阅读说明：本技术 转移进给器装置及转移进给器装置的控制方法 (Transfer feeder device and control method of transfer feeder device ) 是由 藤田健 金子外幸 于 2021-06-01 设计创作，主要内容包括：本申请提供一种可设置与转移进给器装置的转移杆的活动相配合的定时开关的切换点的转移进给器装置等。在压力机中,转移进给器装置用基于与主相位信号同步的转移用独立相位信号的转移运动进行工件的运输运转,包括：设置部,其将到基于转移运动的转移杆的轨迹上的基准点的距离是使用者所指定的指定距离的轨迹上的点,设置为定时开关的切换点；以及信号输出部,其在转移杆到达切换点的定时,将定时信号输出给外部装置。(The present application provides a transfer feeder device and the like that can set a switching point of a timer switch in cooperation with the movement of a transfer lever of the transfer feeder device. In a press, a transfer feeder device for performing a transfer operation of a workpiece with a transfer motion based on a transfer independent phase signal synchronized with a main phase signal, comprising: a setting section that sets, as a switching point of the time switch, a point on a trajectory where a distance to a reference point on a trajectory of the transfer lever based on the transfer motion is a specified distance specified by a user; and a signal output unit that outputs a timing signal to the external device at a timing when the transfer lever reaches the switching point.)

1. A transfer feeder apparatus for performing a conveying operation of a workpiece by a transfer motion based on a transfer independent phase signal synchronized with a main phase signal, comprising:

a setting section that sets, as a switching point of a time switch, a point on a trajectory where a distance from a reference point on the trajectory of a transfer lever based on the transfer motion is a specified distance specified by a user; and

and a signal output unit that outputs a timing signal to an external device at a timing when the transfer lever reaches the switching point.

2. The transfer feeder device of claim 1, wherein:

the transfer motion is composed of a combination of a releasing motion, a returning motion, a clamping motion, a lifting motion, a forward motion, and a lowering motion of the transfer lever,

the reference point is a point at which the motion of the transfer lever changes.

3. The transfer feeder device of claim 2, wherein:

the setting section sets an overlap section, which is an overlap section in which the transfer lever starts an action in a second direction before terminating an action in a first direction among a feeding direction, a gripping direction, and a lifting direction and simultaneously moves in the first direction and the second direction, and sets, as the switching point, a point on the trajectory when the overlap section is not set, at which a distance from the reference point is the specified distance, when the overlap section is set between the reference point and the switching point.

4. Transfer feeder device according to claim 2 or 3, wherein:

the setting section sets an overlap section, which is an overlap section in which the transfer lever starts an action in a second direction before terminating an action in a first direction among a feeding direction, a gripping direction, and a lifting direction and moves in the first direction and the second direction at the same time, and sets a point on the trajectory, at which a distance from the reference point in the second direction is the specified distance, as the switching point when the reference point is located within the overlap section.

5. Transfer feeder device according to any one of claims 2 to 4, wherein:

the setting section sets an overlap section, which is an overlap section in which the transfer lever starts an action in a second direction before ending an action in a first direction among a feeding direction, a gripping direction, and a lifting direction and simultaneously moves in the first direction and the second direction, and sets, as the switching point, a point on the trajectory in which a distance from the reference point in the first direction is the specified distance when the switching point is set within the overlap section.

6. A control method of a transfer feeder device that performs a transport operation of a workpiece by a transfer motion based on an independent phase signal for transfer synchronized with a main phase signal, characterized by comprising:

a setting step of setting, as a switching point of a timer switch, a point on a trajectory where a distance from a reference point on the trajectory of a transfer lever based on the transfer motion is a specified distance specified by a user; and

a signal output step of outputting a timing signal to an external device at a timing when the transfer lever reaches the switching point.

Technical Field

The present invention relates to a transfer feeder device and a control method of the transfer feeder device.

