KR20150062097A - Safety operating system for take-out robot - Google Patents

Abstract

The present invention provides a safety operating system for a takeout robot, which may prevent various kinds of accidents that may sporadically occur while a takeout robot takes out and carries a projected object. The safety operating system for a takeout robot comprises: an impact detector which detects an impact exerted when a takeout robot hits an object during an operation and transmits an impact detection signal to a control module of the takeout robot; and a control module which controls the takeout robot to temporarily stop or move backward in a predetermined distance promptly after receiving the impact detection signal. Moreover, the safety operating system for a takeout robot may comprise a control module controlling the takeout robot to stop during a predetermined time period when a human is detected by a human sensing sensor, which is mounted on the takeout robot, within a predetermined distance on the movement path of the takeout robot.

Description

{SAFETY OPERATING SYSTEM FOR TAKE-OUT ROBOT}

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a safe operation system capable of preventing a collision accident or the like that may occur during operation of a take-out robot.

The demand for robots that take out the injection molds has been greatly increased along with industrial development. Since many products are manufactured through a mold, the take-out robot that takes out the mold from the mold and carries it to the conveyor belt is arranged for each injection machine to perform the work. In many workplaces, a plurality of injection machines are disposed, and accordingly, a plurality of take-out robots are arranged to carry out the injection material transportation work. Naturally, in order to increase the space utilization of the workplace, the injection machine, the take-out robot, and the conveyor belt are arranged, and the workers work together by hand among such equipment. The operation of the take-out robot is controlled by the control module. When the operation program module corresponding to the operation is initially inputted, the take-out robot repeats the operation according to the operation and takes out and transports the work.

The problem is that take-out and hauling operations do not always proceed as expected. Even though the same operation is repeated, an unexpected situation may occur in which the injection molding or the robot arm impacts on the mold, other objects around the object, or even a person who is working. Occasionally, a collision may occur during operation of a controller that manually controls the operation of the take-out robot, due to inactivity or manipulation errors.

In the case where the take-out robot arm impacts a mold or other objects, when the injection object is sucked and transported, the injection object is damaged and defective, causing damage or failure of the take-out robot, . It is a matter of course that a risk of personal injury is generated when an operator is shocked by the take-out robot.

In spite of the above-mentioned problems, there has not been disclosed a take-out robot operating system which can prepare for such a safety accident as the operation system of the take-out robot which has been used yet.

On the other hand, when the injection condition of the injection machine is different from the injection condition of the injection machine, the injection condition of the injection machine must be matched with the injection condition of the injection machine. If the injection condition is set for different injection conditions , Leading to an accident. Therefore, a safety system that can prevent such accidents is required.

In addition, defects in the shape of an injection molded article taken out of a mold, missing nuts and inserts can not be found at the present taking out stage at all, but are later selected as defective, and the defect rate is very high. Therefore, such a problem also needs a management system that can be selected at the extraction stage and quickly corrected.

Korean Patent No. 10-0791957 discloses a method for safely transporting an injection object of a take-out robot, but a sensor for detecting whether or not the injection object is surely attracted to the robot arm rotation portion is provided, And can not solve the above problems.

SUMMARY OF THE INVENTION It is therefore an object of the present invention to provide a safe operation system of a take-out robot that can prevent various safety accidents and failures that may occur unexpectedly in the process of taking out and transporting an injection article.

According to the above-mentioned object, the present invention provides an impact detection system comprising: a shock detection sensor for detecting a shock of a bodily object during operation of the take-out robot and transmitting a signal to a control module of the take-out robot; And

And a control module for temporarily stopping the movement of the robot immediately after receiving the impact detection signal from the control unit of the takeout robot or stopping the robot after a predetermined amount of movement.

According to another aspect of the present invention, there is provided a robot control system comprising a control module for mounting a human body sensor on a take-out robot and controlling movement of the take-out robot for a predetermined time immediately when a human body is detected within a predetermined distance in a movement path of the take- And provides a safe operation system of the take-out robot.

Further, in the present invention, the impact sensor is a server motor included in the take-out robot, and a change in the current value of the server motor is detected by the take-out robot control unit .

In addition, the present invention can provide a safety operation system for a take-out robot, wherein the human body detection sensor communicates with the take-out robot control unit via IoT (Internet to Things).

The present invention also relates to an RFID tag attached to each die;

A server in communication with the RFID tag; And

And a take-out robot having a control module capable of taking out an injection product from a mold and communicable with the take-

In the RFID, unique identification information for each mold is planted, identification information is transmitted to the server,

The server uploads the injection information according to the mold identification number and the operation information of the takeout robot assigned to the mold to the control unit of the injection machine and the control unit of the takeout robot so that the injection information of the injection machine and the operation information of the take- And a safety operation system for the take-out robot is provided which prevents an accident that occurs due to matching.

