TWM577960U - Equipment information management system - Google Patents

Abstract

The present invention is directed to a management system for device information, comprising at least one device, at least one switching device, at least one processing device, and a servo system, the switching device electrically connecting the device and the processing device, and generating one of the devices The signal is transmitted to the processing device, and the processing device decodes the working signal to generate a data. The processing device is electrically connected to the servo system, and the data is transmitted to the servo system for analysis to generate a management information in an operation interface, and the operation interface determines the working state of the device according to the management information. In this way, the remote monitoring device of the system is managed, and the corresponding processing is immediately performed according to the abnormal condition of the device.

Description

Equipment information management system

This creation department is related to a management system, especially a system for obtaining information about the operational status of a device and subsequently performing related management.

The traditional automatic sealing machine is applied to the sealing process of electronic components, and can be installed in a large number of production lines in various working environments according to operational requirements. The conventional automatic sealing machine integrates the related software and hardware devices into a single machine through a programmable logic controller (PLC), and can automatically execute a preset instruction device. Field personnel can view the relevant parameter changes in the human machine interface of the automatic sealing machine, and further set parameters to determine the operation mode of the sealing process.

As one of the important steps in the overall process of electronic components, automatic sealing machine can produce a large amount of products to increase production capacity through automatic control; however, there is still a lack of improvement in the operation of automatic sealing machine. For example, if an automatic sealing machine malfunctions during operation, it is necessary for the on-site personnel to promptly find the failure notification (such as sound, lighting, etc.) issued by the automatic sealing machine in order to solve the problem. If the on-site personnel of the production line fail to pay attention to the machine failure in time (hereinafter referred to as the machine), the output efficiency of the production line will be seriously affected. However, the automatic sealing machine is installed on each floor and everywhere of the plant. It requires on-site personnel to patrol regularly. It takes a certain amount of time to completely check whether each automatic sealing machine is operating normally, which has the disadvantages of time-consuming and labor-intensive.

In addition, the general troubleshooting method for the automatic sealing machine is based on the fault message displayed by the on-site personnel according to the human-machine interface to improve the problem. Furthermore, if the on-site personnel fail to easily eliminate the problem of the automatic sealing machine, it is necessary to contact the relevant maintenance personnel for repair work. Therefore, in the design of the automatic sealing machine, there are still several problems that need to be improved: 1. The problem of the automatic sealing machine must be discovered by the on-site personnel in time, but the automatic sealing machine may be set in multiple ways. It is installed everywhere, so it takes a certain amount of time and manpower to perform. 2. The relevant data such as the parameter setting of the automatic sealing machine can be obtained only on the man-machine interface or the control device in the field, and cannot be performed at the remote end, which is inconvenient. 3. The automatic sealing machine of each brand has different execution modes. The software and hardware programs and compatibility problems are more limited, and it is impossible to effectively integrate the automatic sealing machines of various brands. 4. The automatic sealing machine can only issue warnings for abnormal conditions. It is necessary for the on-site personnel to check the location to understand the problem, and it is impossible to provide the problem in advance, so that the relevant personnel can receive the message and decide to be easily excluded by the on-site personnel. Or notify the machine maintenance personnel to go directly to the repair.

For the sake of the job, the creator has improved the above-mentioned problems, and the idea of creating and improving is to develop a solution, and the management system of the equipment information created by the author has been created for a long time to serve the society. The public and promote the development of this industry.

The purpose of the present invention is to provide a device information management system, which electrically connects at least one device to at least one processing device via at least one switching device, and the processing device is further electrically connected to a servo device, by means of a switching device, processing The device and the servo device integrate management devices, and the operating state of the device can be monitored remotely, so that the monitoring information can be properly processed in real time.

In order to achieve the above-mentioned purpose and effect, the present invention discloses a device information management system, comprising: at least one device generating a working signal; at least one switching device electrically connecting the device and at least one processing device, The processing device receives the working signal through the switching device, and processes the working signal to generate a data; and a servo system includes an operation interface, the servo system is electrically connected to the processing device, and the data is analyzed to generate a management information. Operation interface.

In an embodiment of the present invention, the disclosure further includes a database electrically connected to the processing device and the servo system, the database stores the data, and transmits the data to the servo system.

In an embodiment of the present invention, the database is also disclosed as a cloud storage system, a hard disk or a storage device.

