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What does the industrial control industry do

Industrial automation control
The industrial control industry, also known as industrial automation control, mainly utilizes electronic and electrical, mechanical, and software combinations to achieve automation, efficiency, precision, and controllability and visibility in factory production and manufacturing processes through computer technology, microelectronics technology, and electrical means. This field is a general term for tools involved in the detection and control of production processes, their electromechanical equipment, and process equipment, which have computer properties and characteristics, such as having a CPU, hard disk, memory, peripherals and connections, and equipped with real-time operating systems, control networks and protocols, computing power, and friendly human-machine interfaces.
The industrial control industry has a wide range of application scenarios, including factory automation (FA) and process automation (PA). Factory automation is mainly applied in discrete industries, such as textile machinery and packaging machinery, with a focus on precise control; And process automation mainly controls continuous variables, focusing on controlling stability, and is applied in industries such as metallurgy and chemical industry.


The functions of industrial control products can be mainly divided into three levels: control layer, driver layer, and execution layer. The control layer realizes the analysis, processing, and allocation of tasks; The driver layer decodes the tasks of the control layer into signals that can be recognized by motors, valves, etc; The execution layer executes the corresponding tasks.
The development of the industrial control industry is closely related to the manufacturing industry and has strong pro cyclical characteristics. With the increase in investment activities in the manufacturing industry, the demand in the industrial control industry has also grown. In addition, the industrial control industry is closely related to the macroeconomic operation, and the market size of industrial control products is greatly affected by economic fluctuations.
In summary, the industrial control industry improves the efficiency and quality of industrial production through automation technology, which is an important upstream industry in the manufacturing industry and plays a key role in promoting industrial modernization and intelligent development.

Regardless of physical condition, randomly supplement, the more supplement, the more deficiency!