Further, according to the present invention,

A camera module installed at a robot arm end of the takeout robot; And

And a display device for receiving and displaying image information from the camera module,

And an image of an injection object or an internal image of the injection mold is observed from the display to detect a defect in the injection molding or the presence of foreign matter in the mold.

The safety operation system of the take-out robot may further include a server to compare the image information of the injection molded from the camera module with the image information of the non-defective article stored in advance, And transmits a command signal to the take-out robot control unit so as to set the travel route of the take-out robot differently according to the determination result.

The safe operation system of the take-out robot may further include a server for comparing the mold internal image information transmitted from the camera module with mold internal image information that is not stored in advance, And sends a command signal to the take-out robot control unit to cause an alarm to be issued or to clean the inside of the mold when there is foreign matter in the take-out robot.

According to the present invention, it is possible to significantly reduce defects or failures due to the impact of the take-out robot, and to safely protect persons working among the take-out robots.

According to the present invention, by controlling the RFID tag and the control server on the mold, mismatching between the injection machine and the assignment take-out robot can be prevented so that an accident that may occur due to the mismatching can be prevented in advance.

According to the present invention, a vision is provided on the end of the take-out robot to photograph the inside of the injection mold and the mold to directly observe the image or to compare with the normal image to detect the foreign object in the injection mold or the mold in the extraction step, Respectively.

1 is a schematic diagram for explaining an embodiment of the present invention.
FIG. 2 is a schematic view illustrating a safety operation system according to an impact sensor according to the present invention.
3 is a schematic diagram illustrating a safety operation system according to a human body detection sensor according to the present invention.
4 is a schematic view illustrating a safety operation system according to the automatic mold recognition according to the present invention.
5 is a schematic diagram for explaining a safety operation system by installing a vision according to the present invention.

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings.

FIG. 1 is a schematic diagram for explaining an embodiment of the present invention, and FIG. 2 is a schematic diagram for explaining an embodiment of a shock detection and safety operation system.

There is a possibility that the moving part of the take-out robot may collide with the injection molding machine or other facilities while the take-out robot for taking out and transporting the injection molding material is disposed in the work place where a plurality of injection molding machines are installed. The operation of the take-out robot is performed by inputting variables such as an operation condition inputted to the control module at the beginning of the operation, for example, a movement distance of each direction of XYZ motion, a movement speed, a rotation angle of the rotation part, And the operation is repeated according to the operating condition. It is normal that the collision does not occur due to the operation according to the operating condition, but there may be collision with the periphery when the shape of the taken-out object is defective, and there may be a collision even when the mold opening operation is abnormal. In some cases, collisions may occur by interfering with paths as objects are brought into the workplace. Further, an operator can control the operation of the take-out robot by using a separate wired / wireless controller for remotely controlling the take-out robot, and a crash may occur during the manual operation of the controller (refer to FIG. When such a collision occurs, if the operation of the take-out robot is repeatedly performed, the secondary and tertiary damages follow the same. Ultimately, the operation of the take-out robot should be completely down, and the take-out robot should be restarted after physically arranging the work site. This process significantly reduces the productivity of the extraction operation and expends a large number of unexpected costs. Therefore, according to the present invention, when a collision occurs, the robot immediately detects the collision and stops the operation of the take-out robot. When a collision occurs, an impact is transmitted to the servo motor provided for operation of the take-out robot by the vibration, and the amount of current changes. Therefore, the crash management control module is installed in the take-out robot controller so as to suspend the operation when the current amount or torque value of the server motor is monitored. The stop time can be set in the control module as desired, for example, 3 minutes.

In addition, although a collision can be immediately stopped when a collision occurs, the control module can be set to stop after a certain distance (for example, 10 cm) is reversed.

In addition, one or more additional shock sensors such as vibration sensors may be installed in the robotic arm of the take-out robot. The installed shock sensor generates a current by the vibration and the control unit can recognize the occurrence of the collision through the electric signal.

By stopping the operation of the take-out robot that automatically resumes operation after a predetermined time by physically solving the problem by inputting the workforce quickly while reducing additional damage through the stop and / or reverse operation, have.

On the other hand, if the collision of the take-out robot is a human body, the human injury problem may be more serious. Therefore, the human body detection sensor is installed as shown in FIG. Human body detection sensor can use infrared sensor. It is preferable that the infrared sensor is installed in an end portion (for example, a rotating portion) of the take-out robot arm. Since the take-out robot ascends in the vertical direction after taking out the injection object and then travels while traveling, the end of the arm reaches a considerable height, The shock is the most dangerous. Therefore, the control module of the take-out robot is programmed to stop the operation immediately when the human body detection signal is input from the human body detection sensor. The stopping time can be, for example, one minute, but these values can be adjusted to the situation. The means for communicating with the human body sensor and the control unit of the take-out robot is preferably configured as a wireless IoT (Internet to Things), but it may also be configured as a wire.