In an embodiment of the present invention, it is disclosed that the operation interface includes a control signal generated according to the management information, and transmitted to the processing device via the operation interface, triggering the processing device to shut down the device.

In an embodiment of the present invention, it is disclosed that the operation interface includes a troubleshooting notification generated according to the management information, and transmitted to the at least one communication device via the operation interface.

In an embodiment of the present invention, it is also disclosed that the device is an automatic sealing machine for the electronic component sealing process.

In an embodiment of the present invention, it is also disclosed that the switching device is one of the serial transfer universal buss.

In an embodiment of the present invention, it is also disclosed that the switching device is a serial port wireless transmission extender.

In an embodiment of the present invention, the method further includes a control device electrically connected to the device and the servo system, wherein the operation interface generates a control signal according to the management information, and the control signal is transmitted to the control interface via the operation interface Control device to trigger the control device to shut down the device.

In order to give your reviewers a better understanding and understanding of the characteristics of the creation and the effects achieved, please refer to the examples and detailed explanations as follows:

In the following, various embodiments of the present invention will be described in order to explain the present invention in detail; however, the concept of the present invention may be embodied in many different forms and should not be construed as being limited to the exemplifications set forth herein. Example.

The structural components required for the system of the first embodiment of the present invention are described herein. Please refer to the first figure, which is a system diagram of a first embodiment of a management system for creating device information. As shown, the system required for the first embodiment of the present invention comprises: at least one device 10, at least one switching device 20, at least one processing device 30, and a servo system 50. The device 10 is wired via the switching device 20. Or the wireless electrical connection processing device 30 can electrically transmit one of the working signals 100 to the processing device 30 through the switching device 20, and can transmit the working signal 100 to the processing device 30. The processing device 30 receives the working signal 100 and converts the working signal 100 into a data 300. The servo system 50 includes an operation interface 500. The servo system 50 receives the data 300 for analysis, and then generates a management information 502 in the operation interface 500. The operation interface 500 determines the working state of the device 10 according to the management information 502 (start, close, pause, etc.). status).

The device 10 described above is an automatic sealing machine for electronic components to seal the process, and can be designed for different brands of different brands, and can be installed in various factory locations and production lines of various floors.

The switching device 20 described above is one of the serial port (EIA RS 232, abbreviated as RS232) to the universal serial bus (USB), and the device 10 and the processing device 30 can be connected in a wired manner. Alternatively, for a sequence of wireless transmission extenders, the serial port wireless transmission extender can be disposed on the device 10, and then connected to the processing device 30 to receive the working signal 100 through the wireless transmission mode. Therefore, as long as it is applicable to the device 10 and the switching device 20 in which the processing device 30 is electrically connected, it is not limited to the scope of the present invention.

The processing device 30 can be a computer or a processing software installed in the computer. Since the working signal 100 is continuously generated during the operation of the device 10, the processing device 30 continuously receives the working signal 100 and converts it into data. 300, that is, the current operation of the sustainable acquisition device 10.

The above-mentioned servo system 50 is a webpage architecture, which includes an operation interface 500 for the relevant personnel to observe the current operation status of the equipment 10 set in each factory area and each floor. After the servo system 50 receives the data 300, the analysis generates the management information 502 and displays it on the operation interface 500. The relevant personnel will remotely monitor the working condition of the device 10 through the data displayed by the operation interface 500.

Continuing to explain the process steps performed by the system of the present invention, please refer to the second figure, which is a flow chart of the first embodiment of the management system for the device information of the creation. As shown in the figure, the method performed by the device information management system of the embodiment includes the following steps: Step S10: providing at least one device to generate a working signal; Step S30: providing at least one switching device to receive the working signal And transmitting to the at least one processing device, the processing device processes the working signal to generate a data; and step S50: the servo system analyzes the data to generate a management information in an operation interface, and the operation interface determines the device according to the management information Working status.

The flow of the first embodiment of the management system of the device information of the present invention will be described below, and the first to second figures will be referred to collectively. First, each device 10 generates a working signal 100 (step S10), and the working signal 100 includes a working normal signal, a working abnormal signal, a temperature control signal, and an I/O signal (such as a solenoid valve, a computer translation, etc.). The status of the input or output sensing signal for the action conversion), the signal of the operation of the motor or the servo motor, etc., the signals generated by the soft and hardware devices during the operation, shutdown, and abnormality of the device 10 are all included in the working signal 100. In addition, other implement devices that are applied to the production line and have the work signal 100 generated by the operation of the device 10 described above can also be used as the device 10 of the present invention, and are combined with the switching device 20, the processing device 30, and the servo system 50, and are not limited thereto. The field of automatic sealing machines.