With the rapid development of society, now everyone has some degree of illness!
The pressure of life is increasing, and the number of sub healthy people is also increasing. According to relevant data, only 5% of the world’s truly healthy population is in sub healthy state, and the total population in sub healthy state accounts for 75%.
Among them, the sub healthy population in China has already reached 70%, which means that more than 900 million Chinese people are in a sub healthy state. In order to maintain health, many people will use various methods to supplement.
However, if one starts to supplement without understanding their physical condition, it may have the opposite effect and make the body even weaker.
Images from the internet
Therefore, when we nourish and regulate our bodies in daily life, we must follow our own physical constitution.
The first step in health preservation: Identify physical constitution!
Physical constitution refers to the comprehensive and stable characteristics of the human body’s morphological structure, physiological functions, and psychological state displayed under the combined effects of innate genetics and acquired environment.
The Chinese Society of Traditional Chinese Medicine released the “Classification and Determination of Traditional Chinese Medicine Constitution” on March 26, 2009, which clearly stated that currently, the most authoritative classification of traditional Chinese medicine constitution is 9 types, including 1 mild constitution and 8 biased constitution.
The peaceful constitution represents a healthy physiological state, while the other eight biased constitutions – qi deficiency, yang deficiency, yin deficiency, phlegm dampness, damp heat, qi stagnation, blood stasis, and intrinsic qualities – are considered as manifestations of sub healthy states.
What are the manifestations of sub-health status? Sudden lack of energy, fatigue, lethargy, distraction, chest tightness, palpitations, insomnia, pain in various parts of the body, dizziness, menstrual disorders, and sexual dysfunction are common manifestations of sub-health.
It is not difficult to find in daily life that some people do not gain weight no matter how they eat, while others gain weight as soon as they eat; Some people are not afraid of cold or hot, while others often feel cold; Some people have delicate skin, while others have many skin problems.
The differences in these situations are actually closely related to an individual’s physical condition!
Traditional Chinese medicine identifies and divides a person’s physique based on their body shape, skin color, posture, speech and behavior, and their ability to adapt to the external environment.
If you want to have a healthy physique, the most crucial thing is to understand and determine your physical type, and then choose targeted and effective health plans that suit you, in order to effectively adjust your body condition and achieve the best health results.
This can not only effectively improve one’s health condition, but also achieve twice the result with half the effort in the process of health preservation.
If the body is sick, the tongue will first “report”
We have the most sensitive organ in our body, and almost all systemic diseases can be most intuitively reflected on this organ, which is the tongue.
By combining the tongue images of traditional Chinese medicine with various other body information, we can comprehensively judge and identify our physical constitution, which is the relatively stable inherent characteristic of each of us.
In history, many medical classics, such as “Su Wen”, can be treated with tongue to tongue conversion; The divine physician Hua Tuo died with his tongue curled black; The Golden Chamber states that the tongue can be lowered with yellow color; The Treatise on Cold Damage includes a white tongue with slippery coating and a dry and urgent tongue; The “Tongue Diagnosis and Correction” discusses that distinguishing the tongue is better than diagnosing the pulse, and also emphasizes the importance of tongue diagnosis.
In the diagnosis and treatment of traditional Chinese medicine, “tongue image” is an indispensable part, reflecting a person’s physical condition, such as cold and heat deficiency and excess, disease severity, qi and blood rise and fall, and disease location.
Modern instruments may not be able to detect various negative emotions in humans, but traditional Chinese medicine constitution identification can do so, and the biased state of various constitutions is actually the internal root of disease disorders.
Among them, tongue diagnosis is one of the most common and practical diagnostic and treatment methods in traditional Chinese medicine. It is not only simple and easy to implement, but also objectively and accurately reflects the condition, providing important basis for understanding the development and changes of diseases.
Tongue diagnosis is also an important component of the “four diagnostic methods” in traditional Chinese medicine. Doctors can use tongue diagnosis to diagnose symptoms and apply medication. If ordinary people can also master tongue observation, which is the most intuitive technique to show our physical health status, it will undoubtedly help prevent diseases and improve health levels.
Daily health can be regulated through traditional Chinese medicine!
Traditional Chinese medicine has a history of thousands of years, and its treatment methods are rich and diverse. The core treatment methods include eight methods: sweating, vomiting, descending, harmonizing, warming, clearing, dissipating, and tonifying.
As stated in “Medical Mind Enlightenment”: “When it comes to the reliance on diseases, the eight characters of cold, heat, deficiency, excess, exterior, interior, yin, and yang are used to unify them. When it comes to the prescription of diseases, the eight methods of sweating, vomiting, descending, harmonizing, warming, clearing, eliminating, and supplementing are used to complete them.”
It may also be known from the daily life of health preservation, treatment and recuperation that the methods of Chinese medicine recuperate the body mainly include acupuncture and moxibustion therapy, scraping therapy, massage therapy, Chinese medicine therapy, etc.
With a clear understanding of physical fitness and health status, targeted combination of one or more appropriate conditioning methods can maximize the therapeutic effect and efficiently and accurately regulate a healthy and comfortable living state.
Modern instruments may not be able to detect various negative emotions in humans, but traditional Chinese medicine constitution identification can do so, and the biased state of various constitutions is actually the internal root of disease disorders.
Among them, tongue diagnosis is one of the most common and practical diagnostic and treatment methods in traditional Chinese medicine. It is not only simple and easy to implement, but also objectively and accurately reflects the condition, providing important basis for understanding the development and changes of diseases.
Tongue diagnosis is also an important component of the “four diagnostic methods” in traditional Chinese medicine. Doctors can use tongue diagnosis to diagnose symptoms and apply medication. If ordinary people can also master tongue observation, which is the most intuitive technique to show our physical health status, it will undoubtedly help prevent diseases and improve health levels.
Daily health can be regulated through traditional Chinese medicine!

The Development History of Automation

in 946, D., a mechanical engineer at Ford Motor Company in the United States S. Harde first proposed the term “automation” and used it to describe the process of automatic transmission and machining of engine cylinders. In the 1950s, the development of automatic regulators and classical control theory led automation into a local automation stage dominated by single variable automatic regulation systems. In the 1960s, with the emergence of modern control theory and the promotion and application of electronic computers, automatic control and information processing were combined, bringing automation into the comprehensive automation stage of optimal control and management in the production process.
In the 1970s, the object of automation became large-scale, complex engineering and non engineering systems, involving many problems that were difficult to solve with modern control theory. The study of these issues has promoted innovation in the theory, methods, and means of automation, leading to the emergence of large-scale system control and intelligent control of complex systems. Advanced automation systems that comprehensively utilize achievements in computer, communication technology, system engineering, and artificial intelligence have emerged, such as flexible manufacturing systems, office automation, intelligent robots, expert systems, decision support systems, computer integrated manufacturing systems, etc.
The emergence and application of automatic devices dates back to the 18th century. The formation period of automation technology was from the late 18th century to the 1930s. In 1788, British mechanic J. Watt invented the centrifugal governor (also known as the flyball governor) and connected it to the valve of the steam engine to form a closed-loop automatic control system for the speed of the steam engine. Watt’s invention opened a new era in the application of modern automatic control devices and had a significant impact on the development of the first industrial revolution and later control theory. People have started to use automatic adjustment devices to address control issues raised in industrial production. These regulators are devices that track given values, keeping some physical quantities near the given values. The application of automatic regulators marks a new historical period for automation technology. After entering the 20th century, various automatic regulating devices were widely used in industrial production, promoting the analysis and comprehensive research of regulating systems. Although feedback control structures were widely used in automatic regulators during this period, theoretical research on the principles of feedback control began in the 1920s. In 1833, British mathematician C. Babbage first proposed the principle of program control when designing analytical machines. In 1939, the world’s first group of professional research institutions on systems and control were established, which made theoretical and organizational preparations for the formation of classical control theory and the development of local automation in the 1940s.


