JP2015000470A - Robot control apparatus and robot control method - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a robot control apparatus and a robot control method which perform emergency stop operation without damaging a robot including accessory devices such as a fingertip tool and an article being gripped by the robot while minimizing the safety distance to isolate an operator from the robot.SOLUTION: A robot control apparatus comprises: an emergency stop detection unit; a determination unit for determining whether or not a robot is capable of stopping within a robot stop time or whether or not the robot has entered a safety time stop area; and a stop mode setting unit for setting a deceleration stop mode, maximum speed control mode, or immediate stop mode. When an emergency stop is detected by the emergency stop detection unit, the deceleration stop mode, maximum speed control mode, or immediate stop mode is set by the robot control apparatus to stop the robot depending upon whether or not the robot is capable of stopping within the robot stop time or whether or not the robot has entered the safety time stop area.

Description

  The invention of the present application relates to a robot control apparatus and a robot control method for controlling an emergency stop operation of a robot.

  Up to now, industrial robots equipped with robot hands have been developed for production automation in factories.

  As a conventional technique for controlling a robot that performs a collaborative work with a worker, Patent Document 1 discloses that when the robot enters a collaborative operation area in which both the worker and the robot can enter, the operation speed of the robot. Is reduced to a low speed (250 mm / s or less) in accordance with ISO 10218-1, so that the worker can take an avoidance action when he is about to collide with the robot within the cooperative operation area, A production system is disclosed in which even if an operator collides with a robot, it is not necessary to receive a large impact.

JP 2010-188515 A

The following problems to be solved remain in conventional robot control devices.
Hereinafter, with reference to FIG. 1, the problem which the conventional robot control apparatus has is demonstrated. FIG. 1 is a schematic plan view showing the positional relationship among the worker 1, the robot 2, and the jig 3. The robot 2 is controlled so as to be able to move only in the movable area (dangerous area) 4. Here, an isolation surface 5 for separating the worker 1 and the robot 2 is set, and the distance between the movable region 4 and the isolation surface 5 is defined as a safety distance 6 (S). An area for limiting the operation speed of the robot 2 is referred to as an operation speed restriction area 7, and an area where the robot 2 can operate without being subjected to the speed restriction is referred to as an operation speed restriction release area 8. A boundary surface between the operation speed restriction area 7 and the operation speed restriction release area 8 is determined by a safety distance S obtained from the robot stop time in the deceleration stop mode.
Here, the safe distance S between the movable region 4 and the isolation surface 5 is determined by ISO 13855 and JIS B9715 by the following equation.

S = (K × T) + C ――― (1)

K is a parameter (2000 mm / s) defined by ISO extracted from data based on the approach speed of the worker 1 or a part (hand) of the worker 1, and T is a stop time required for the robot 2 to stop operating. (Unit: s), C is an additional distance (unit: mm) that accounts for the possibility of the operator 1 entering the movable region 4 before the light safety device 9 such as a safety sensor is activated. The additional distance C here takes into consideration the thickness width of the light of the optical sensor that the light-type safety device 9 irradiates along the isolation surface 5.

  Here, the safety distance S between the movable region 4 and the isolation surface 5 needs to be as short as possible in order to reduce the equipment size and increase the work efficiency of the worker 1. It is essential to reduce the time T. Reducing the stop time T in Equation 1 is to shorten the stop time T from the time when the robot 2 is operating until it stops, and reducing the stop time T increases the deceleration when the robot 2 is stopped. Thus, the impact load on the robot 2 when the robot 2 is stopped increases, which may cause mechanical / electrical damage and shorten the life of the robot 2. Furthermore, when a large deceleration is applied to the robot 2, there is a risk that an accessory device such as a product gripped or held by the robot 2 or a fingertip tool attached to the fingertip portion of the robot 2 may be damaged or dropped, and may jump out. is there.

The reason why the above problem occurs is that the minimum stop time T _min from the maximum speed of the robot 2 to the sudden stop is assumed as the stop time T in Equation 1 assuming that the robot 2 malfunctions due to a failure. .
Thus, if the minimum stop time T _min is used in any case when the robot 2 is in an emergency stop, the minimum stop time T _min is used when the robot 2 is in an emergency stop, for example, even if the operation speed of the robot 2 is slow. The minimum stop time T _min is used when the robot 2 is in an emergency stop even when 2 is located at a position far from the worker 1 as in the operation speed limit release region 8.
Under such circumstances, it is desired to further reduce the safety distance S. In particular, the stop time T of the robot 2 has not been studied. Conventionally, in any region, during an emergency stop, for example, The operation suddenly stops at the maximum deceleration of the robot 2 only by immediately cutting off the supply current to the motor driving the robot 2.

