Table of contents
Instructions for the first part of the competition
2. Professionalism and Safety Awareness
The second part of the competition task
Module 1 Industrial Internet equipment installation and commissioning
Module 2 Industrial Internet Platform Development and Application
Instructions for the first part of the competition
1. Competition Requirements
1. Correct use of tools and operation safety regulations;
2. If there is any objection during the competition, it can be reported to the referee, and the order of the field must not be disturbed;
3. Obey the field discipline, respect the referee, and obey the arrangement.
2. Professionalism and Safety Awareness
1. All operations to complete the competition tasks are in compliance with the safety operation specifications, and pay attention to the safety of electricity use.
2. Obey the discipline of the arena, respect the staff of the arena; cherish the equipment and equipment of the arena.
3. Point deduction
1. During the competition, if the equipment is destructively damaged or caused an accident due to improper operation, it will depend on the circumstances.
10 to 20 points, if the situation is serious, the qualification will be disqualified.
2. Behaviors that do not conform to professional standards, such as disheveled clothing, polluting the arena environment, disturbing the order of the arena, and interfering with the work of referees, will be deducted from the corresponding professionalism in Module 3. If the circumstances are serious, they will be disqualified from the competition.
4. Information for players
1. If there are problems such as missing pages or unclear handwriting in the task book, please notify the referee in time and replace it;
After the competition, all paper materials and USB flash drives provided by the competition shall not be taken away from the competition venue.
2. Please operate in strict accordance with the requirements of the mission statement and process specifications for the installation and configuration of the equipment.
3. Participating teams should complete the content required by the mission statement within the specified time. The documents and materials formed during the mission realization process must be stored in the designated location of the U disk, and at the same time copy a copy of the "submitted materials" to the "D disk" root of the server. Under the directory, files that are not stored in the specified location will not be scored.
4. During the competition, if the player determines that the device or device is faulty, he can ask the referee to replace it; if the device or device is determined to be intact, it is a misjudgment, and the time for the device or device to be recognized will be included in the competition time; if the device or device is determined to be If there is a fault, the equipment will be replaced on the spot. For the time loss caused during this process (from the start of equipment detection to the completion of the replacement), after the end of the game time, the team will be compensated for the same amount of time delay.
5. Devices will not be replaced if they are damaged due to human error during the competition.
6. After the referee team announces the end of the competition, the contestants should immediately stop any use of the competition equipment and computers.
what to do.
The second part of the competition task
1. Task requirements
The competition platform is mainly composed of feeding and filling workstations, processing and testing workstations, finished product storage workstations, intelligent control units, industrial Internet network equipment, industrial Internet gateways, industrial Internet platforms, industrial Internet Kanban display systems, training tables, computer tables and chairs, etc. composition. The competition platform takes the intelligent canning production line as the carrier, and with the help of industrial Internet, big data, cloud computing and other technical means, builds a typical production scene based on data collection, modeling, and analysis. etc. as the perception layer; with PLC, acquisition module, HMI as the control and display unit, with industrial switches, IOT gateways and remote debugging modules as the network layer, with cylinders, frequency conversion motors, stepper motors, servo motors, pneumatic components, industrial The robot is the execution unit, and the terminal connection platform and the industrial Internet platform are used as the platform layer to realize the full-process automated production of the canning production line. It can assess the installation and commissioning of industrial equipment, industrial network networking and configuration, industrial gateway configuration, and industrial Internet platform. Integrated application (device access, data acquisition, cloud access, data visualization, digital twin, industrial APP development) and other technical capabilities.
2. Task environment
Hardware resources: computers, industrial Internet integrated application workstations, industrial Internet platforms, toolboxes, consumables, etc.
Software resources: see the "competition data" folder in the U disk.
3. Task implementation
Module 1 Industrial Internet equipment installation and commissioning
Task scenario:
The installation and wiring of the unit's control system has been completed. The contestants need to use the devices and materials purchased by the customer. The team is responsible for the installation and wiring connection of the RFID code reader, and the installation and wiring connection of the visual camera, so as to ensure that the mechanism can operate correctly and the circuit can operate correctly, and the system conforms to professional technical specifications. Draw the network topology diagram and complete the network installation and debugging of the industrial network system of the industrial Internet competition platform.
