plate is provided with a lock hole into which the lock pin is fitted, and the lock pin and the lock hole are of a tapered fitting type. Device. 2. The lock pin is incorporated so as to be able to come into contact with the circumferential surface of an actuator driven by a cylinder provided on the fixed plate side, and is capable of moving back and forth in the direction of the lock hole due to the tapered shape of the actuator. The automatic tool changer according to claim 1. 3. The automatic tool changer according to claim 2, wherein the surface of the lock pin that abuts against the circumferential surface of the actuator is pointed, and a circumferential surface parallel to the axis is formed in the middle of the tapered shape of the actuator. . 4. The automatic tool changer according to claim 1, wherein the actuator and the lock pin are connected by two connecting rods forming a toggle mechanism.