  The invention of the present application has been made in view of the circumstances as described above, and minimizes the safety distance for isolating the worker from the robot, and is held or held by the robot and the robot including ancillary devices such as fingertip tools. An object of the present invention is to provide a robot control apparatus and a robot control method capable of performing an emergency stop operation without damaging a product.

In order to solve the above-described problems, the invention according to claim 1 of the present application is directed to a safety distance between an isolation surface separating a worker and a robot and a movable region of the robot, The robot stop time required for stopping without exceeding the safe distance, the operation speed limit area for limiting the operation speed of the robot, or the operation speed limit at which the robot can operate without speed limitation. A release area and a safety time stop area where the robot stops in a time not exceeding the safety distance or an apparatus protection time stop area where the robot stops to protect ancillary devices such as a fingertip tool are set. The robot control device includes an emergency stop detection unit that stops the operation of the robot that needs to be stopped, and the robot. A determination unit for determining whether or not the robot can be stopped without exceeding the stop time of the robot, or whether or not the robot has entered the safe time stop region, a deceleration stop mode of the robot, and a maximum speed of the robot A maximum speed control mode for stopping the robot with a limit to a stop mode, or a stop mode setting unit for setting an immediate stop mode, and when an emergency stop is detected by the emergency stop detection unit, When the determination unit determines that the robot can stop within the robot stop time, the deceleration mode is set by the stop mode setting unit, and the robot is within the robot stop time. If it is determined that the vehicle cannot be stopped, the maximum speed control mode is set in the stop mode setting unit, or When the emergency stop is detected by the normal stop detection unit, if the determination unit determines that the robot has entered the safe time stop region, the stop mode setting unit performs the immediate stop. A mode is set, and when it is determined that the robot has not entered the safe time stop region, the deceleration stop mode is set by the stop mode setting unit.
According to the invention relating to the robot control device of claim 1 of the present application, the robot operation speed is variably limited (decelerated) so that the robot keeps a safe distance, and the robot is stopped from being operated until it is stopped. Because the time can be changed, the robot can be stopped with a slow decelerating acceleration within the robot stop time required for the robot to keep a safe distance, or the robot can enter the safe time stop area. The robot stop time can be changed by selecting the deceleration stop mode or the immediate stop mode alternatively depending on whether the robot is in motion or not. Without exceeding, the robot can be brought to an emergency stop with a slow deceleration.

In order to solve the above-described problem, an invention according to a robot control method of claim 2 of the present application is directed to a safety distance between an isolation surface that separates a worker and a robot and a movable region of the robot, The robot stop time required for stopping without exceeding the safe distance, the operation speed limit area for limiting the operation speed of the robot, or the operation speed limit at which the robot can operate without speed limitation. A release area and a safety time stop area where the robot stops in a time not exceeding the safety distance or an apparatus protection time stop area where the robot stops to protect ancillary devices such as a fingertip tool are set. A robot control method for controlling a robot, wherein the robot control method detects whether it is necessary to emergency stop the operation of the robot. And determining whether the robot can stop without exceeding the robot stop time, or whether the robot has entered the safe time stop area, and detecting When a stop is detected, if it is determined in the determining step that the robot can stop within the robot stop time, a deceleration stop mode is set, and the robot stops the robot If it is determined that the robot cannot be stopped in time, the maximum speed control mode for stopping the robot is set by limiting the maximum speed of the robot, or an emergency stop is detected in the detecting step. When it is determined that the robot has entered the safe time stop area, the immediate stop mode is Set, if the robot determines that it is not penetrated into the safety time stop region is characterized by having a step of setting the deceleration stop mode.
According to the invention related to the robot control method of claim 2 of the present application, similarly to the invention related to the robot control apparatus of claim 1 of the present application, it is determined whether the robot can be stopped without exceeding the robot stop time. The robot can be emergency stopped with a slow deceleration without exceeding the robot stop time, or it can be judged whether the robot has entered the safe time stop area, and the deceleration stop mode or immediate stop mode By selecting, the robot can be brought to an emergency stop with a slow or rapid acceleration without exceeding the robot stop time.

(Mode of Invention)
Hereinafter, embodiments of the invention that is recognized as being capable of being claimed in the present application (hereinafter referred to as claimable invention) will be exemplified and each exemplified embodiment will be described. Here, as in the claims, each aspect is divided into paragraphs, numbers are assigned to the respective paragraphs, and the descriptions of other paragraphs are cited as necessary. This is for the purpose of facilitating the understanding of the claimable invention, and is not intended to limit the combination of the constituent elements constituting the claimable invention to those described in the following sections. In other words, the claimable invention should be construed in consideration of the description accompanying each section, the description of the embodiment, etc., and as long as the interpretation is followed, another aspect is added to the aspect of each section. Moreover, the aspect which deleted the component from the aspect of each term can also be one aspect of the claimable invention.
The invention of the present application is configured in the following aspects (1) to (6). The aspects of the items (1) and (4) correspond to the first and second aspects.