As such, the stopping motion after a human body detection prevents the occurrence of an accident and enhances the safety.

On the other hand, when a plurality of injection machines and a plurality of take-out robots are used in a single workplace to produce various kinds of injection materials, the injection conditions stored in the injection machine control device must be set individually for each injection object, The injection condition of another injection object may be called up. In this case, since the motion condition of the take-out robot performing the take-out operation from the injection machine is generally adjusted to the correct injection object, the operation conditions of the take-out robot do not match each other, leading to an accident. Therefore, according to the present invention, as shown in FIG. 4, a user control server capable of managing a workplace is installed, an RFID tag is attached to each mold, a unique identification number is assigned, and injection information (injection pressure, injection temperature, (Motion direction, motion distance, speed, rotation angle, etc.) of the take-out robot assigned to the injector are recorded on the user control server. The server recognizes the identification number transmitted through the RFID according to the mold, searches for corresponding injection information, transmits the injection information to the injection control unit and uploads the same, and at the same time, the control unit of the take- So that the accident caused by the mismatching can be prevented in advance. In this case, the communication means used may also be a wired / wireless IoT.

5, when the arm is lowered and the mold is opened to take out the injection molded product, a shape of the molded product is photographed and a display device (camera module, Such as a monitor or a smart phone, which are linked to each other. Therefore, the shape defect of the injection object, the nut and / or the missing of the insert are checked through the image, and in the case of defective, the conveyance path is set to the defective article collection box. That is, the path of the take-out robot can be immediately controlled by identifying the defect with the naked eye of the operator, the good shape is stored in the server, the recognized image information is compared, and if the shape outside the good category is recognized, The program module may be installed in the take-out robot control unit.

While the robot arm is lifted in a state where the take-out robot takes out the injection object, the vision can photograph the inside of the opened mold and transmit the image to the user control server. An operator observing the image through the display checks whether or not foreign matter exists in the mold, and performs a foreign matter removing operation (ion cleaning, etc.) before the work is repeated if a foreign matter is found. Also, the image information photographed by the vision may be compared with the in-mold image information stored in advance, and an automatic alarm may be generated when an image that can be regarded as a foreign object is detected. Such a configuration can facilitate the work of the operator.

It is possible to configure the integrated control server installed in the company by the take-out robot manufacturing vendor in addition to the user control server so that the image information of the vision is also transmitted to the integrated control server so that the operation of the take- It is possible.

It is to be understood that the invention is not limited to the disclosed embodiment, but is capable of many modifications and variations within the scope of the appended claims. It is self-evident.

No reference symbol.

Claims (8)

A shock sensor for detecting a shock when the take-out robot is in operation and transmitting a signal to the control module of the take-out robot; And
And a control module for temporarily stopping the movement of the robot immediately after receiving the impact detection signal from the control unit of the take-out robot or stopping the robot after a predetermined amount of movement. And a control module for controlling the take-out robot to stop the movement of the take-out robot for a predetermined time when a human body detection sensor is mounted on the take-out robot and a human body is detected within a predetermined distance in the movement path of the take-out robot, . The take-off robot safe operation system according to claim 1, wherein the impact sensor is a server motor included in the take-out robot, and the change in the current value of the server motor is detected by the take-out robot control unit. 3. The safety operation system of the take-out robot according to claim 2, wherein the human body detecting sensor communicates with the take-out robot control unit via IoT (Internet to Things). An RFID tag attached to each mold;
A server in communication with the RFID tag; And
And a take-out robot having a control module capable of taking out an injection product from a mold and communicable with the take-
In the RFID, unique identification information for each mold is planted, identification information is transmitted to the server,
The server uploads the injection information according to the mold identification number and the operation information of the takeout robot assigned to the mold to the control unit of the injection machine and the control unit of the takeout robot so that the injection information of the injection machine and the operation information of the take- And a safety operation system of the take-out robot is provided. A camera module installed at a robot arm end of the takeout robot; And
And a display device for receiving and displaying image information from the camera module,
Wherein a display of an image of an injection object or an internal image of the mold is observed from the display to detect a defect of an injection molding or the presence of a foreign substance inside the mold. 7. The safety operation system of the take-out robot according to claim 6, further comprising a server, wherein the exit image information transmitted from the camera module is compared with the image information of the non-defective article stored beforehand to determine whether the article is good or defective And transmits a command signal to the take-out robot control unit so as to set the travel route of the take-out robot differently according to the determination result. The safety operation system of the take-out robot according to claim 6, wherein the safety operation system of the take-out robot further includes a server, wherein the mold internal image information transmitted from the camera module is compared with the mold internal image information which is not stored in advance, And sends a command signal to the take-out robot control unit to cause an alarm to be issued or to clean the inside of the mold.

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