The device 10 and the processing device 30 are electrically connected by the switching device 20, and the working signal 100 can be transmitted to the processing device 30, after which the processing device 30 continuously receives the working signal 100 and converts the processing into data 300 (step S30). The purpose of converting the working signal 100 into the data 300 is to encode the data of different machines in order to enable the components of the two different system architectures to be compatible with the soft and hard acceptable compatibility information. The / or decoding mode processes the working signal 100 as data 300. For example, assuming that the system in which the device 10 operates is one of a DOS system, a WINDOWS system, a Macintosh operating systems system, an Android system, or an IOS system, and the servo system 50 is not operated by the same system as the device 10, the processing device 30 must work. The signal 100 is converted into data 300 that the servo system 50 can receive in order to facilitate the servo system 50 to perform subsequent steps. Therefore, in addition to the advantages of encoding and/or decoding the working signal 100 into the data 300, the processing device 30 can convert the working signals 100 generated by the devices 10 of the various brands into the data 300 receivable by the servo system 50. Effectively integrate the information collection of the plurality of devices 10.

Thereafter, the data 300 generated by the processing device 30 is transmitted to the servo system 50, and the data 300 is generated via the servo system 50 to generate management information 502 for viewing by the relevant personnel in the operation interface 500 (step S50). The management information 502 includes various signals disclosed by the working signal 100, and further analyzes and integrates the signals to be received and displayed in the operation interface 500. Various information such as the operation of soft and hardware components of each device 10, downtime, scheduling, statistical analysis of the number of normal/abnormal occurrences, and immediate update of the operational status are displayed on the operation interface 500 after analysis and reform by the servo system 50. Provide personnel with information on the condition of equipment 10 at each location.

Please refer to the third figure, which is a flowchart 1 of the first embodiment of the management system for creating device information. As shown in the figure, when the step of the first embodiment of the present invention is executed to S50, the method further includes: Step S510: The operation interface determines, according to the management information, that the device does not meet the standard operation, and generates a control signal to be transmitted to the processing device, triggering The processing device stops the operation of the device.

When the device 10 is in normal operation, and the operation interface 502 of the servo system 50 receives the management information 502 to determine that the device is also in normal operation, the device 10 continues to transmit the working signal 100 to the processing device 30, and continues to maintain steps S10 to S50. However, if the device 10 has an abnormal condition, the servo system 50 analyzes the management information 502 generated by the data 300, and displays the abnormal information on the operation interface 500, except that the device 10 confirms a certain position through the display of the operation interface 500 by the relevant personnel. In addition to the problem of operation, a control signal 5000 is actively transmitted from the operation interface 500 to the processing device 30, and the processing device 30 is triggered to stop the operation of the device 10, thereby preventing the device 10 from continuously malfunctioning and affecting the yield of the product on the production line. Therefore, if the person monitoring the operation interface 500 fails to find the problem of the device 10, the operation interface 500 can automatically stop the operation of the device 10 in time, and then the monitoring personnel view the operation interface 500, and the operation interface 500 can be known to be relevant. Measures.

Referring to the fourth figure, it is a flow chart 2 of the first embodiment of the management system for creating device information. As shown in the figure, when the step of the first embodiment of the present invention is executed to S510, the method further includes:

Step S520: The operation interface determines, according to the management information, that the device does not meet the standard operation, and generates a fault elimination notification.

When the step is executed to S510, the servo system 50 can internally build the relevant fault data of the device 10, or directly analyze the data from the abnormal data 300, compare the difference between the normal data 300, and then obtain the device according to the generated management information 502. 10 machine problems. Therefore, in addition to the instant stop device 10 continuing to operate incorrectly, at least one communication device (not shown, such as a smart phone, a computer, etc.) that notifies the field personnel or maintenance personnel at the location of the device 10 can be sent. Let it go to the inspection immediately after it is notified. Therefore, the operation interface 500 sends the basis of the troubleshooting report, and the management information 502 obtains the problem of the device 10, and can further determine that the simple fault is eliminated, the transmission failure notification is notified to the field personnel, or the device 10 is determined to be significant. If the machine component fails, the troubleshooting report needs to be sent directly to the tool maintenance personnel, and go to the site to perform the repair work, thereby reducing the equipment 10 failure time and reducing the impact of the production line performance.