(1) a safe distance between an isolation surface that separates a worker and a robot and a movable region of the robot, and a robot stop time required for the robot to stop without exceeding the safe distance; An operation speed limit area that limits the operation speed of the robot, or an operation speed limit release area in which the robot can operate without being subjected to a speed limit, and a safety time stop in which the robot stops in a time that does not exceed the safety distance. And a device protection time stop region for stopping to protect an auxiliary device such as a fingertip tool, respectively, and the robot control device needs to make an emergency stop An emergency stop detector for stopping the robot operation, whether the robot can stop without exceeding the robot stop time, and A determination unit for determining whether or not the robot has entered a safe time stop area, and a deceleration stop mode of the robot, a maximum speed control mode for stopping the robot by limiting the maximum speed of the robot, or A stop mode setting unit that sets an immediate stop mode, and when the emergency stop is detected by the emergency stop detection unit, the determination unit may stop the robot within the robot stop time. When it is determined that it is possible, the deceleration mode is set by the stop mode setting unit, and when it is determined that the robot cannot be stopped within the robot stop time, the stop mode is set. The maximum speed control mode is set by the control unit or when the emergency stop is detected by the emergency stop detection unit, the determination unit Is determined to have entered the safe time stop area, the immediate stop mode is set by the stop mode setting unit, and the robot has not entered the safe time stop area. If the determination is made, the deceleration control mode is set by the stop mode setting unit. (Corresponding to claim 1).
According to the robot control device of item (1), the maximum operation speed of the robot can be variably limited (decelerated), and the stop time from the operation of the robot to the stop can be shortened. It is possible to make an emergency stop with a slow decelerating acceleration without exceeding the robot stop time required for stopping without exceeding the distance.
Also, the robot position is constantly monitored, and the stop mode is switched to either immediate stop or deceleration stop depending on the area where the robot is located when emergency stop is input, and the robot can be operated without exceeding the robot stop time. An emergency stop is also possible.

(2) When the determination unit determines that the robot cannot stop without exceeding the robot stop time, the maximum speed of the robot is limited to a speed at which the robot can stop within the robot stop time. The robot control device according to item (1), characterized in that:
According to the robot control device of item (2), when the determination unit determines that the robot cannot stop without exceeding the robot stop time, the robot is controlled by limiting the maximum speed of the robot. The emergency stop can be performed with a slow deceleration without exceeding the robot stop time.

(3) When the determination unit determines whether or not the robot has entered the safe time stop region, the operation speed of the robot can be limited by a teaching speed. The robot control device according to item (1).
According to the robot control device of item (3), even when the robot stops immediately, the robot can be stopped immediately with a relatively small deceleration, and is held or held by the robot mechanism and the robot. Damage to the product can be suppressed.

  (4) a safe distance between an isolation surface that separates a worker and a robot and a movable region of the robot, and a robot stop time required for the robot to stop without exceeding the safe distance; An operation speed limit area that limits the operation speed of the robot, or an operation speed limit release area in which the robot can operate without being subjected to a speed limit, and a safety time stop in which the robot stops in a time that does not exceed the safety distance. A robot control method for controlling a robot in which a region or a device protection time stop region for stopping an accessory device such as a fingertip tool is set, and the robot control method includes: Detecting whether it is necessary to make an emergency stop, and stopping the robot without exceeding the robot stop time. And determining whether an emergency stop is detected in the detecting step, the robot determines that the robot When it is determined that the robot can stop within the stop time, a deceleration stop mode is set, and when it is determined that the robot cannot stop within the robot stop time, the robot The maximum speed control mode for stopping the robot by setting the maximum speed is set, or when an emergency stop is detected in the detecting step, the robot enters the safe time stop area. If it is determined that the robot is in an immediate stop mode, it is determined that the robot has not entered the safe time stop area. If was boss, the robot control method characterized by comprising the steps of: setting the deceleration stop mode. (Corresponding to claim 2).

  (5) When the determination unit determines that the robot cannot stop without exceeding the robot stop time, the maximum speed of the robot can be stopped without exceeding the robot time. The robot control method according to item (4), further including a step limited to:

  (6) When the determination unit determines whether or not the robot has entered the safe time stop region, the operation speed of the robot can be limited by a teaching speed. The robot control method according to item (4).