Background

The multi-station press system is composed of a press for performing press working and a transfer feeder device for transporting a workpiece (material). As the press machine, there are a conventional mechanical press machine using a gear, a cam, or the like for driving the press, and a servo press machine using a servo motor which has been developed in recent years. Similarly, there are a mechanical transfer feeder device which mechanically operates in conjunction with a crank angle (press angle) of a press and a servo transfer feeder device which uses a servo motor which has been developed in recent years. With the advent of servo presses, for example, complicated motions that could not be provided by conventional mechanical presses can be provided by controlling the servo motors by setting the speed or position at the time of machining by numerical values such as operating at a high speed during press machining and reducing the speed near the bottom dead center (lowest point of pressurization), or repeating the reverse rotation of the crankshaft while switching the rotational direction of the servo motors and reciprocating the slide only near the bottom dead center (forward and reverse motions). Therefore, the press working can be realized which ensures high quality and also gives consideration to productivity.

In a conventional multi-station press system, in the movement (transfer movement) of a transfer lever of a transfer feeder device, a start point and an end point of each movement (forward movement and return movement) in an X-axis (feed direction), a start point and an end point of each movement (clamping movement and unclamping movement) in a Y-axis (clamping direction), and a start point of each movement (lifting movement and lowering movement) in a Z-axis (lifting direction) are assigned by a press angle, and the transfer movement is linked with the movement of the press. Therefore, in the case of the transfer press system using the servo press, even if the transfer feeder device is set to be capable of freely performing the transportation motion by using the servo motor, for example, if the transfer feeder device is operated in conjunction with the press angle, the operation of the transfer feeder device is affected by the acceleration/deceleration, the rotational direction, or the like of the press, and the stable transfer motion cannot be performed. In order to solve the problem, a servo transfer feeder device is used in a multi-station press system having a servo press, the servo transfer feeder device performs a press operation by a press motion based on an independent phase signal for press operation by the servo press, instead of interlocking the operation of the press and the transfer feeder device in accordance with a press angle, and the servo transfer feeder device performs a transport operation by a transfer motion based on the independent phase signal for transfer, adjusts the timing and the phase so that the servo press and the servo transfer feeder device do not interfere with each other, and synchronizes and controls the respective phase signals with a master phase signal, thereby operating with a transfer motion most suitable for a freely set phase signal (patent document 1).

Documents of the prior art

Patent document

[ patent document 1 ] Japanese patent laid-open No. 2013-91078

Disclosure of Invention

Technical problem to be solved by the invention

In the conventional transfer press system, as shown in fig. 17, a point at which a timing switch is switched on or off (a point at which a timing signal is output to an external device) is set by designating a crank angle (press angle) of the press at each of the on time and the off time. In the example shown in fig. 17, the timing signal is set to be off when the press angle is 65 °, and the timing signal is set to be on when the press angle is 295 °. In the case of a mechanical transfer press system, since the movement of the transfer lever of the transfer feeder device (transfer movement) is also linked to the punching angle of the press, the position of the switching point of the time switch relative to the transfer movement can also be set with the punching angle. However, in the case of a servo multi-station press system in which the servo press and the transfer feeder are operated by different independent phase signals, the transfer motion is not directly related to the press angle, and therefore, the setting of the timing switch in accordance with the transfer motion cannot be performed.

The present invention has been made in view of the above-described problems, and an object thereof is to provide a transfer feeder device and a control method of the transfer feeder device, in which a switching point of a timer switch can be set in accordance with movement of a transfer lever of the transfer feeder device.

Means for solving the problems

(1) The present invention relates to a transfer feeder device for performing a transport operation of a workpiece by a transfer motion based on a transfer independent phase signal synchronized with a main phase signal, the transfer feeder device comprising: a setting section that sets, as a switching point of a time switch, a point on a trajectory where a distance to a reference point on the trajectory of the transfer lever based on the transfer motion is a specified distance specified by a user; and a signal output unit that outputs a timing signal to an external device at a timing when the transfer lever reaches the switching point.