The 1940s to 1950s were the period of local automation, and the classic control theory formed during the Second World War played an important role in promoting the development of local automation after the war. In the process of solving the problem, classical control theory was formed, and various precision automatic adjustment devices were designed, opening up a new scientific field of systems and control. This new discipline was called servo mechanism theory in the United States at the time and automatic adjustment theory in the Soviet Union, mainly aimed at solving single variable control problems. The name classical control theory was proposed at the first United States Joint Conference on Automatic Control in 1960. After 1945, due to the lifting of the wartime publishing ban, there were works that systematically expounded classical control theory. In 1945, American mathematician Wiener N. extended the concept of feedback to all control systems. After the 1950s, there were many new developments in classical control theory.. The methods of classical control theory can basically meet the needs of military technology during World War II and the needs of post-war industrial development. But by the late 1950s, it was discovered that applying the methods of classical control theory to multivariable systems would lead to incorrect conclusions. The methods of classical control theory have their limitations.
The invention of electronic digital computers in the mid-1940s ushered in a new era of digital program control. Although it was still limited to automatic computing at that time, the successful manufacturing of ENIAC and EDVAC opened up a new era of electronic digital program control. The invention of electronic digital computers laid the foundation for the widespread application of program control and logic control in control systems in the 1960s and 1970s, as well as the widespread use of electronic digital computers to directly control production processes.
Since the late 1950s, it has been a period of comprehensive automation, during which space technology has developed rapidly and there is an urgent need to solve the optimal control problem of multivariable systems. So modern control theory was born. The formation and development of modern control theory have laid the theoretical foundation for comprehensive automation. At the same time, microelectronics technology has made new breakthroughs. Transistor computers emerged in 1958, integrated circuit computers emerged in 1965, and single-chip microprocessors emerged in 1971. The emergence of microprocessors has had a significant impact on control technology, and control engineers can easily use microprocessors to achieve various complex controls, making comprehensive automation a reality. “Automation” is an American D S. Harder proposed in 1936 that in a production process, the transfer of parts between machines does not require human handling, which is called “automation”.
On February 25, 2022, Hunan Huada Dana Intelligent Manufacturing Technology Co., Ltd. produced the first integrated automated nucleic acid testing laboratory in the province, which was launched in the eastern industrial park of Yiyang High tech Zone.

ABB Talent Growth and R&D Development

Talent: Local Growth
ABB values the cultivation of local talents and actively creates favorable development opportunities for its employees. In 2003, ABB was named one of the top 10 “Excellent Employers” in China in a survey conducted jointly by media outlets such as Fortune and Yahoo. In early 2006, ABB was named one of the most popular employers by college students in a survey organized by 51job website. In 2009, ABB was selected as one of the “Top 10 Best Employers in the Energy/Electrical/Chemical Industry” in the 7th China University Student Best Employer Survey initiated by China Talent Network, becoming the most popular job seeking enterprise among Chinese university students. In 2013, ABB was selected as one of the most ethical companies in the world. In 2012, researchers from ABB Group’s China Research Institute were also awarded the “Capital Labor Medal” by the Beijing Federation of Trade Unions.