  And since the robot control method as described in said (4) to (6) item can be implemented by the robot control apparatus as described in said (1) to (3) item, said (1) To (3), the same operation and effect as the robot control device described in the item (3) can be obtained.

According to the invention related to the robot control device of the first aspect, since the stop time of the robot can be minimized, the safety distance for isolating the worker from the robot is minimized, and an auxiliary device such as a fingertip tool is included. The emergency stop operation can be performed with a slow decelerating acceleration that does not damage the robot and the product held or held by the robot.
According to the invention related to the robot control method of the second aspect, since the stop time of the robot can be minimized, the safety distance for isolating the worker and the robot is minimized, and an auxiliary device such as a fingertip tool is included. It is possible to provide a robot control method capable of performing an emergency stop operation with a slow deceleration without damaging the robot and a product held or held by the robot.
In the invention according to the robot control device according to claim 1 and the robot control method according to claim 2, when the deceleration stop mode and the maximum speed control mode are used, the robot including the accessory device and the product held or held by the robot are protected. However, when the immediate stop mode is used, the robot and the product including the incidental device cannot be protected. In this case, in order to give up protecting the robot or product including the auxiliary device, or to protect the robot or product including the auxiliary device, the immediate stop mode can be used after the teaching speed of the robot is reduced. .

FIG. 1 is a schematic plan view showing the positional relationship among workers, robots, and jigs. FIG. 2 is a block diagram of the robot control apparatus according to the present invention. FIG. 3 is a flowchart showing a control processing flow in the robot control method according to the first embodiment of the present invention. FIG. 4 is a diagram illustrating operation characteristics at the time of emergency stop of the robot in the robot control method according to the first embodiment of the present invention. FIG. 5 is a flowchart showing a control processing flow in the robot control method according to the second embodiment of the present invention. FIG. 6 is a diagram illustrating operation characteristics at the time of emergency stop of the robot in the robot control method according to the second embodiment of the present invention.

  DESCRIPTION OF THE PREFERRED EMBODIMENTS Preferred embodiments of the present invention will be described below with reference to the accompanying drawings. However, the apparatus described below and its components, components, parts, and materials are the same as those of the present invention. It is an example of an embodiment and is not limited to this. Moreover, in the figure, the part which attached | subjected the same code | symbol represents the same thing and the same member, and each dimension and each ratio of an apparatus or a member are not what reflected the actual thing but shown schematically.

A robot control apparatus according to the present invention will be described with reference to FIG.
Whether the robot controller 10 can stop the emergency stop detection unit 11 such as an emergency stop button that the worker 1 presses to make the robot 2 emergency stop or the robot 2 can be stopped without exceeding the safety distance 6 (S). Or a determination unit 12 that determines whether or not the robot 2 has entered the safe time stop region 27 (see FIG. 6), and a stop mode that sets a stop mode of deceleration stop, maximum speed control, or immediate stop A setting unit 13 is provided.
The robot control apparatus 10 includes, for example, a CPU (Central Processing Unit) that performs control processing, arithmetic processing, and the like, a ROM (Read Only Memory) that stores control programs and arithmetic programs executed by the CPU, and processing. The hardware is composed mainly of a microcomputer having a RAM (Random Access Memory) that temporarily stores data and the like. The plurality of CPUs, ROMs, and RAMs are connected to each other by a data bus.

  FIG. 2 shows a robot control apparatus 10 that can control the emergency stop operation of the robot 2. The robot control apparatus 10 has a main CPU 14 that executes a control program, a servo control CPU 15, and safety functions of the robot 2. Functional safety control CPU 16 to be controlled, contactor 17, servo amplifier 18, motor 19 that rotates and moves robot 2, encoder 20 that measures the joint angle value of robot 2 in order to calculate the current position of robot 2, and power, A main CPU 14, a servo control CPU 15, a functional safety control CPU 16, and a power supply 21 that supplies power to the contactor 17 are included. The robot controller 10 constantly monitors the position and operating speed of the robot 2 and limits the maximum operating speed of the robot 2 if necessary so that the robot 2 stops without exceeding the safety distance S when an emergency stop occurs. Alternatively, when the robot 2 enters the safe time stop area 27 (see FIG. 6), the emergency stop operation of the robot 2 is controlled by stopping the robot 2 immediately.

  Here, the main CPU 14 issues a position command to the servo control CPU 15 and a power cutoff command to the contactor 17. The servo control CPU 15 transmits the current position of the robot 2 to the main CPU 14 and receives the position command from the main CPU 14. Then, a current command and a power shutoff instruction are transmitted to the servo amplifier 18 and the contactor 17. The functional safety control CPU 16 executes a calculation program and transmits the current position calculation of the robot 2, a maximum speed limit instruction (the speed limit in this limit function is variable), and a power cutoff instruction to the servo control CPU 15 and the contactor 17. . The contactor 17 receives a power cutoff instruction from the three CPUs 14, 15, 16 and opens / closes (releases / shuts off) the power to the motor 19, and the servo amplifier 18 receives a current command from the servo control CPU 15, and receives the motor command. A current for driving 19 is supplied.