Task 1-1 Industrial Internet equipment installation
device installation
Contestants use the network components and tools provided on site to complete the installation of networking equipment such as switches, wireless routers, MODBUS gateways, edge computing gateways, and industrial Internet gateways.
Task 1-2 Industrial Internet equipment debugging
(1) Connect the power cable of the visual camera to the XS203 interface, make a network cable and connect the communication cable of the visual camera to LAN1;
(2) The IP address of the vision camera is set to: 192.168.3.23;
(3) Connect the RFID communication line to the POE interface, and set the IP address to: 192.168.3.22;
(4) Create a detection plan for the visual camera, continuously detect the material bottles on the conveying line, create feature matching detection for the material cap and material bottle respectively, and format the status results of the feature matching module, and send them to port 8192 in the form of a TCP server number sent to the PLC.
For example:
The visual camera detects that there is a bottle, the cap is tightened, and the TCP server of the visual camera sends a string: 1; 1;
The visual camera detects that there is a bottle, the cap is not tightened or there is no cap, and the TCP server of the visual camera sends a string: 1; 0;
Module 2 Industrial Internet Platform Development and Application
Task scenario:
The contestants are completing the installation and debugging of Task 1. Now the team is required to complete the PLC program writing and robot parameter setting of the finished product storage workstation, the touch screen configuration and debugging, the whole machine joint debugging, operation and program optimization. From the process of empty bottle feeding, liquid filling, capping, capping, testing, product sorting, robotic handling of qualified products into boxes, and finished product storage, it is guaranteed that the system can operate correctly and the system complies with professional technical specifications. Complete the programming and debugging of the entire production line within the specified time, so that the production process automation and industrial Internet data collection can be realized in the later stage of the production line.
Task 2-1 Data Acquisition System and Application
Industrial Internet Gateway Data Acquisition
(1) Task purpose
Based on the industrial Internet data acquisition gateway, read the data related to the equipment in the PLC, and realize the data acquisition of the processing and testing workstation to the gateway.
(2) Task requirements
1. Data acquisition project creation
(1) To create a new project in the gateway configuration software , the specific requirements are as follows:
| serial number |
Design requirements |
screenshot |
|
| 1 |
name |
Processing and testing workstation data acquisition cloud project |
Screenshot, saved in U:\Industrial Internet Integrated Application Competition (Higher Vocational)\No. * Field\No. * Station\Industrial Internet Gateway Data Acquisition, named: 01 New Project.jpg |
| 2 |
path |