Further, a method of controlling a transfer feeder device according to the present invention is a method of controlling a transfer feeder device that performs a transport operation of a workpiece by a transfer motion based on an independent phase signal for transfer synchronized with a main phase signal, the method including: a setting step of setting, as a switching point of a time switch, a point on a trajectory where a distance to a reference point on the trajectory of a transfer lever based on the transfer motion is a specified distance specified by a user; and a signal output step of outputting a timing signal to an external device at a timing when the transfer lever reaches the switching point.

According to the present invention, the switching point of the timer switch can be set by specifying the distance to the reference point located on the trajectory of the transfer lever without using the parameters (press angle) of other devices, and therefore the switching point of the timer switch can be set intuitively and easily while adjusting the timing in consideration of the movement of the transfer lever.

(2) In the transfer feeder device and the method for controlling a transfer feeder device according to the present invention, the transfer motion may be a combination of a releasing motion, a returning motion, a gripping motion, a lifting motion, a forward motion, and a lowering motion of the transfer lever, and the reference point may be a point at which the motion of the transfer lever changes.

With the present invention, by setting the point at which the movement of the transfer lever changes (the point at which the gripping movement changes to the lifting movement, the lifting movement changes to the advancing movement, the advancing movement changes to the descending movement, the descending movement changes to the releasing movement, the releasing movement changes to the returning movement, or the returning movement changes to the gripping movement) as the starting point (reference point) of the distance at which the switching point of the timer switch is set, it is basically possible to eliminate the need to change the set value (specified distance) of the switching point of the timer switch even if the transfer movement is changed.

(3) In the transfer feeder device and the method of controlling a transfer feeder device according to the present invention, the setting section may set (in the setting step) an overlap section that starts an action in a second direction before an action in a first direction is terminated among a feeding direction, a gripping direction, and a lifting direction and moves in the first direction and the second direction at the same time, and when the overlap section is set between the reference point and the switching point, a point on the trajectory where a distance from the reference point when the overlap section is not set is the specified distance may be set as the switching point.

With the present invention, even if the length of the overlap section (overlap amount) is changed, the set value (specified distance) of the switching point of the timer switch does not need to be changed.

(4) In the transfer feeder device and the method of controlling a transfer feeder device according to the present invention, the setting section may set (in the setting step) an overlap section, which is an overlap section in which the transfer lever starts an action in a second direction before terminating an action in a first direction among a feeding direction, a gripping direction, and a lifting direction and moves in the first direction and the second direction at the same time, and when the reference point is located within the overlap section, a point on the trajectory in which a distance from the reference point in the second direction is the specified distance may be set as the switching point.

(5) In the transfer feeder device and the method of controlling a transfer feeder device according to the present invention, the setting section may set (in the setting step) an overlap section, which is an overlap section in which the transfer lever starts an action in a second direction before terminating an action in a first direction among a feeding direction, a gripping direction, and a lifting direction and moves in the first direction and the second direction at the same time, and when the switching point is set within the overlap section, a point on the trajectory in which a distance from the first direction to the reference point is the specified distance may be set as the switching point.

Drawings

Fig. 1 is a block diagram of a servo multi-station press system including a transfer feeder device according to the present embodiment.

Fig. 2 is a front view of the servo press.

Fig. 3 is a diagram showing the trajectory of the transfer lever based on the transfer motion.

Fig. 4 is a diagram for explaining the setting of the switching point.

Fig. 5 is a diagram for explaining the setting of the switching point.

Fig. 6 is a diagram for explaining the overlapping section.

Fig. 7 is a diagram for explaining the overlapping section.

Fig. 8 is a diagram for explaining the overlapping section.

Fig. 9 is a diagram for explaining the overlapping section.

Fig. 10 is a diagram for explaining the overlapping section.

Fig. 11 is a diagram for explaining the setting of the switching point when the overlap section is set between the reference point and the switching point.

Fig. 12 is a diagram for explaining the setting of the switching point when the overlap section is set between the reference point and the switching point.

Fig. 13 is a diagram for explaining the setting of the switching point when the overlap section is set between the reference point and the switching point.

Fig. 14 is a diagram for explaining the setting of the switching point when the reference point is within the overlap section.

Fig. 15 is a diagram for explaining the setting of the switching point when the switching point is set in the overlap section.