As shown in FIG. 2, the functional safety control CPU 16 of the robot controller 10 determines the current position of the robot 2 calculated by forward kinematics using the joint angle measurement value of the robot 2 from the encoder 20. Current position determination means 22 is provided. Here, as a means for determining the current position of the robot 2, a position command from the main CPU 14 can be used instead of a calculated value by forward kinematics using the joint angle of the encoder 20.
Furthermore, the functional safety control CPU 16 should set in advance a stop distance required from the time when the robot 2 is operating to an emergency stop, and monitor the robot 2 from the current position of the robot 2 and the set stop distance. A stop distance / monitoring area setting means 23 for setting the area is provided.

Further, the functional safety control CPU 16 predicts whether or not the robot 2 can make an emergency stop at the set emergency stop distance based on the emergency stop distance set in advance by the user in the stop distance / monitoring area setting means 23. At the same time, the stop time / distance predicting means 24 for predicting the stop time required for the robot 2 from operating to the emergency stop based on the current position of the robot 2 determined by the current position determining means 22 and the operation speed of the robot 2. It has.
The functional safety control CPU 16 further restricts the maximum operation speed of the robot 2 or sets the stop mode for deceleration stop, maximum speed control, or immediate stop when the robot 2 is in an emergency stop. Setting means 25 is provided.

  Further, the functional safety control CPU 16 protects the stop time at the time of emergency stop of the robot 2 with respect to ancillary devices such as fingertip tools and products gripped or held by the robot and prevents the robot 2 from being mechanically damaged. , Continuously changing to an arbitrary deceleration stop speed, decelerating and stopping the robot 2, or limiting the maximum operation speed of the robot 2, or protecting the incidental device, the product, and the mechanism of the robot 2 Means for immediately stopping the robot 2 without considering the above, in other words, when the robot 2 is in an emergency stop, the robot 2 when the robot 2 is decelerated to stop, the maximum speed is limited, or is immediately stopped without exceeding the safety distance S. The stop time adjusting means 26 for adjusting the stop time is provided. The functional safety control CPU 16 needs to acquire third party authentication when using the stop time adjusting means 26.

Here, the determination unit 12 of the robot control apparatus 10 includes a current position determination unit 22, a stop distance / monitor area setting unit 23, and a stop time / distance prediction unit 24.
The determination unit 12 uses the stop time / distance predicting unit 24 to predict the stop time and stop distance required until the robot 2 is in operation until the emergency stop, and the current position determining unit 22 and the stop distance / distance By using the monitoring area setting means 23, it is possible to assume the area in which the robot 2 exists when the robot 2 is stopped in an emergency, and the robot 2 can make an emergency stop without exceeding the safety distance S. Whether it can be determined.
Further, the current position determination means 22 can determine whether the robot 2 has entered the safe time stop area 27.
Still further, the stop mode setting unit 13 of the robot control device 10 includes an operation speed limit / stop mode setting means 25. By using the operation speed limit / stop mode setting means 25, the robot 2 is decelerated and stopped when the robot 2 is in an emergency stop. A stop mode of either maximum speed control or immediate stop can be set (selected), and the maximum operation speed of the robot 2 can be limited (decelerated).

  By appropriately using these means in necessary control processing steps, the robot control apparatus 10 according to the present invention uses the stop time T (see Formula 1) of the robot 2 while preventing the robot 2 from stopping due to a large deceleration. Can be shortened. Therefore, the robot control apparatus 10 according to the present invention shortens the safety distance S (see Formula 1 and FIGS. 1, 4 and 6) between the isolation surface 5 and the operation speed limit area 7 or the safety time stop area 27. Therefore, the equipment size can be reduced and the working flow of the robot 2 can be shortened. In addition, the mechanism portion of the robot 2 can be appropriately protected without reducing the cycle time. Further, the acceleration / deceleration load is not applied to the auxiliary device such as a product gripped or held by the robot 2 or a fingertip tool attached to the fingertip portion of the robot 2, so that the emergency stop of the robot 2 occurs. The product or fingertip tool can be prevented from being damaged or dropped, and the product can be prevented from popping out.

  With reference to FIG. 3, the robot control method according to the first embodiment of the present invention will be described. By using the control method 100 of the robot 2 according to the first embodiment of the present invention, the robot 2 does not exceed the safe distance S without damaging the robot 2 including the accessory device and the product held or held. The robot 2 can be brought to an emergency stop at the fastest speed.