R&D: Local development
ABB adheres to the development strategy of “in China, for China and the world”, promotes the localization of technology research and development, and continuously improves local research and innovation capabilities through continuous investment and optimization of research and development layout. In 2005, ABB established one of the seven global research and development centers in China. ABB China’s R&D team has made a series of R&D achievements, developing the smallest robot IRB 120 “Chinese Loong”, the world’s fastest stacking robot IRB 460, door opening robots and welding robots used in the automobile manufacturing industry, the award-winning “Mingyue” intelligent building intercom system, and future oriented products such as compact gas insulated switchgear ZX1.5-R SP, TEC ST smart transformer, 550 kV gas insulated switchgear, and ring network cabinets that can be applied to 90% of China’s high-altitude areas. In 2012, the first ± 800kV high-voltage direct current transformer manufactured by ABB Chongqing passed testing and began offline production, which is currently the highest voltage level transformer product produced by ABB in China; At the same time, ABB has closely cooperated with State Grid to successfully develop ± 1100 kV converter transformers, continuously achieving milestone breakthroughs in the field of ultra-high voltage direct current research and development.
With globally leading product technology and solutions, ABB actively helps domestic customers increase efficiency and energy conservation, and promotes the development of renewable resources, contributing its own strength to achieving China’s green and eco-friendly sustainable development. Over the past 10 years, ABB has provided domestic customers with frequency converters that have saved 157 billion kilowatt hours of electricity, equivalent to the annual electricity consumption of 56 million households; ABB’s high-efficiency motor products only helped domestic customers save 240 million kilowatt hours of electricity in 2012, equivalent to reducing 200000 tons of carbon dioxide emissions. At the same time, ABB provides leading converters, generators, substations, and battery energy storage facilities for major domestic projects such as onshore wind farms and offshore intertidal wind farms, helping China build a globally leading green power grid.

ABB’s development history

The relationship between ABB and China can be traced back to 1907 at the beginning of the last century. At that time, ABB provided China with the first steam boiler. In 1974, ABB established its China business unit in Hong Kong and established an office in Beijing in 1979. In 1992, ABB invested and established its first joint venture in Xiamen. In 1994, ABB relocated its headquarters in China to Beijing and officially registered its investment holding company, ABB (China) Co., Ltd., in 1995.
After years of rapid development, ABB has established 36 enterprises in China and sales and service branches and offices in 90 cities. It has a comprehensive business of research and development, production, engineering, sales and services, and approximately 19000 employees. In 2012, ABB’s sales revenue in China exceeded 5.2 billion US dollars, maintaining ABB Group’s position as the world’s second largest market.
ABB has established strong production, engineering, and service bases in areas such as power transmission and distribution, automation products, and systems through close cooperation with local partners in China. The business includes a complete series of power transformers and distribution transformers; Application of high, medium, and low voltage switches; Electrical transmission system and motor, etc. These products have been widely used in industry, commerce, electricity, and public utilities.

Driven by ABB China’s strategic initiatives, its service business has maintained a strong upward trend, with sales revenue and order volume both achieving nearly 15% growth. In 2012, ABB built three new service centers in Suzhou, Nanjing, and Guangzhou to further connect with customers.
In 2012, ABB launched two industrial robots and leading solutions to further expand its product portfolio. ABB robots are not only widely used in traditional automotive industry, but also continuously expanding new applications in fields such as 3C, food and beverage, medicine, and feed processing. ABB robots not only help domestic customers improve production efficiency and reduce operating costs by up to 50%, but also liberate workers from intensive and repetitive physical labor, while significantly improving product quality.
On March 6, 2013, ABB announced its business performance in China for 2012, with stable growth in sales revenue exceeding 5.2 billion US dollars. This performance was mainly due to the increase in market demand for improving domestic manufacturing and infrastructure construction, as well as the sustained growth of ABB’s export business.

Application of automated robotic arms and automated production lines in various industries of the national economy

1. Diversification of raw materials
The first major category is the mechanical manufacturing industry, which includes the processing of durable consumer goods such as clocks, sewing machines, bicycles, and household appliances using metal materials as raw materials. The second category is based on non-metallic materials such as agriculture, forestry, animal husbandry, sidelines, and chemical products as raw materials for processing. For example, pastry machinery in food machinery mainly uses agricultural products as raw materials; Canning and brewing machinery mainly use agricultural and sideline products as processing materials; Pulp and paper machinery uses forest products and agricultural by-products as raw materials; Leather machinery mainly uses livestock products as raw materials; Ceramics, glass, and plastic machinery use minerals and chemical products as their raw materials. It indicates that automated robotic arms and automated production lines are widely used in various fields.
2. Diverse types of automated robotic arms and automated production line processes;
(1) Metal cutting and assembly are used to complete mechanical functions.
(2) Tobacco is the one that completes physical functions.
(3) Fermentation is the process that completes biochemical reactions.
(4) Electroplating and corrosion are the processes that complete electrochemical reactions.
(5) The processes that complete chemical reactions include cooking in papermaking machinery and melting in light bulb machinery.
3. Diverse categories and diverse structures
There are many industrial categories, and the machinery used varies greatly in terms of principles and motion mechanisms due to different industries, processed products, functions, and functions. Even those that perform the same function may have different working principles and mechanisms. If different equipment can be used to process the same product on a mechanical processing production line, the automated robotic arm applied to it may also differ from the automated production line; Candy packaging machines have various different process principles and structures; The light bulb winding machine can be divided into non core, continuous with core, and discontinuous with core winding machines due to different process principles.
4. Large product volume and high degree of automation
Industrial products are essential for people’s daily lives, and therefore require mass production, which inevitably requires the widespread use of semi-automatic and automated robotic arms. As a result, the application of automated production lines is becoming increasingly widespread.
5. Industrial automation robotic arms often have characteristics such as complex movements, high mechanism movement speed, wide range of disciplines, and fast updates.
Fold and edit the composition structure of this paragraph