U:\Industrial Internet Integrated Application Competition (Higher Vocational) |
|
| 3 |
Other parameters |
default |
|
(2) Add equipment in the "Processing and Testing Workstation Data Acquisition Cloud Project", the specific requirements are as follows:
| serial number |
Design requirements |
screenshot |
|
| 1 |
name |
Gateway equipment ECU-1251 |
Screenshot, saved in U:\Industrial Internet Integrated Application Competition (Higher Vocational)\No. * Field\No. * Station\Industrial Internet Gateway Data Acquisition, named: 02 Add Gateway Device.jpg |
| 2 |
Equipment type |
ECU-1251 TL-R10A |
|
| 3 |
Identification method |
IP address/domain name |
|
| 4 |
IP address/domain name |
192.168.3.99 |
|
| 5 |
Other parameters |
default |
|
(3) Set basic information in "Gateway Equipment ECU-1251"/"Data Center"/"I/O Point"/"TCP", the specific requirements are as follows:
| serial number |
Design requirements |
screenshot |
|
| 1 |
Scan time (ms) |
1000 |
Screenshot, saved in U:\Industrial Internet Integrated Application Competition (Higher Vocational)\No. *Field\No.* Station\Industrial Internet Gateway Data Collection, named: 03TCP Basic Information.jpg |
| 2 |
timeout (ms) |
2000 |
|
| 3 |
number of retries |
5 |
|
| 4 |
Automatic recovery time (s) |
5 |
|
| 5 |
Other parameters |
default |
|
2. Add data acquisition node
(1) Add devices in "Gateway Device ECU-1251"/"Data Center"/"I/O Point"/"TCP", the specific requirements are as follows:
| serial number |
Design requirements |
screenshot |
|
| 1 |
name |
PLC device FX5U_64_02 |
Screenshot, saved in U:\Industrial Internet Integrated Application Competition (Higher Vocational)\No. * Field\No. * Station\Industrial Internet Gateway Data Acquisition, named: 04 Add PLC Device.jpg |
| 2 |
Equipment type |
Mitsubishi MELSEC-Fx5 Series PLC(MC Protocol) |
|
| 3 |
unit number |
1 |
|
| 4 |
IP/domain name |
The IP of the PLC of the processing and testing workstation |
|
| 5 |
The port number |
3001 |
|
| 6 |
Other parameters |
default |
|
(2) Refer to the "PLC data point table" to add device data in the "I/O point" respectively. The specific requirements are as follows:
| serial number |
point name |
type of data |
conversion type |
PLC address |
Other parameters |
| 1 |
Push level detection |
Discrete |
N/A |
X0 |
default |
| 2 |
Stepper motor direction |
Discrete |
N/A |
Y3 |
default |
| 3 |
Push cylinder solenoid valve |
Discrete |
N/A |
Y5 |
default |
| 4 |
Screw cap motor |
Discrete |
N/A |
Y7 |
default |
| 5 |
Capped lifting cylinder solenoid valve |
Discrete |
N/A |
Y14 |
default |
| 6 |
Return to raw material warehouse inspection |
Discrete |
N/A |
X32 |
default |
| 7 |
Suction Cup Solenoid Valve |
Discrete |
N/A |
Y21 |
default |
| 8 |
start flag |
Discrete |
N/A |
M1 |
default |
| 9 |
Cover Quantity |
Analog |
Unsigned Integer |
D0250 |
default |
| 10 |
Bottle cap count |
Analog |
Unsigned Integer |
D0252 |
default |
| 11 |
Bottle screw cap timing |
Analog |
Unsigned Integer |
D0262 |
default |
| 12 |
Servo motor speed |
Analog |
Unsigned Integer |
D0802 |
default |
| 13 |
Servo alarm information |
Analog |
Integer |
D0822 |
default |