The robot control method 100 according to the present invention is started in step S102. In step S102, the stop time / distance predicting means 24 of the functional safety control CPU 16 calculates and predicts the stop time and stop distance required until the robot 2 stops from the current operating speed of the robot 2. The functional safety control CPU 16 ends this calculation process and stores the calculation result in the RAM.
After that, based on the above calculation result, the functional safety control CPU 16 can determine whether the determination unit 12 can stop the robot 2 within the robot stop time required to stop the robot 2 without exceeding the safety distance S. Determine if. When the determination result of the determination unit 12 is “yes”, the process proceeds to the next step S104, and when the determination result of the determination unit 12 is “no”, the process proceeds to step S106.
In step S <b> 104, the main CPU 14 determines whether or not an input is made to the emergency stop detection unit 11. If it is determined by the main CPU 14 that the emergency stop has been input to the emergency stop detection unit 11 (“yes” in step S104), the process proceeds to step S108, the deceleration mode is set by the stop mode setting unit 13, and the robot 2 Decelerates and stops at a slow decelerating speed that does not damage the robot including the device and the product held or held. If the main CPU 14 determines that no input is made to the emergency stop detection unit 11 (“no” in step S104), the process proceeds to step S110.

  In step S110, the functional safety control CPU 16 determines whether or not the next step in an arbitrary cycle time (sampling time) has been reached. When it is determined by the functional safety control CPU 16 that the next step has been reached (“yes” in step S110), the process proceeds to step S112, the movement to the next step is started, and then the process returns to step S102. A loop (see FIG. 3) is formed. When the functional safety control CPU 16 determines that the next step has not yet been reached (“no” in step S110), another loop (see FIG. 3) is returned to step S102 as it is.

If it is determined in step S102 that the robot 2 cannot stop within the robot stop time ("no" in step S102) and the process proceeds to step S106, the stop mode setting unit 13 is set in step S106. Is set to the maximum speed control mode, and the functional safety control CPU 16 limits (decelerates) the maximum speed of the robot 2 by the operation speed limit / stop mode setting means 25 so that the robot 2 stops within the robot stop time. .
Thereafter, the process proceeds to step S114. In step S114, the main CPU 14 determines whether or not an input is made to the emergency stop detection unit 11. When the main CPU 14 determines that an input has been made to the emergency stop detection unit 11 (“yes” in step S114), the process proceeds to step S116, where the robot 2 is immediately stopped. In step S106, the robot 2 is stopped. Since the maximum speed of the robot is limited so as to limit (decelerate) the maximum speed of the robot 2 so that it stops in time, the robot 2 damages the robot including the accessory device and the product held or held. It is possible to stop immediately with a slow deceleration that does not give
In step S114, when it is determined by the main CPU 14 that no input has been made to the emergency stop detection unit 11 (“no” in step S114), the process is merged to step S110, and the process of step S110 is performed. Then, the process proceeds to step S112, and then returns to step S102 or forms two loops that return to step S102 as they are (see FIG. 3).

With reference to FIG. 4, characteristics of the emergency stop operation of the robot 2 in the robot control method 100 according to the first embodiment of the present invention will be described. By using this control method 100, when an emergency stop is input, if the robot 2 exists in the operation speed limit release area 8, the maximum speed of the robot 2 is not decelerated and stopped as it is ( (Deceleration stop mode), if the robot 2 is in the operation speed limit area 7, the maximum speed of the robot 2 is immediately stopped after being limited by linear linear function or step function (maximum speed control mode) . By applying the maximum speed control mode, the robot 2 variably limits (decelerates) the maximum operation speed of the robot 2 as it approaches the vertical axis surface of the origin in FIG. Accordingly, the stop time of the robot 2 can be shortened in a linear linear function or step function in the motion speed limit region 7, so that the safety distance S can be minimized (S _min ). Further, in both the deceleration stop mode and the maximum speed control mode, the robot 2 can stop at the maximum speed without damaging the robot 2 including the accessory device and the product held or held without _exceeding the safety distance _Smin. it can.
Here, since the actual speed limit of the robot 2 is set below the maximum speed, there is no influence on the cycle time.