In addition, the step S510 and the step S520 of the present invention may be performed simultaneously after the step S50, that is, the operation interface 500 determines that the device 10 does not meet the standard operation according to the management information 502, and simultaneously generates the control signal 5000 and the troubleshooting notification, and the control signal 5000 on the one hand. Transfer to processing device 30 triggers processing device 30 to stop operation of device 10. On the other hand, the operation interface 500 determines, according to the management information 502, that the troubleshooting report is directly transmitted to the field personnel or the machine maintenance personnel to handle the problem. After the step S50 of the present creation, the step S520 may be directly implemented, and after the step S50, the step S520 is performed first, and then the step S510 is performed. In other words, the steps S510 and S520 may be performed separately after the step S50, or the S510 may be performed first and then the S520 may be performed by using the combination, and the S520 may be performed first and then S510 may be performed instead of the present embodiment.

The structural components required for the system of the second embodiment of the present invention are described herein. Please refer to the fifth figure, which is a system diagram of a second embodiment of the management system for device information. As shown in the figure, the system required for the second embodiment of the present invention differs from the first embodiment in that it further includes a database 70 electrically connected to the processing device 30 and the servo system 50 for receiving the processing device 30. The transmitted data 300 is stored, and then the data 300 is further transmitted to the servo system 50 for analysis and utilization by the servo system 50. The data library 70 is disposed in a cloud storage system, a hard disk or a storage device. Therefore, the database 70 can be configured as a software or/and a hardware, as long as the data 300 can be stored. Limited. The purpose of the storage is for the subsequent servo system 50 to read historical information from the database 70 for analysis, and to facilitate understanding of the operation of the device 10 at various time periods to facilitate further improvement of the problem, or the servo system 50 may also store the management information 502. Read in the database 70 for reference.

Continuing to explain the process steps performed by the system of the present invention, please refer to the sixth figure, which is a flow chart of the second embodiment of the management system for the device information of the creation. As shown in the figure, the method performed by the device information management system of the embodiment includes the following steps: Step S10: providing at least one device to generate a working signal; Step S30: providing at least one switching device to receive the working signal And transmitting to the at least one processing device, the processing device processes the working signal to generate a data; Step S40: providing a database to store the data, and transmitting the data to the servo system; and step S50: analyzing the data by a servo system A management information is generated in an operation interface, and the operation interface determines the working state of the device according to the management information.

The structural components required for the system of the third embodiment of the present invention are described herein. Please refer to the seventh figure, which is a system diagram of a third embodiment of the management system for device information. As shown in the figure, the system required for the third embodiment of the present invention differs from the first embodiment in that it further includes a control device 80, an electrical connection device 10, and a servo system 50. The operation interface 500 is based on the management resource 502. A control signal 5000 is generated, and the control signal 5000 is transmitted to the control device 80 via the operation interface 500 to trigger the control device 80 to turn off the device 10. The control device 80 can be a computer or a processing software disposed on the computer for electrical use. Connect a switch or program command that shuts down the operation of device 10.

Please refer to the eighth figure, which is a flowchart 1 of the third embodiment of the management system for creating device information. As shown in the figure, when the step of the third embodiment of the present invention is executed to S50, the method further includes: Step S530: The operation interface determines, according to the management information, that the device does not meet the standard operation, and generates a control signal to be transmitted to a control device, triggering The control device stops the operation of the device.

The control device 10 is provided to mean that if the device 10 has an abnormal condition, the servo system 50 analyzes the management information 502 generated by the data 300, and displays the abnormal information on the operation interface 500, except that the relevant personnel confirm the display via the operation interface 500. In addition to the problem of the device 10 in a certain location, the control interface 500 actively transmits a control signal 5000 to the control device 80, and the trigger control device 80 stops the operation of the device 10, thereby preventing the device 10 from continuing to malfunction and affecting the product on the production line. rate.

Referring to the ninth figure, it is a flow chart 2 of the third embodiment of the management system for the device information of the present invention. As shown in the figure, when the step of the third embodiment of the present invention is executed to S530, the method further includes: Step S540: The operation interface determines, according to the management information, that the device does not meet the standard operation, and generates a fault elimination notification.