| 14 |
Turntable speed |
Analog |
IEEE Floating Point |
D0224 |
default |
| 15 |
Discharge tray speed |
Analog |
IEEE Floating Point |
D0296 |
default |
| 16 |
Screw cap time setting |
Analog |
IEEE Floating Point |
D0260 |
默认 |
| 17 |
伺服有效负荷率 |
Analog |
Integer |
D0814 |
默认 |
如下:
对PLC设备数据截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网网关数据采集,命名为:05添加加工检测工作站采集数据.jpg
3.数据采集工程运行与维护
(1)在“加工检测工作站数据采集上云工程”/“系统设置”/“网络和Internet”/“网络设置”中设置ECU-1251 TL-R10A网关IP地址和子网掩码,具体要求如下:
| 序号 |
设计要求 |
截图 |
|
| 1 |
IP地址 |
192.168.3.99 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网网关数据采集,命名为:06网关网络设置.jpg |
| 2 |
子网掩码 |
255.255.255.0 |
|
| 3 |
其他参数 |
默认 |
|
(2)保存工程并下载到网关中,并在“在线设备”中查看17个数据点是否采集正常。用录屏软件录制“网关设备ECU-1251”在线设备的采集状态,具体要求如下:
在线监控账号:admin,密码:00000000
录制视频时长1分钟以内,录制界面需包含17个数据点;视频命名成“11加工检测工作站数据采集本地在线监测.mp4”;保存在“U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网网关数据采集”中。
任务2-2 标识解析系统集成应用
工业互联网标识解析服务应用
任务目的
基于产品属性监测实训案例,融入标识解析技术,体验标识解析的标识定义、标识二维码生成、标识注册、标识解析二级节点平台登录、标识解析等功能。
任务要求
运用工业互联网标识解析一物一码功能,以二维码为信息载体,对产线上产品的信息进行编码,一品一码,建立商品信息管理数据链,通过手机终端中安装的识读软件轻松扫码,即可实时方便地查询商品信息,有效辨识真假。
截图:选手需对任务实施过程中的标识定义界面、生成的标识二维码、标识注册界面、标识解析二级节点平台登录界面、扫码解析结果的界面进行保存,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\标识解析服务应用。
任务2-3边缘计算及数据可视化应用
1.工业互联网边缘服务开发
任务目的
基于工业互联网边缘端数据的采集,对数据进行计算分析,完成数据过滤及预警,作出边缘端应急处理,并完成预警信息及处理结果的上报。
任务要求
(1)边缘采集功能应用开发
| 序号 |
设计要求 |
截图 |
|
|
|
启动边缘端数据库MongoDB服务 |
打开电脑运行窗口,输入“cmd”,打开系统命令窗口,输入“net start mongoDB”,按“enter”键,启动MongoDB服务。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:启动MongoDB.jpg |
|
|
启动开发工具,导入项目工程文件 |
启动Visual Studio 2019,导入“EdgeDAPos”项目工程文件,文件存储位置“U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务5:工业互联网边缘服务开发”。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:导入“EdgeDAPos”工程文件.jpg |
|
|
编写数据采集程序 |
在DataAcqPos类中,新增ReadPos()方法,实现对液位数据(位置、液位值、时间)的读取。数据在边缘数据库MangoDB中读取,数据库名:EdgeDB,集合PosSet(位置、液位值、时间)。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:液位值读取程序.jpg |
|
|
在界面视图中添加timer组件,并在初始化函数里启动timer组件,调用ReadPos()方法,实现循环读取数据。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:调用液位读取函数.jpg |
|
|
|
编写数据显示程序 |
在界面视图中添加TextBox控件,在timer函数中添加数据绑定,将读取的实时数据显示在TextBox控件中。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:实时液位值显示.jpg |
|
|
在界面视图中添加chart控件,在timer函数中添加数据绑定,在chart控件中绘制液位值曲线。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:液位值曲线.jpg |
|
(2)边缘计算功能应用开发
| 序号 |
设计要求 |
截图 |
|
|
|
在DataAnalPos类中,新增AnalysisPos()方法,实现对液位数据的过滤,找出预警液位值(12 cm≤液位值≤14 cm)信息(位置、液位值、时间)。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:预警液位数据计算分析程序.jpg |
|
|
|
在DataAnalPos类中,新增AnalysisPosEx()方法,实现对液位数据的过滤,找出超阈值液位值(14cm)的信息(位置、液位值、时间)。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:超阈值液位数据计算分析程序.jpg |
|
|
|
在timer函数中调用AnalysisPos()、AnalysisPosEx()方法。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:调用液位值分析函数.jpg |
|
|
|
编写分析结果显示程序 |
在界面视图中添加ListBox控件,在timer函数中添加数据绑定,显示分析找出的预警液位及超阈值液位信息。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:异常液位数据信息显示.jpg |
(3)边缘采集主动上报功能应用开发
| 序号 |
设计要求 |
截图 |
|
|
|
MySQL数据库操作 |
启动MySQL数据库,在DBeaver主界面中,使用“root”账户创建与MySQL数据库的连接。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:建立数据库连接.jpg |
|
|