Fig. 16 is a flowchart showing the flow of processing of the setting section and the signal output section.

Fig. 17 is a diagram for explaining a conventional example.

Detailed Description

Embodiments of the present invention are described below with reference to the drawings.

Fig. 1 is a block diagram of a servo multi-station press system including a transfer feeder device according to the present embodiment. The servo multi-station press system has a servo press 1 that performs press working, a servo transfer device 10 (transfer feeder device) that transports (transfers) a workpiece, and a transfer press operation control device 30. Fig. 2 is a front view of the servo press 1.

In the servo press 1, the slide 6, which is guided in the main body 9 so as to be movable up and down, is moved up and down by a slide driving mechanism (including the crankshaft 2 and the like). An upper die 7 is arranged on the sliding block 6, and a lower die 8 is arranged on a base plate (lathe). The crankshaft 2 is rotationally driven by a servomotor 4 via a gear mechanism. The crankshaft 2 is provided with a crankshaft encoder 3 that detects a rotation angle (press angle) of the crankshaft 2. The detected rotation angle signal θ ck of the crank encoder 3 is input to the shift press operation control device 30. By performing signal processing on the detected rotation angle signal θ ck, the press Speed (SPM) and the current vertical position (bottom dead center position, etc.) of the slide 6 can be detected. The servo motor 4 is provided with a motor encoder 5. The detected rotation angle signal θ pf from the motor encoder 5 is input to the servo press control device 21 and the servo amplifier 22 as for servo press control, and is also input to the transfer press operation control device 30.

The servo transfer device 10 is configured to transfer-drive (may be driven by two servo motors) a pair of right and left transfer levers 11 by a plurality of (three in this example) servo motors 14(14a, 14b, 14 c). The transfer lever 11 is provided with means (fingers, claw members, vacuum chucks, etc.) for gripping the workpiece. In the present embodiment, the transfer lever 11 is provided with a finger. The transfer lever 11 performs a transfer operation while partially repeating (overlapping) the unclamping operation, the returning operation, the clamping operation, the lifting operation, the advancing operation, and the lowering operation. The transfer lever 11 is operated in the feeding direction (return operation, forward movement) by the servo motor 14a, operated in the clamping direction (unclamping operation, clamping operation) by the servo motor 14b, and operated in the lifting direction (lifting operation, lowering operation) by the servo motor 14 c. The servo motors 14 are respectively provided with motor encoders 15. The detected rotation angle signal θ tf from the motor encoder 15 is input to the servo shift control device 25 and the servo amplifier 26 as well as to the shift press operation control device 30 for servo shift control.

The transfer press operation control device 30 includes a press motion storage device 34P, a transfer motion storage device 34T, an operation unit 36, a main phase signal generation output device 50, and an independent phase signal generation output device 60.

The user (operator) inputs the data Spmd for creating the press motion most suitable for the press working using the operation unit 36. The image of the punching motion is in the form of a graph having the value (for example, 0 ° to 360 ° value) of the independent phase signal for punching as the horizontal axis and the slider position as the vertical axis. The data Spmd is subjected to smoothing processing or the like and stored in the press motion storage device 34P as an image-based press motion. The stored punching motion is supplied to the servo-punching control means 21 and the independent phase signal generation output means 60.

Similarly, the user inputs data Stmd for creating the transfer motion most suitable for workpiece transport using the operation unit 36. The image of the transfer motion data is in the form of a graph having the value of the independent phase signal for transfer (for example, a value of 0 ° to 360 °) as the horizontal axis and the three-dimensional position of the transfer lever 11 (the positions in the feed direction (X-axis direction), the grip direction (Y-axis direction), and the lift direction (Z-axis direction)) as the vertical axis. The data Stmd is subjected to smoothing processing or the like and stored in the transition motion storage device 34T as an image-based transition motion. The stored transfer motion is provided to the servo transfer control means 25 and the independent phase signal generation output means 60.