In the third embodiment of the present invention, the processing device 30 receives only the working signal 100 generated by the device 10 to process the working signal 100 to generate the data 300. The control device 80 determines whether to generate the control signal 5000 according to the result of the analysis and determination of the servo system 50. If an abnormal condition is required to generate the control signal 5000, the servo system 50 transmits the control signal 5000 to the control device 80 to trigger. Control device 80 turns off device 10. Therefore, the step S510 of the first embodiment of the present invention is similar to the operation of the step S530 of the third embodiment. The difference is that the control signal 5000 is transmitted back to the processing device 30 or is transmitted to the control device 80 to turn off the abnormal device 10. In addition, the step S540 of the third embodiment of the present invention is the same as the step S520 of the first embodiment, and the execution manners of the steps S530 and S540 are the same as the sequential/simultaneous execution manner of the step S510 and the step S520 of the first embodiment. The description will not be repeated.

The advantages of the management system of the device information of this creation are as follows: 1. Unifiedly integrate the operation status of each device for remote monitoring, and centrally manage the servo system for immediate control without the need for timing, capacity, and fixed-point inspection equipment. 2. The status of the abnormality of the equipment is displayed on the operation interface for the relevant personnel to know, and the equipment assigned to the dispatcher can be accurately sent to the machine for troubleshooting. 3. Effectively integrate the equipment of various brands to obtain information, and uniformly display the operation situation by the operation interface of the servo system to improve the incompatibility of traditional equipment.

The management system of the device information of the present invention has indeed achieved the intended purpose and effect of use, and is more ideal and practical than the prior art; however, the above embodiments are specifically described for the preferred embodiment of the present invention, and are not used. In order to limit the scope of the patent application of this creation, all other equivalent changes and modifications that have been made without departing from the technical means disclosed in the present invention shall be included in the scope of the patent application covered by this creation.

10‧‧‧ Equipment

100‧‧‧Working signals

20‧‧‧Transfer device

30‧‧‧Processing device

300‧‧‧ data

50‧‧‧Servo system

500‧‧‧Operator interface

5000‧‧‧Control signal

502‧‧‧Management Information

70‧‧‧Database

80‧‧‧Control device

S10‧‧‧ steps

S30‧‧‧ steps

S40‧‧‧ steps

S50‧‧ steps

S510‧‧‧Steps

S520‧‧‧Steps

S530‧‧‧Steps

S540‧‧‧Steps

The first picture is a schematic diagram of the first implementation system of the management system for the device information of the creation; the second picture: the flow chart of the first embodiment of the management system for the device information of the creation; The flow chart 1 of the first embodiment of the management system for creating the device information; the fourth picture: the flow chart 2 of the first embodiment of the management system for the device information of the creation; the fifth picture: A schematic diagram of a second embodiment of a management system for equipment information; a sixth diagram: a flowchart of a second embodiment of a management system for equipment information created by the author; and a seventh diagram: a management system for equipment information of the creation The third embodiment is a schematic diagram of the processing flow of the third embodiment of the device management system of the present invention; and the ninth diagram: the third embodiment of the management system for the device information of the creation Process flow diagram II.

Claims (9)

A device information management system, comprising: at least one device generating a working signal; at least one switching device electrically connecting the device and at least one processing device, the processing device receiving the working signal via the switching device, and Processing the working signal generates a data; and a servo system includes an operation interface electrically connected to the processing device, and analyzing the data to generate a management information in the operation interface. The management system of the device information as described in claim 1 further includes a database electrically connected to the processing device and the servo system, the database storing the data and transmitting the data to the servo system. For example, the management system of the device information described in claim 2, wherein the database is a cloud storage system, a hard disk or a storage device. The management system of the device information as described in claim 1, wherein the operation interface includes a control signal generated according to the management information, and transmitted to the processing device via the operation interface, triggering the processing device to close the device . A management system for device information as described in claim 1 or 4, wherein the operation interface includes a troubleshooting notification generated based on the management information and transmitted to the at least one communication device via the operation interface. For example, the management system of the device information described in claim 1 of the patent scope, wherein the device is an automatic sealing machine for the electronic component sealing process. The management system of the device information as described in claim 1, wherein the switching device is one of a sequence transfer universal sequence bus. The management system of the device information as described in claim 1, wherein the switching device is a serial port wireless transmission extender. The management system of the device information as described in claim 1 further includes a control device electrically connected to the device and the servo system, and the operation interface generates a control signal according to the management information, and the control signal is operated by the operation. The interface is transmitted to the control device to trigger the control device to shut down the device.