新建数据库并命名“DataProPos”,新建数据库表并命名“DataLogPos”,在表格里添加位置、异常液位值、异常发生时间等 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:创建数据库及数据表.jpg |
|
|
|
编写现场应急处理程序 |
在DataProPos类中,新增EdgeProPos()方法,实现设备停机。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:设备停机程序.jpg |
|
|
在timer函数中调用EdgeProPos()方法。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:调用设备停机函数.jpg |
|
|
|
编写数据上报程序 |
在DataProPos类中,新增ReportPos()方法,实现异常数据的上报存储(存储在DataLogPos表格里)。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:异常液位上报程序.jpg |
|
|
在timer函数中调用ReportPos()方法。 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\工业互联网边缘服务开发,命名为:调用异常液位上报函数.jpg |
|
任务2-4 工业互联网平台服务应用
任务目的
通过采集加工检测单元每个节拍的开始和结束时间计算出每个节拍时长,实现数据实时显示并根据节拍时间优化产线生产效率提高产能。
任务要求
可实时显示料瓶拧盖、成品检测、总时长的开始时间、结束时间和工序耗时,还可显示系统当前日期和时间,另外还设有“复位”按键,双击可初始化所有数据。
1.低代码开发平台的数据采集
(1)节点安装
mcprotocol节点路径:U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\node-red-contrib-mcprotoco
| 序号 |
要求 |
截图 |
|
| 1 |
node-red-contrib-mcprotoco |
完成MC Read和MC Write两个节点的安装 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测01节点安装.jpg |
(2)虚拟机IP配置
| 序号 |
要求 |
截图 |
|
| 1 |
IP地址 |
192.168.3.100 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测02虚拟机以太网配置.jpg |
| 2 |
子网掩码 |
255.255.255.0 |
|
| 3 |
默认网关 |
192.168.3.254 |
|
| 4 |
DNS |
192.168.3.15 |
|
(3)节点添加及连接
- MC Read 节点添加
| 序号 |
节拍内容 |
PLC IP地址和端口号 |
地址 |
| 1 |
料瓶拧盖 |
192.168.3.20:3000 |
M50 |
| 2 |
成品检测 |
M51 |
将“料瓶拧盖”节配置截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测03MC Read 节点1.jpg
将“成品检测”节配置截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测04MC Read 节点2.jpg
| 节拍起/止时间标志位说明表 |
|||
| 序号 |
节拍内容 |
起始点 |
终止点 |
| 1 |
料瓶拧盖 |
M50=1(PLC1) |
M50=0(PLC1) |
| 2 |
成品检测 |
M51=1(PLC1) |
M51=0(PLC1) |
2.低代码开发平台的组件开发
(1)组件开发要求
开发一个计时组件,实现任意两个数据时间差的计算。
(2)组件开发过程
- 创建时间节点文件
在C:\Users\Administrator\.node-red\node_modules下创建一个“node-red-contrib-detect”文件夹,并按下表要求完成文件创建。将创建的文件截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测05创建文件.jpg
| 序号 |
文件名称 |
备注 |
| 1 |
node-red-contrib-time-difference.html |
|
| 2 |
node-red-contrib-time-difference.js |
|
| 3 |
package.json |
- “node-red-contrib-detect.html”代码编写
参考U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\node-red-contrib-time-difference\node-red-contrib-detect.html完成代码编写,具体要求如下
| 序号 |
属性 |
属性值 |
| 1 |
节点分类 |
function |
| 2 |
颜色 |
#a6bbcf |
| 3 |
属性 |
Name{value} |
| 4 |
输入个数 |
1 |
| 5 |
输出个数 |
1 |
| 6 |
图标 |
File.png(在线图片,导入文件名就可以使用) |
| 7 |
节点名称 |
detect |
将编写好的代码截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测06html代码.jpg
- “node-red-contrib-detect.js”代码编写
参考U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\node-red-contrib-detect\node-red-contrib-detect.js完成代码编写,具体要求如下
| 序号 |
要求 |
|
| 1 |
代码工作流程 |
1.收到reset指令,将“firsttime”清空; 2.收到第1个信号输入,将当前时间存入“firsttime”; 3.收到第2个信号输入,用当前时间减去“firsttime”里的时间,计算出时间差,单位毫秒; |
| 2 |
状态显示流程 |
1.在节点下方显示一个方形图标; 2.没有信号时,不显示; 3.有信号输入且没有计算时间差时,显示为黄色;同时在方形图标右侧显示:时间差缺失 4.有信号输入且有计算时间差时,显示为绿色;同时在方形图标右侧显示:时间差****ms |
将编写好的代码截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测07js代码.jpg
- “package.json”代码编写
参考U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\node-red-contrib-detect\package.json完成代码编写,使“node-red-contrib-detect.html”和“node-red-contrib-detect.js”关联在一起。