The master phase signal generation output device 50 generates a master phase signal Smph using a clock signal output from an oscillation circuit in the CPU, and outputs the master phase signal Smph to the independent phase signal generation output device 60. When the shift press operation is started, the value of the master phase signal Smph rises from 0 °, and when it exceeds 360 °, it becomes 0 ° again, and this is repeated later.

The independent phase signal generation and output device 60 generates an independent phase signal for press Spmph synchronized with the master phase signal Smph from the input master phase signal Smph and the phase signal Spph based on the stored press motion, and outputs the generated independent phase signal for press Spmph to the servo press control device 21. Similarly, the independent phase signal generation and output device 60 generates an independent phase signal for transition Stmph synchronized with the master phase signal Smph from the input master phase signal Smph and the phase signal Stph based on the stored transition motion, and outputs the generated independent phase signal for transition Stmph to the servo transition control device 25.

The servo press control device 21 generates a press control signal Spc for matching the actual crank angle with the calculated target crank angle while referring to the independent phase signal for press Spmph and the detected rotation angle signal θ pf. The calculated crank target angle is an angle calculated as a crank target angle mechanically uniquely corresponding to the current slide target position obtained from the press motion (slide position data Spps). The generated press control signal Spc is amplified by the servo amplifier 22, and the servo motor 4 is rotationally driven as a press drive signal Spcd.

The servo transfer control device 25 generates a transfer control signal Stc for matching the actual motor angle with the calculated motor target angle while referring to the independent phase signal for transfer Stmph and the detected rotation angle signal θ tf. The calculated motor target angle is an angle calculated as a servo motor target angle for feeding, clamping, and lifting that is mechanically uniquely associated with the current target position (feed target position, clamping target position, and lift target position) of the transfer lever 11 obtained from the transfer motion (transfer position data Stps). The generated transfer control signal Stc is amplified by the servo amplifier 26, and rotationally drives the servo motor 4 as a transfer drive signal Stcd.

The servo transfer device 10 includes a setting section 28 and a signal output section 29. The functions of the setting unit 28 and the signal output unit 29 can be realized by hardware such as a processing unit (CPU) or an input/output interface on the servo transfer apparatus 10, or software such as a program stored in a storage unit on the servo transfer apparatus 10.

The setting section 28 sets, as a switching point of the time switch, a point on a trajectory (movement trajectory) of the transfer lever 11 based on the transfer motion, at which a distance to a reference point on the trajectory is a specified distance specified by the user, based on an operation input to the operation section 36 by the user. The reference point is, for example, a point at which the operation (the unclamping operation, the returning operation, the clamping operation, the lifting operation, the advancing operation, and the lowering operation) of the transfer lever 11 changes.

The signal output unit 29 acquires the current position of the transfer lever 11 (the three-dimensional position of the transfer lever 11 obtained from the actual motor angle of feeding, clamping, and lifting, etc.) based on a signal from the servo transfer control device 25, etc., and outputs a timing signal TS (on signal or off signal) to an external device at the timing when the transfer lever 11 reaches a switching point set on the trajectory. The external device is, for example, a grip error detection device or an external transport device that detects that the fingers of the transfer lever 11 do not grip the workpiece (grip error). For example, when the timing signal TS is output to the grip error and leak detection device, the grip error and leak detection device starts the detection of the grip error and leak when receiving the on signal from the signal output unit 29, and stops the detection of the grip error and leak when receiving the off signal from the signal output unit 29.

Fig. 3 is a diagram showing the locus of the transfer lever 11 based on the transfer motion. The following describes the trajectory of one of the pair of right and left transfer levers 11, but the same applies to the other. In the present embodiment, a reference point PR (PR) is set on the trajectory TR of the transfer lever 11₁～PR₆) Is provided at the point where the action of the transfer lever 11 changes. The reference point PR is a point that is set as a reference (starting point of a predetermined distance) when a switching point of the timer switch is set. More specifically, a reference point PR is provided at the start point of the return motion (the circuit moving motion in the X-axis direction) on the trajectory TR₁A reference point PR is provided at the start point of the gripping action (action of moving in the Y-axis direction to attach the finger to the workpiece)₂A reference point PR is provided at the start point of the lifting motion (the lifting motion in the Z-axis direction)₃A reference point PR is provided at the starting point of the forward movement (forward movement in the X-axis direction)₄A reference point PR is provided at the start point of the lowering operation (the lowering operation in the Z-axis direction)₅A reference point PR is provided at the start point of the unclamping operation (operation of moving in the Y-axis direction to separate the finger portion from the workpiece)₆。

