JPS6062482A - Control system of safety speed of robot - Google Patents

Abstract

(57) [Summary] This bulletin contains application data before electronic filing, so abstract data is not recorded.

Description

DETAILED DESCRIPTION OF THE INVENTION BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a safe speed control method for an automatic machine, 1", that is, a U-bot, which performs certain operations, processing, and machining according to a program.

Since the robot operates automatically and moves its arm, etc. over a large distance, if a human approaches Robot 1~ while it is moving towards Robot 1~, the moving parts of Robot 1~ may cause injury. There is sex. Therefore, IF.

A dangerous area is set up around the robot, and in this dangerous area, robot 1 is prohibited from entering while it is in operation. However, when J3 was in the teaching mode, there was a problem that it would be dangerous if the robot 1~ overturned its operation at too high a speed.

Purpose of the Invention The present invention provides that in playback mode, no matter what the set speed 1111 is, when a specific signal is input, the speed is below a certain upper limit value! r! The purpose of this invention is to provide a safe speed control method for Shishida Robot I.

The present invention includes a switch for selecting the drive speed rank of the robot 1~, a recording IQ means for memorizing the specific drive speed rank, and a device for detecting the intrusion of foreign objects into the dangerous area of the robot 1~. If a foreign matter intrusion detection signal is not outputted from the inspection unit in the regeneration mode, the robot 1~ is driven at the drive speed rank set by the above switch, and when the detection signal is output, the above-mentioned This is a safe speed control system for a robot in which the drive speed rank set by the switch is compared with the drive speed rank stored in the storage means, and the robots 1 to 1 are driven at the smaller drive speed rank.

Embodiment FIG. 1 is a hardware block diagram of a control device according to an embodiment of the present invention.
2 is a ROM that stores a program for controlling the entire control device;
3 is a nonvolatile memory for storing a program for controlling the robot 1 for calculation processing, etc., and parameters for controlling the driving speed of the robot 1 to be described later; is a manual operator)j device, and the manual operator is
The teaching mode of the robot 1~ is set by the overwrite switch that sets the drive speed rank provided in 5.
715 The drive speed rank that falls in the first position) is certified. Furthermore, the manual input device 5 sets the parameters using the override switch, sets lζ(0), and stores them in the non-volatile memory 4. 6 is the output interface. 7 is an input interface circuit that receives signals from Renly, etc. installed on robots 1 to 1.

In particular, in the embodiment of the present invention, when a foreign object such as a person or object enters a dangerous area provided around the robot, a signal is emitted.
A signal is received from the detection means, for example, a limit switch provided on a safety fence surrounding the dangerous area. Note that 8 is a bus.

Next, the operation of this embodiment will be explained with reference to the operation flow shown in FIG. 2.

The non-volatile memory 4 has already stored the upper limit value of the override in the teaching mode and the reproduction mode.

Therefore, the operator of the robot 1 operates the override switch on the manual input device 5 to set the optimum value for driving the robot
J: The robot will be operated by setting the teaching mode and playback mode, but as shown in Figure 2, first
The PU 1 determines whether the teach mode is currently selected or whether the playback mode is the selection mode (step S1). If the teach mode is selected, the override value set by the override switch and the nonvolatile memory are stored in the PU 1. 4
Output the small force value (step S3, S4) of the parameter described in (1) (step S2), output the small force value (step S3, S4). If the speed is smaller than 1, set the override switch to avoid driving the robots 1 to 1 at the IC speed A-Parite drive J speed rank (step S3).
), if the set value of the override switch is larger than the parameter, the output of A-paralite is output at the set value of the parameter, and the robot is driven at that speed rank (step S4). This automatically determines the upper limit of the pull A-paraite in the teaching mode, and even if the override switch is set to a high speed in the teaching mode, dangerous speeds may occur during the teaching operation. The upper limit value is limited so that it does not occur.

Note that the speed I in the teaching mode (maximum speed 1) is about 1/2 that in the reproducing mode.

In addition, if it is the playback mode (step S1), the CPU
Step 1 is to determine whether there is a signal from the detection means installed in the dangerous area, that is, whether there is a person or object intruding into the dangerous area.Step S5): There is no intrusion and it is safe. If there is a signal (safety switch ON>), A-
The setting 10"■ (override output) set with the para-light switch is issued (step Se), and the robots 1 to 1 start operating at the finger γ speed rank. Also, the safety switch is set to O.
For FF, -! In other words, when a person-1b object enters the danger area and the safety switch is turned off, the CPU
1 compares the value set by the override switch with the value of the parameter stored in the nonvolatile memory 4 (step S7), and outputs the smaller override value (steps Se, Ss), that is, the override switch If the set value is smaller, the set value is used as is, and the robot is driven (step Se). However, if the parameter value is smaller than the override switch setting value, the parameter value is output and the robot is driven at a low speed. This prevents the robot from being driven at a dangerous speed that exceeds the override value set by the parameter when a person or object enters the dangerous area. As soon as the safety switch is activated, the robot 1 is driven to the 15 safety speed. .

Effects of the Invention As described above, the present invention prevents the L1 hot from being driven at a speed higher than the specific drive speed rank recorded in the IQ in the 10th means when a person or object enters the dangerous area of the robot 1. In addition, the robot 1~ will drive at the set drive speed rank when there are no people or objects entering the dangerous area, so the work will be done efficiently.

Also, in the teaching speed, even if the drive speed is set to a dangerously high speed rank for some reason, the robot 1 will not move above the specific drive speed rank stored in the storage device. , safe speed control of the robot 1 is performed even in the teaching mode.

[Brief explanation of drawings]

FIG. 1 is a hardware block diagram of a control device according to an embodiment of the present invention, and FIG. 2 is an operational flowchart of the embodiment. 1... Central processing unit, 2... Read only memory, 3... Random access memory, 8... Bus. Special engineering 'F applicant FANUC Co., Ltd.

Claims (3)

[Claims] (1) Switches for selecting the 15V dynamic speed ranks of robots 1 to 1 are regenerated by means for recording the specific drive speed ranks and detection means for detecting foreign objects entering into dangerous areas of the robot. In the mode, if the detecting means does not output a foreign object intrusion detection signal, the robot is driven at the drive speed rank set by the above switch, and when the detection signal is output, the robot is driven at the drive speed rank set by the switch and the A safe speed control method for a robot that compares two driving speed ranks stored in a storage means and avoids driving the robot using the smaller driving speed rank. (2) In the teaching mode, the drive speed rank set by the switch is compared with the drive speed rank stored in the storage means, and the robot is driven at the teaching speed of 1-4 using the smaller drive speed run. Safe speed control system for the robot 1 described in item 1. (3) The safe speed control system for the robot 1 according to claims 1 and 2, wherein the detection means is a switch installed on a safety fence.