A robot control method 200 according to a second embodiment of the present invention will be described with reference to FIG. In this embodiment, the movable region 4 of the robot 2 includes the safe time stop region 27 where the robot 2 immediately stops in a time not _{exceeding the} safe distance S _min ′, and the robot 2 including an accessory device such as a fingertip tool or the grasping or holding It is divided into a device protection time stop region 28 for decelerating and stopping so as to protect the product (see FIG. 6). The boundary surface between the safe time stop region 27 and the device protection time stop region 28 is the same as the boundary surface between the operation speed limit region 7 and the operation speed limit release region 8, and the robot stops in the deceleration stop mode. It is determined by the safety distance S obtained from time.
By using the robot control method 200 according to the second embodiment of the present invention, the position of the robot 2 is constantly monitored, and the position of the robot 2 when an emergency stop input is made enters the safe time stop area 27. Depending on whether or not, the stop mode is switched to either immediate stop or deceleration stop, and the robot 2 makes an emergency stop without exceeding the safe distance S _min '. Here, when the deceleration stop mode is used, it is possible to protect the robot 2 including the accessory device and the product held or held, but when the immediate stop mode is used, the robot 2 or product including the accessory device is protected. It cannot be protected. In this case, it is used after giving up protecting the robot 2 or the product or by reducing the teaching speed of the robot in order to protect the robot 2 or the product.

The robot control method 200 according to the second embodiment of the present invention is started in step S202. In step S <b> 202, the current position determination unit 22 of the functional safety control CPU 16 determines whether the robot 2 has entered the safe time stop area 27 from the current position of the robot 2.
If the functional safety control CPU 16 determines that the robot 2 has entered the safe time stop area 27 (“yes” in step S202), the process proceeds to step S204, where it is determined that the robot 2 has not entered (step S202). If “no” in S202), the process proceeds to step S206.

  In step S206, the main CPU 14 determines whether or not an input is made to the emergency stop detection unit 11. When it is determined by the main CPU 14 that the emergency stop has been input to the emergency stop detection unit 11 (“yes” in step S206), the process proceeds to step S208, and the functional safety control CPU 16 sets the deceleration stop mode by the stop mode setting unit 13. The robot 2 decelerates to a stop with a slow decelerating acceleration that can protect the robot 2 including the accessory device and the product held or held. If the main CPU 14 determines that no input is made to the emergency stop detector 11 (“no” in step S206), the process proceeds to step S210.

  In step S210, the functional safety control CPU 16 determines whether or not the next step in an arbitrary cycle time (sampling time) has been reached. If it is determined by the functional safety control CPU 16 that the next step has been reached (“yes” in step S210), the process proceeds to step S212, the movement to the next step is started, and then the process returns to step S202. A loop (see FIG. 5) is formed. If the functional safety control CPU 16 determines that the next step has not yet been reached (“no” in step S210), another loop (see FIG. 5) is returned to step S202.

If it is determined in step S202 that the robot 2 has entered the safe time stop area 27 (“yes” in step S202) and the process proceeds to step S204, the main CPU 14 determines that an emergency has occurred as in step S206. It is determined whether or not an input has been made to the stop detection unit 11. When it is determined that the main CPU 14 has input to the emergency stop detection unit 11 (“yes” in step S204), the process proceeds to step S214, and the functional safety control CPU 16 sets the immediate stop mode by the stop mode setting unit 13. Then, the robot 2 is immediately stopped. In this immediate stop mode, the robot 2 and the product including the incidental device cannot be protected. Therefore, this immediate stop mode is used after giving up protecting the robot 2 and the product, or when the robot 2 has entered the safe time stop area 27 in order to protect the robot 2 and the product. In addition, it is used after the teaching speed of the robot 2 is arbitrarily reduced. If the teaching speed of the robot 2 is reduced in the safe time stop area 27, even if the robot 2 stops immediately, the robot 2 can stop with a relatively small deceleration, and the mechanism and product of the robot 2 can be moved to. Damage can be suppressed.
In step S204, if it is determined by the main CPU 14 that no input has been made to the emergency stop detection unit 11 (“no” in step S204), the process is merged to step S210, and the process of step S210 is performed. Then, the process proceeds to step S212 and then returns to step S202 or forms two loops that return to step S202 as they are (see FIG. 5).

With reference to FIG. 6, the characteristics of the emergency stop operation of the robot 2 in the robot control method 200 according to the second embodiment of the present invention will be described. When the robot control method 100 according to the first embodiment is used, the robot 2 can reduce the safe distance S _min by limiting (decelerating) the operation maximum speed of the robot 2 variably or stepwise as necessary. The robot 2 can be brought to an emergency stop with a slow decelerating acceleration that can protect the robot 2 including the accessory device and the product held or held by the robot 2 without exceeding. On the other hand, when the robot control method 200 according to the second embodiment is used, the robot 2 stops time without limiting the maximum speed of the robot 2, and the robot 2 determines the safe time stop area 27 and the device protection time. By selectively switching to either the immediate stop mode or the deceleration stop mode depending on which of the stop regions 28 exists, the robot 2 does not exceed the safe distance S _min '. The robot 2 is brought to an emergency stop.