In the present embodiment, the user designates the reference point PR, and designates the distance to the designated reference point PR, thereby setting the switching point of the timer switch. For example, as shown in fig. 4, when a switching point PS of the time switch (e.g., a point at which the time switch is switched on) is set at a position in the forward motion on the trajectory TR (a reference point PR as a starting point of the forward motion)₄And a reference point PR as a starting point of the lowering operation₅In between), the user specifies the reference point PR₄By specifying a reference point PR from which to specify₄An arbitrary distance d from the switching point PS may be from the reference point PR along the track TR₄A switching point PS is provided at a position on the trajectory TR where the distance d is set, and a conduction signal can be outputted to an external device at a timing when the transfer lever 11 reaches the switching point PS.

In this way, according to the present embodiment, the reference point PR (PR) located on the trajectory TR of the transfer lever 11 is specified without using the press angle₁～PR₆) Since the switching point PS of the timer switch can be set at the distance d, the switching point PS of the timer switch can be set intuitively and easily while adjusting the timing in consideration of the movement of the transfer lever 11. Further, by setting the point at which the movement of the transfer lever 11 changes as the starting point (reference point PR) of the distance d when the switching point PS is set, even if the transfer movement changes, the set value (specified distance) of the switching point PS basically does not need to be changed, and the convenience of the user can be improved. For example, even if the lift stroke (the moving distance in the Z-axis direction) of the transfer motion shown in fig. 4 increases, the transfer motion shown in fig. 5 is changed to the reference point PR₄The position of the switching point PS for the distance d does not change. Thus, the set value of the switching point PS does not need to be changed.

Here, the total distance of the trajectory TR of the transfer lever 11 is not limited to the sum of the double distance of the moving distance (feed stroke) in the X-axis direction of the forward movement and the return movement, the double distance of the moving distance (grip stroke) in the Y-axis direction of the gripping movement and the unclamping movement, and the double distance of the moving distance (lift stroke) in the Z-axis direction of the lifting movement and the lowering movement. As shown in fig. 3, this is because in the transfer motion, an overlap section in which the transfer lever 11 is simultaneously movable (starts movement in the second direction before terminating movement in the first direction) in the first direction and the second direction among the feeding direction (X-axis direction), the gripping direction (Y-axis direction), and the lifting direction (Z-axis direction) can be set. Specifically, an overlap section in which the return motion is started before the termination of the unclamping motion and the movement is performed in the Y-axis direction and the X-axis direction at the same time, an overlap section in which the gripping motion is started before the termination of the return motion and the movement is performed in the X-axis direction and the Y-axis direction at the same time, an overlap section in which the raising motion is started before the termination of the gripping motion and the movement is performed in the Y-axis direction and the Z-axis direction at the same time, an overlap section in which the advancing motion is started before the termination of the raising motion and the movement is performed in the Z-axis direction and the X-axis direction at the same time, an overlap section in which the lowering motion is started before the termination of the advancing motion and the movement is performed in the X-axis direction and the Z-axis direction at the same time, and an overlap section in which the unclamping motion is started before the termination of the lowering motion and the movement is performed in the Z-axis direction and the Y-axis direction at the same time may be provided. As shown in fig. 6, the length of the overlapping section (overlapping amount) may be expressed in percentage with respect to the range in which the overlapping section can be set.