The automated robotic arm consists of five main parts:
Drive system: It is the power source of an automatic robotic arm, which can be electric motor drive, hydraulic drive, pneumatic drive, etc.
Transmission system: Its function is to transmit motion and power to various executing mechanisms to complete the process operations of automated robotic arms, while also transmitting motion to auxiliary mechanisms to complete auxiliary actions. This includes belt drive, gear drive mechanism, etc.
Execution mechanism: It is the part that realizes automated and auxiliary operations, and its action sequence and motion law are determined by the process principles and requirements.
Control system: Its function is to control the driving system, transmission system, and execution mechanism of the machine, allocate motion to each execution mechanism, and make them coordinate actions on time and in sequence.
Detection system: Its function is to detect the position, stroke, speed, pressure, flow rate, etc. of the automated robotic arm and provide feedback to the control system.
The development direction of folding and editing this paragraph
With the rapid development of China’s national economy and industry, the variety, scale, design and manufacturing technology of industrial automation robots have also been rapidly developed and improved. It has become an inevitable trend to independently design and manufacture from single machines to complete sets of equipment and even automatic production lines.
With the development of new materials, processes, and technologies, various automated robotic arms are rapidly advancing towards mechatronics and intelligence.
Mechatronics integration is the result of various technologies permeating each other, and its main related technologies can be summarized into six aspects: mechanical technology, detection and sensing technology, information processing technology, automatic control technology, servo transmission technology, and overall system technology.

Introduction to Electrical Automation

In 1908, Tang Wenzhi, the then president of the Shanghai Higher Industrial School (now Jiaotong University) under the Ministry of Posts and Communications, adjusted the departmental structure. We have successively added railway and electrical engineering majors with a three-year education system, marking the beginning of higher education in electrical engineering in China. This is the earliest electrical engineering major. With the development of electricity and the need for social division of labor, Jiaotong University changed its Electrical Engineering Department to Electrical Machinery Department in 1913. In 1917, the Electrical Machinery Department began to establish wireless switches. In 1928, it was changed to the School of Electrical Engineering, and in 1937, it was changed to a department, divided into “Power Gate” and “Telecommunications Gate”, namely “Strong Electric” and “Weak Electric”.
In 1912, Tongji Medical and Engineering School (now Tongji University) established the Department of Electrical Engineering, which has now developed into the Department of Electrical Engineering of the School of Electronic and Information Engineering at Tongji University; In 1920, the Public Industrial Specialized School (now Zhejiang University) established the Department of Electrical Engineering, which has now developed into the School of Electrical Engineering at Zhejiang University; In 1923, the Department of Electrical Engineering was established at Central University (now Southeast University); In 1932, Tsinghua University established the Department of Electrical Engineering, which has now developed into the Department of Electrical Engineering and Applied Electronic Technology; In 1933, the Department of Electrical Engineering was established at Beiyang University (now Tianjin University), which has now developed into the School of Electrical and Automation Engineering at Tianjin University.