将编写好的代码截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测08json代码.jpg
- 测试“node-red-contrib-detect”节点功能
- 安装部署“node-red-contrib-detect”节点。
- 添加节点“inject”和“debug”,并与“node-red-contrib-detect”节点完成连接和调试;调试好后录制视频时长1-2分钟,录制内容详见下表;视频命名成“加工检测09节点测试.mp4”,保存在“U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP。
节点测试录制内容要求
| 序号 |
内容 |
备注 |
|
| 1 |
注入消息 |
计算出时间差,时间差为最后一次注入的消息和第一次注入消息的时间差 |
|
| 2 |
清空数据 |
清空所有数据 |
|
3.生产节拍分析APP开发设计
(1)function节点添加要求
| 序号 |
function节点名称 |
备注 |
序号 |
function节点名称 |
备注 |
| 1 |
输出信号4 |
3 |
计时 |
||
| 2 |
输出信号5 |
4 |
复位 |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测10function节点添加.jpg
(2)其他节点添加要求
| 序号 |
节点类型 |
节点名称 |
备注 |
| 1 |
uibuilder |
detect |
|
| 2 |
Link in |
||
| 3 |
Link out |
截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测11其他节点添加.jpg
(3)节点连接
按照任务要求,将添加好的节点按逻辑规则连接起来,并将连接好的界面截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测12节点连接.jpg
(4)节点代码导入
- function节点代码导入
function节点代码路径:U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\function节点代码
| 序号 |
function节点 |
导入脚本 |
序号 |
function节点 |
导入脚本 |
| 1 |
输出信号4 |
输出信号4.txt |
3 |
计时 |
计时.txt |
| 2 |
输出信号5 |
输出信号5.txt |
4 |
复位 |
复位.txt |
将“输出信号1”节点代码导入截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测13function节点代码导入1.jpg
将“复位”节点代码导入截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测14function节点代码导入2.jpg
- uibuilder节点代码导入
将U:\工业互联网集成应用赛项(高职)\参考资料\模块B\任务七、加工检测生产节拍分析APP设计开发、分析优化\uibuilder界面文件\detect,复制粘贴到Node-red安装目录下的对应文件夹中(替换原来文件夹),完成后截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测15uibuilder节点代码导入.jpg
(5)界面修改及虚拟运行
- 添加“模拟开始时间”节点和“模拟结束时间”节点,替代MC Read 节点的信号输入,部署并打开detect,点击“模拟开始时间”观察detect的界面变化并截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测16模拟开始时间界面.jpg
- 点击“模拟结束时间”观察detect的界面变化并截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测17模拟结束时间界面.jpg
- 修改脚本调整detect的界面显示及功能,符合下列要求,脚本修改完成后,录制视频时长1-2分钟,录制内容需包括数据注入过程和detect界面变化情况;视频命名成“加工检测18APP虚拟运行.mp4”,保存在“U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP。
| 序号 |
内容 |
属性 |
属性值 |
| 1 |
一级标题 |
文本 |
加工检测生产节拍分析APP |
| 颜色 |
Red |
||
| 大小 |
H1标签默认大小 |
||
| 2 |
二级标题 |
文本 |
实时数据监控 |
| 颜色 |
aliceblue |
||
| 大小 |
20px |
||
| 3 |
指示灯 |
大小 |
100px*100px |
| 形状 |
圆 |
||
| 未运行颜色 |
#c1ce83 |
||
| 运行中颜色 |
#0dd30d |
||
| 运行结束颜色 |
#003c00 |
||
| 4 |
第四个单元标题 |
内容 |
料瓶拧盖 |
| 颜色 |
aliceblue |
||
| 大小 |
默认值 |
||
| 5 |
第五个单元标题 |
内容 |
成品检测 |
| 颜色 |
aliceblue |
||
| 大小 |
默认值 |
||
| 6 |
第十个单元标题 |
内容 |
总时长 |
| 颜色 |
aliceblue |
||
| 大小 |
默认值 |
||
| 7 |
单元文本要求 |
内容 |
开始时间:12:34:55 结束时间:12:34:58 工序耗时:3.216秒 |
| 要求 |
三行文本不能再同一行显示,没有时间时,就只显示文字 |
||
| 颜色 |
aliceblue |
||
| 大小 |
默认值 |
||
| 行高 |
34px |
||
| 8 |
系统时间 |
内容 |
2022/10/23 14:23:45 |
| 颜色 |
Orange |
||
| 大小 |
25px |
||
| 9 |
复位功能 |
内容 |
复位 |
| 点击效果 |
点击后弹窗提示复位中 |
||
| 字体颜色 |
默认 |
||
| 大小 |
默认 |
||
| 10 |
全局属性 |
大小 |
1600px*900px |
| 背景颜色 |
Rgb(15,15,64) |
4.生产节拍分析APP服务应用及运行监测
(1)部署运行
部署,并打开detect,将显示界面截图,保存在U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP,命名为:加工检测19部署运行.jpg
(2)接真实设备运行监测
将加工检测的真实数据接入,调试好后录制视频时长3-5分钟,录制内容需包括数据注入过程和detect界面变化情况;视频命名成“加工检测20APP真实运行.mp4”,保存在“U:\工业互联网集成应用赛项(高职)\第*场\第*号工位\加工检测生产节拍分析APP。