When the overlap section is set, the distance on the trajectory TR of the transfer lever 11 that spans the overlap section is shorter than when the overlap section is not spanned (when the overlap amount is 0%). For example, as shown in fig. 7, in the transfer motion when the end of the lifting action and the start of the forward action are not overlapped (the overlap amount is 0%) when the lifting stroke is 200mm, the reference point PR as the start point of the lifting action is reached along the trajectory TR₃Is 400mm is the point P₁However, as shown in fig. 8, in the transfer motion when the termination of the lift motion and the start of the forward motion overlap (overlap amount L%), the trajectory TR is shifted to the reference point PR₃Is 400mm is the point P₂Is smaller than the point P in the transfer motion shown in FIG. 7₁Further downstream. Furthermore, as shown in fig. 9, during the transfer motion when the overlap amount is greater than 0% and less than L%, the reference point PR is reached along the trajectory TR₃Is 400mm is the point P₃Is smaller than the point P in the transfer motion shown in FIG. 8₂Further to the upstream side. Furthermore, as shown in fig. 10, in the transfer motion when the overlap amount is larger than L%, the reference point PR is reached along the trajectory TR₃Is 400mm is the point P₄Comparison point P₂Further downstream. As described above, when the overlap amount is changed, the position of a point located on an axis different from the axis on which the reference point PR is located, where the distance from the trajectory TR to the reference point PR is a predetermined distance, changes.

Therefore, in the present embodiment, when an overlap section is provided between the reference point PR and the switching point PS, a point at which the distance from the reference point PR on the trajectory TR when no overlap section is provided (the overlap amount is 0%) (the distance d along the trajectory TR when the overlap amount is 0%) is a specified distance is set as the switching point PS. For example, as shown in FIGS. 11 to 13, when the lift stroke is 200mm, if "to the reference point PR" is designated₃Is 400mm "is the distance d for setting the switching point PS, even in the transfer motion in which the termination of the lifting motion and the start of the forward motion overlap, the trajectory TR (the trajectory TR shown in fig. 7) when the termination of the lifting motion and the start of the forward motion do not overlap can be brought up to the reference point PR₃Is 400mm from a point P₁Set to the switching point PS. Although the overlap amount is L% in fig. 11, 0% < overlap amount < L% in fig. 12, and > L% in fig. 13, in either case, the point P at the same position will be located₁Set to the switching point PS. In this way, when the overlap section is set between the reference point PR and the switching point PS, the set value (the predetermined distance) of the switching point PS of the timer switch does not need to be changed even if the overlap amount is changed.

Further, when the reference point PR is located within the overlap section (the section in which the transfer lever 11 starts the motion in the second direction before terminating the motion in the first direction), a point on the trajectory TR at which the distance from the reference point PR in the second direction is the specified distance (distance d) is set as the switching point PS. For example, in the example shown in fig. 14, the reference point PR is located within an overlap section (start point of the overlap section) in which the operation in the α -axis direction (second direction) is started before the operation in the β -axis direction (first direction) is terminated. In this example, for example, when "the distance to the reference point PR is 25 mm" is specified as the distance d for setting the switching point PS, the point P on the trajectory TR at which the distance to the reference point PR in the α -axis direction is 25mm is specified₅Set as the switching point PS (the α -axis coordinate value of the switching point PS is set to 25 mm). Also, the same applies toWhen "the distance to the reference point PR is 50 mm" is designated as the distance d, the point P on the trajectory TR at which the distance to the reference point PR in the α -axis direction is 50mm is designated as the distance P₆Set to the switching point PS. Here, although the point at which the overlap section ends is the point P at which the distance from the reference point PR in the α -axis direction is 100mm₇However, the same applies to the case where the distance d exceeds 100 mm. For example, when "the distance to the reference point PR is 200 mm" is designated as the distance d, the point P on the trajectory TR at which the distance to the reference point PR in the α -axis direction is 200mm is designated as the point P₈Set to the switching point PS.