In 1952, China underwent a large-scale departmental adjustment, leading to the emergence of a group of multidisciplinary universities with engineering as the main focus, as well as a group of mechanical and electrical colleges. These colleges basically established departments of electrical engineering or power engineering.
In 1977, after the restoration of the college entrance examination system, most universities gradually changed their “Department of Electrical Engineering” or “Department of Electric Power Engineering” to “Department of Electrical Engineering”. After the 1990s, it was gradually renamed as the School of Electrical Engineering.
In 1993, in the catalog of undergraduate majors in ordinary higher education institutions issued by the Ministry of Education, electrical related majors in the engineering category were divided into two branches: electrical engineering and electronics and information. Electrical engineering includes five majors: motor and electrical appliances and their control, power system and its automation, high voltage and insulation technology, industrial automation, and electrical technology.
In 1998, the Ministry of Education issued the “Catalogue of Undergraduate Majors in Ordinary Higher Education Institutions (1998)”, which merged electrical engineering and electronics and information into electrical information. The original 19 majors were merged into 7. Among them, the majors of motor and electrical appliances and their control, power system and its automation, high voltage and insulation technology, and electrical technology in the original electrical engineering category have been merged into the majors of electrical engineering and its automation.
In 2012, the Ministry of Education issued the “Catalogue of Undergraduate Majors in Ordinary Higher Education Institutions (2012)”, which merged the original Electrical Engineering and Automation major with the Electrical Engineering and Automation, Electrical Information Engineering, Power Engineering and Management, Electrical Technology Education, and Intelligent Electrical Machinery and Electrical Appliances special majors to form the Electrical Engineering and Automation major.

Omron: The i-Automation of Scholar Technical Experts! Evolutionary theory

In 2015, Omron innovatively proposed a new intelligent manufacturing concept, i-Automation!. As a result, this innovation storm instigated by Omron extends step by step from the “manufacturing site” and leverages the future of innovative automation. Specialization and innovation have become i-Automation! A solid footnote to success.
By 2020, we will be confronted with the COVID-19 that has swept the world. The increasing geopolitical friction will make the global economic atmosphere more tense. Under the superposition of various uncertainties, what made Omron achieve offensive growth in the first half of the year? I-Automation! What new chapters have been added to the theory of evolution?
On August 31, 2020, Omron Automation (China) Co., Ltd. President Hiroshi Ohashi and Gongkong ® President Pan Yingzhang practices the annual agreement between the two parties through cloud based dialogue and reveals the answers to the above puzzles.

According to the Nikkei Chinese website on August 20, the real gross domestic product (GDP) of 24 major countries in the world from April to June 2020 shrank by 9.1% year on year, and the impact of the COVID-19 epidemic is very prominent. These 24 countries account for two-thirds of the world’s GDP, with only China achieving positive growth.
Faced with this sudden stress test, Omron shifted from passive defense to active attack and defense. “According to our investigation, customers were greatly affected after the Spring Festival, and by mid March, their production activities had resumed by 50-70%,” said Da Chang Hezhi.
According to Da Chang Hezhi, Omron’s performance in the second quarter of this year was impressive: a 70% increase compared to the first quarter and a 20% increase compared to the same period last year.
He believes that there are three main reasons: firstly, in the first quarter, due to the impact of the epidemic, everyone was in a wait-and-see state, and project investment was temporarily postponed. After April, the investment direction became clearer; Secondly, medical supplies such as masks, artificial ventilators, and non-contact thermometers have become a “hard currency” in the market, and the demand for such equipment has surged. Omron has achieved considerable success in the essential goods market; Thirdly, after April, the suspended customer demand was rapidly released, and the demand for components increased rapidly. Omron had anticipated this trend and prepared inventory in advance, resulting in an improvement in IAB (Industrial Automation Business) performance.
“In summary, this epidemic means more opportunities for Omron,” said Da Chang Hezhi. For example, the market for essential goods such as medical supplies is an area that Omron (IAB) has not been involved in in the past; For example, more customers are cross-border producers of mask machines and urgently need Omron to provide them with supporting solutions and products.
How to respond quickly and seize opportunities is crucial. On the one hand, Omron timely learns about customer needs, disassembles them into corresponding supply products, prepares in advance, and actively responds; On the other hand, overseas markets such as the United States, Europe, and Japan have been affected by the epidemic and have stopped production, while Omron has already resumed work and production in China, and can actively and timely respond to the needs of overseas customers. At the same time, Omron also organized and analyzed the impact and changes of the epidemic on customer production sites and work itself, actively thinking about i-Automation! How to empower customers and turn challenges into more opportunities.
For the future development of the industrial automation market, Da Chang He Zhi still maintains an optimistic attitude. At present, Omron is optimistic about the secondary battery, food and beverage, semiconductor and other industry markets.
I-Automation! Diexin
Visualization is required at the manufacturing site
The methodologies for intelligent manufacturing in Japan and China are not the same. Da Chang Hezhi stated that “Made in China” promotes practical operations through concepts, anticipates the concepts of informatization, digitization, and intelligence, and then gradually implements them on manufacturing sites. “The Japanese manufacturing industry does not place too much emphasis on the concepts of informatization, digitization, and intelligence, but focuses on optimizing and improving every detail of the manufacturing site.”
From i-Automation! From the birth of concepts to the gradual implementation and upgrading of integrated (control evolution), intelligent (intelligence), and interactive (new human-machine cooperation) in manufacturing sites, Omron is more concerned with how to help customers solve practical problems, innovate manufacturing sites, and innovate the future of automation.