By using this control method 200, when an emergency stop input is made, if the robot 2 exists in the device protection time stop area 28, the robot 2 is decelerated and stopped as it is (deceleration stop mode), and the robot 2 is safe. If it exists in the time stop area 27, the stop time of the robot 2 is shortened in a step function and immediately stopped (immediate stop mode). With these two stop modes, the robot 2 switches the stop time depending on whether the robot 2 exists in the safe time stop region 27 or the device protection time stop region 28. The robot 2 can be brought to an emergency stop without exceeding S _min '. In the safe time stop area 27, the robot 2 can be shortened for a shorter stop time without limiting the speed of the robot 2. Therefore, the safe distance S can be set to a shorter safe distance (S _min '). .

  In the robot control method 200 according to the second embodiment of the present invention, when the robot 2 is decelerated and stopped (step S208), the robot 2 can be stopped with a slow decelerating force. The product held or held by can be protected. On the other hand, when the robot 2 is immediately stopped (step S214), there is a possibility that strong deceleration is generated in the robot 2. However, if the teaching speed of the robot 2 is reduced in the safe time stop region 27, for example. Even when the robot 2 is stopped immediately, the robot 2 can be stopped with a relatively small deceleration, and damage to the mechanism unit of the robot 2 and the product held or held by the robot 2 can be suppressed. However, when the robot 2 malfunctions and the robot 2 is operating at the maximum speed, if the robot 2 is immediately stopped, a large deceleration is applied to the robot 2, and the mechanism part of the robot 2 or the robot 2 grips it. Or the held product may be damaged.

  The present invention can be suitably applied to such a system as long as it is necessary to have an emergency stop function.

1 ... worker, 2 ... robot, 3 ... jig, 5 ... isolation surface, 6 ... safety distance,
7 ... Operation speed limit area, 8 ... Operation speed limit release area, 9 ... Light beam safety device,
10 ... Robot control device, 11 ... Emergency stop detection unit, 12 ... Determination unit,
13 ... Stop mode setting section, 27 ... Safe time stop area,
28 ... Device protection time stop area, 100, 200 ... Robot control method

Claims (2)

A safety distance between an isolation surface separating a worker and a robot and a movable area of the robot, a robot stop time required for the robot to stop without exceeding the safety distance, An operation speed limit region for limiting the operation speed, an operation speed limit release region in which the robot can operate without being subjected to a speed limit, and a safe time stop region in which the robot stops in a time not exceeding the safety distance, or And a device control time stop region for stopping the auxiliary device such as a fingertip tool, respectively, and the robot control device,
An emergency stop detector that stops the operation of the robot that needs to be stopped;
A determination unit that determines whether the robot can stop without exceeding the robot stop time, or whether the robot has entered the safe time stop region;
A deceleration stop mode of the robot, a maximum speed control mode for stopping the robot by limiting the maximum speed of the robot, or a stop mode setting unit for setting an immediate stop mode,
When the emergency stop is detected by the emergency stop detection unit, when the determination unit determines that the robot can stop within the robot stop time, the stop mode setting unit When the deceleration stop mode is set and it is determined that the robot cannot stop within the robot stop time, the maximum speed control mode is set by the stop mode setting unit, or
When the emergency stop is detected by the emergency stop detection unit, if the determination unit determines that the robot has entered the safe time stop region, the stop mode setting unit performs the immediate A robot control apparatus, wherein a stop mode is set and the deceleration stop mode is set by the stop mode setting unit when it is determined that the robot has not entered the safe time stop region. A safety distance between an isolation surface separating a worker and a robot and a movable area of the robot, a robot stop time required for the robot to stop without exceeding the safety distance, An operation speed limit region for limiting the operation speed, an operation speed limit release region in which the robot can operate without being subjected to a speed limit, and a safe time stop region in which the robot stops in a time not exceeding the safety distance, or , A robot control method for controlling a robot in which a device protection time stop region for stopping to protect an auxiliary device such as a fingertip tool is set, and the robot control method includes:
Detecting whether it is necessary to emergency stop the operation of the robot;
Determining whether the robot can stop without exceeding the robot stop time or whether the robot has entered a safe time stop area; and
When an emergency stop is detected in the detecting step, if it is determined in the determining step that the robot can stop within the robot stop time, a deceleration stop mode is set, When it is determined that the robot cannot stop within the robot stop time, a maximum speed control mode for stopping the robot by limiting the maximum speed of the robot is set, or
When it is determined that the robot has entered the safe time stop area when an emergency stop is detected in the detecting step, the immediate stop mode is set, and the robot And a step of setting the deceleration stop mode when it is determined that the vehicle has not entered the stop area.

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