When the switching point PS is set in the overlap section (the section in which the transfer lever 11 starts the movement in the second direction before the movement in the first direction is terminated), a point on the trajectory TR at which the distance from the reference point PR on the axis in the first direction is the predetermined distance (distance d) is set as the switching point PS. In the example shown in fig. 15, an overlap section is provided in which the operation in the β axis direction (second direction) is started before the operation in the α axis direction (first direction) is terminated, the stroke length in the α axis direction is 200mm, and the point at which the overlap section is terminated is a point P having a distance of 300mm from the reference point PR on the trajectory TR when the overlap section is not provided₉. In this example, when the specified distance is less than 200mm (stroke length in the α -axis direction), a point on the trajectory TR, at which the distance from the reference point PR in the α -axis direction is the specified distance, is set as the switching point PS. For example, when "the distance to the reference point PR is 150 mm" is designated as the distance d, the point P on the trajectory TR at which the distance to the reference point PR in the α -axis direction is 150mm is designated as the point P₁₀Set as a switching point PS (the α -axis coordinate value of the switching point PS when the α -axis coordinate value of the reference point PR is set to 0 is set to 150 mm). Likewise, when "the distance to the reference point PR is 175 mm" is designated as the distance d, the point P on the trajectory TR at which the distance to the reference point PR in the α -axis direction is 175mm is designated as the point P on the trajectory TR₁₁Set to the switching point PS. Further, when the specified distance is between 200mm and 300mm, a point P at which the overlap section ends₉Set to the switching point PS.

As described above, even when there is no overlapping section (fig. 7), when the reference point PR and the switching point PS are provided outside the overlapping section (fig. 11 to 13), or when the reference point PR or the switching point PS is provided within the overlapping section (fig. 14 and 15), the switching point PS of the transfer motion setting timing switch can be matched by specifying the distance d to the reference point PR.

Fig. 16 is a flowchart showing the flow of processing of the setting section 28 and the signal output section 29. The setting unit 28 determines whether or not there is a setting input of the switching point PS (input of the designated distance d and the reference point PR as a starting point of the distance d) (step S10), and when there is the setting input (Y in step S10), sets a point on the trajectory TR whose distance from the reference point PR designated by the setting input is the distance d designated by the setting input as the switching point PS (step S11). In step S11, when an overlap section (a section in which the second-direction motion is started before the first-direction motion is terminated) is set between the reference point PR and the switching point PS, the setting section 28 sets, as the switching point PS, a point on the trajectory TR at which the distance from the reference point PR to the trajectory TR is the distance d when the overlap amount is 0%, sets, as the switching point PS, a point on the trajectory TR at which the distance from the reference point PR in the second direction is the distance d when the reference point PR is within the overlap section, and sets, as the switching point PS, a point on the trajectory TR at which the distance from the reference point PR in the first direction is the distance d when the switching point PS is within the overlap section.

Next, it is determined whether or not the transfer operation (transportation operation) has been started (step S12), and when the transfer operation has been started (Y in step S12), the signal output unit 29 acquires the current position of the transfer lever 11 (the position on the trajectory TR) based on a signal from the servo transfer control device 25 or the like (step S13). Next, the signal output unit 29 determines whether or not the transfer lever 11 has reached the switching point PS set in step S11 based on the acquired current position (step S14), and outputs a timing signal TS to the external device when the switching point PS is reached (Y in step S14) (step S15). Next, it is determined whether or not the shift operation has been stopped (step S16), and when the shift operation is continuing (N of step S16), the process proceeds to step S13, and when the shift operation has been stopped (Y of step S16), the process proceeds to step S10.

Although the embodiments of the present invention have been described in detail as above, those skilled in the art will readily appreciate that many modifications are possible without materially departing from the novel features and advantages of the present invention.

Description of the reference numerals

1. Servo press, 2 crankshaft, 3 crankshaft coder, 4 servo motor, 5 motor coder, 6 slide block, 7 upper mould, 8 lower mould, 9 main body, 10 servo transfer device (transfer feeder device), 11 transfer rod, 14 servo motor, 15 motor coder, 21 servo press control device, 22 servo amplifier, 25 servo transfer control device, 26 servo amplifier, 28 setting part, 29 signal output part, 30 transfer press operation control device, 34P press movement storage device, 34T transfer movement storage device, 36 operation part, 50 main phase signal generating output device, 60 independent phase signal generating output device.