Building a modern factory has become a mainstream demand at present, but Da Chang He Zhi directly points to customers’ “misconceptions”. “Building a modern factory is not just about achieving informatization and intelligence. Omron believes that improving production efficiency and product quality on the manufacturing site, reducing energy consumption, and visualizing is the first step.”
At the upcoming 22nd China International Industrial Expo (CIIE), Omron will showcase intelligent unit production lines featuring human-machine collaboration. This production line integrates advanced technologies unique to Omron such as AI, IoT, MOMA ※, and collaborative robots. Based on big data analysis, it is actually applied in Omron’s own factory’s near future production management system.

By visualizing the management of homework and process status, Omron creates a self disciplined production site, reducing talent training time by half; Through traceability management, the defect outflow rate caused by manual operation errors is reduced to 0; By leveraging the advantages of both humans and robots and improving automation levels, production efficiency can be doubled.

Yaskawa Electric, Motor, E-Learning

YASKAWA takes pride in its sports technology, which serves as a platform in the global industrial sector and contributes to improving the added value of machinery. Since its launch in 1997, the MP series of machine controllers has been continuously improving in order to address issues such as high-speed and precise control of machinery and devices at a higher level, improving production efficiency by shortening interval times, reducing costs by simplifying systems, and solving system visualization.
YASKAWA takes pride in its sports technology, which serves as a platform in the global industrial sector and contributes to improving the added value of machinery. Since its launch in 1997, the MP series of machine controllers has been continuously improving in order to address issues such as high-speed and precise control of machinery and devices at a higher level, improving production efficiency by shortening interval times, reducing costs by simplifying systems, and solving system visualization.

As a successor to the MP2000 series, the Yaskawa Machine Controller MP3300 has a synchronous scanning speed of up to 0.125ms. MP3300 provides a system solution based on the concept of “solving FA device problems, balancing environment and energy conservation”. It can be combined with various network basic units, CPU modules, and optional machine controllers according to the user’s control scale and control cabinet specifications.

Since its launch, YASKAWA’s MP3000 series of machine controllers have been trusted by customers for their high-performance motion control and stable quality.
The MP3200, which is mainly characterized by controlling the number of axes and high data communication, is the core product of this series. In order to meet the needs of high-speed and high-performance equipment, as well as cost reduction and efficiency improvement in industries such as semiconductor production and electronic component assembly, YASKAWA has successively released CPU units CPU-201 and CPU-202 for use with M3200.

In recent years, in addition to high-speed control performance, the market’s demand for high-speed data communication that can control more axes and peripheral device data is still increasing. For this reason, YASKAWA has also launched CPU-203. This CPU unit is equipped with multiple Gigabit Ethernet ports while improving program execution performance, and has been widely praised in the market.
On the basis of CPU-203, YASKAWA has developed a new CPU-203F that supports the next-generation industrial network MECHATROLINK-4 (100Mbps) communication. Compared to the previous MECHATROLINK-III, the newly launched MECHATROLINK-4 has increased its transmission efficiency by four times. Therefore, while CPU-203F achieves high-speed communication, the number of axes that CPU-203F can control increases without optional modules. CPU-203F unit and YASKAWA Σ- The combination of X series drives can significantly improve the performance of customer devices.

Product features of CPU-203F
1. Improved sports processing performance
Equipped with four MECHATROLINK-4 communication processors, MECHATROLINK-4 communication processing can be executed in parallel. Supports a transmission cycle of 62.5 Å and increases the number of axes controlled for each transmission cycle. Without optional modules, up to 256 axis servo can be controlled.
2. Improvement of ladder diagram programming performance
Adopting multi-core high-speed processors. It can optimize the processing capabilities of each core and improve the execution and processing capabilities of ladder programs.
3. Standard with 2 Gigabit Ethernet ports
Two ports can be used as information type data processing (universal Ethernet) ports and control type data processing (EtherNET/IP) ports respectively, achieving high-speed communication through parallel means.

Schneider Electric and Jinrong Tianyu signed a service cooperation agreement

Schneider Electric, a Digital transformation expert in the field of global energy management and automation, and Tianjin Jinrong Tianyu Precision Machinery Co., Ltd. (hereinafter referred to as “Jinrong Tianyu”) officially signed the Service Cooperation Agreement. Both parties agree to further engage in in-depth exchanges around supply chain, digital factories, intelligent manufacturing, sustainable development, and other fields on the basis of providing a one-stop digital solution for smart energy systems, and work together to innovate to create a win-win and sustainable partnership. Zhang Kaipeng, senior vice president of Schneider Electric and head of the global supply chain in China, Li Jimin, vice president of Schneider Electric in China and head of the national sales department’s industrial sales and development department, Sun Xingwen, chairman of Jin Rongtianyu, Zhao Hong, president of Jin Rongtianyu, and Xiao Yunzhi, vice president of Jin Rongtianyu, attended the signing ceremony.
Sun Xingwen, chairman of Jinrong Tianyu, said: “This signing activity marks that Schneider Electric has helped Jinrong Tianyu enter a new stage of zero carbon transformation and sustainable development, and Jinrong Tianyu will usher in new opportunities for green and high-quality development.”

The manufacturing industry is the mainstay of China’s national economy. The green development and transformation and upgrading of manufacturing enterprises are crucial for the realization of China’s economy and the “dual carbon” goals. And digital technology can help manufacturing enterprises more effectively improve energy efficiency and achieve green and low-carbon production goals.
Jinrong Tianyu is a high-tech enterprise focusing on the research, development, production and sales of precision metal parts and energy storage products in the whole industrial chain technology, and has maintained a long-term friendly cooperation relationship with Schneider Electric. Through this signing, Schneider Electric will further promote the development level of informatization and intellectualization of equipment and facilities in Jinrong Tianyu Plant, enrich its energy consumption management means in the plant, improve equipment energy consumption supervision ability, practically meet the demand for safe production guarantee such as prediction, early warning and pretreatment of electrical equipment, and achieve economic benefits and reflect social benefits while ensuring energy conservation and consumption reduction.
In the future cooperation process, both parties promise to continue to cooperate around the application and innovation of Schneider Electric’s medium and low voltage products, as well as equipment energy consumption management, life cycle management, safe operation management, informatization and digital operation and maintenance solutions, and jointly establish digital integrated solutions, improve the convenience, safety, energy efficiency and intelligence of Jinrong Tianyu’s operation and management, and achieve the goal of cost reduction and efficiency increase; And will further expand the field of technical cooperation, exploring the use of EcoStruxure ™ A feasible solution for platform application, analysis, and service level cooperation. In addition, Schneider Electric will also provide one-stop overall solutions for Jinrong Tianyu and other overseas factory subsidiaries nationwide, and continue to track the construction of Jinrong smart energy management system, provide advice and guidance for them, and help the “double carbon” construction.
Zhao Hong, President of Jinrong Tianyu, said, “Based on the cooperation between the two sides in the field of carbon reduction, Jinrong Tianyu has gained new grip on lean digitization, energy conservation and emission reduction, and sustainable development. Both sides will establish a long-term communication mechanism, output tangible carbon reduction results, and assume corporate social responsibility

As one of the first partners to join Schneider Electric’s “Master of Carbon Reduction” project, Jin Rong Tianyu has cooperated with Schneider Electric for more than 20 years. Schneider Electric has helped Jin Rong Tianyu grow all the way from the aspects of training, hand in hand support for key projects and technical support. By the end of 2022, the company’s carbon emission reduction per billion yuan of sales has decreased by 22.2%, Its smart energy system project has also been successfully selected as a successful case of Schneider Electric’s “carbon reduction master” plan, and has worked with Schneider Electric to promote the joint construction of a broader sustainable ecosystem.
Senior Vice President of Schneider Electric Zhang Kaipeng, the head of global supply chain in China, said: “As an active promoter of energy transformation and power system innovation, Schneider Electric looks forward to working hand in hand with Jinrong Tianyu in the future to deepen cooperation and development between the two sides in supply chain cooperation, digital factory, intelligent manufacturing, sustainable development and other fields, enhance strategic mutual trust, seek innovation and win-win, explore a green development path for more manufacturing enterprises, and inject more power into the construction of new smart energy systems.”

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