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The rise of the equipment manufacturing industry is an important support for China's industrial modernization and the improvement of the country's overall national strength. On the one hand, manufacturing progress enhances material production capacity and solves the problem of manufacturing key equipment. On the other hand, the common technology of military and civilian use in manufacturing is of great significance to national defense and national security. CNC technology is a key technology group supporting modern equipment manufacturing industry. It directly determines the function and performance of manufacturing equipment. It is the key technology for informationization to drive the equipment layer in the industrialization process, and belongs to the important basic technology group supporting advanced manufacturing technology. Moreover, the numerical control technology is characterized by high-precision follow-up control and multi-motion coordinated control. It has common technical foundations with automatic artillery control, radar control and gyro navigation control technology, and has typical application characteristics of military and civilian.
1. The international competition environment curbs the rise of China's numerical control technology
It is precisely because of the characteristics of dual-use CNC technology, the international competition environment has obvious intention to curb the rise of China's numerical control technology. From the "Batumi" to the technical blockade stage of the Cox report, to the establishment of factories through joint ventures, local production, low-end product dumping, and the independent research and development of China's domestic research and development forces can reflect the intention to contain. Quite a number of facts prove that we are trying to introduce the technology, the good intention of "changing technology with the market" is just wishful thinking. The result is often that the market is lost, but the technology has not been exchanged. At present, the controller giants headed by Japan FANUC and SIEMENS monopolize more than 80% of the products, and high-end products not only monopolize but also restrict Chinese imports. Through nearly 20 years of continuous technological research and market cultivation, China has created a number of CNC manufacturers, opening up the situation in the low-end market and forming a certain market scale; but in the technology-intensive mid-to-high-end controller market, the scale of domestic controllers Always in a compressed state, profit margins are compressed, and R&D systems cannot support sustainable technological advances.
Industry experts admit that "the level of China's CNC machine tools and the world's developed countries are at least 15 years." Japanese international economics parent Tanikawa Taro, published an article entitled "China's future depends on Japan" in the May 2005 issue of Japan's "Huasheng". According to the article, in the automobile manufacturing industry, the average working time of machine tools for producing auto parts is as high as 3,500 hours, and only Japanese-made machine tools can guarantee the performance for five consecutive years. "Without Japan's machine tools, China's auto industry will be difficult to move." Hasegawa Kyotaro predicts that China’s dependence on Japan will only grow stronger and will not weaken. This means that "Japan is increasingly capable of controlling China." Objectively analyzing this article and abandoning the arrogant mentality of a few Japanese scholars, the article's point of view is that it should arouse our sense of urgency in terms of the gap between the key components of the manufacturing equipment and the products in the equipment manufacturing industry.
2. CNC technology has technical conditions and industrial conditions for breakthrough containment
Breaking the foreign main means of curbing our CNC technology is to reduce the dependence on foreign technology, choose the key technology with technical support conditions as a breakthrough, and take the initiative to break through, in order to win the initiative in the competition. With the support of computer hardware and software technology and communication technology advancement in the past decade, CNC technology has the key technology breakthrough conditions. From the perspective of industry, the basic characteristics of CNC controller products can be summarized as dedicated industrial computers; the characteristics of servo drive system products are industrial power supplies for driving motors; the characteristics of servo motor products are high with high-precision position feedback originals. Precision motor. In view of these product characteristics, from the industrial point of view, China is fully equipped with high-end CNC system industry conditions, and some products with similar industrial characteristics are world-leading. Therefore, jumping out of the narrow sense of motion controller manufacturing, from the perspective of China's industry as a whole, the CNC system industry breakthrough is industrial support conditions. Another feature of the CNC system industry is the softwareization of technology. Software running on digital controllers and servo drives carries the main functions and performance of the system. Therefore, competition in this industry will be more transformed into an intellectual level competition based on software technology, control technology and manufacturing technology, and an engineering level competition characterized by technology integration.
3. The key to breakthrough technology containment is to establish an independent innovation platform suitable for the growth of core technology systems.
The key to anti-containment is to build an independent innovation platform suitable for the growth of core technology systems, from passive technology catch-up to active technology confrontation. High-end CNC technology is not only a problem of controllers, but a group of technical disciplines related to motor, drive, measurement, communication, computer hardware and software technology, and machine tool testing and simulation. These technical aspects will have an impact on the final device control effect.
This problem is illustrated by taking high-speed, high-precision, high-response motion control as an example. From the material published by FANUC, the control resolution is increased to nanometer to double the precision of the processed product and double the surface quality. But this result requires a comprehensive technical upgrade of the controller. For the implementation of high-speed motion control technology, motion trajectory analysis and prediction based on the advance read mechanism is required. This mechanism will place higher demands on the architecture of the system. Trajectory smoothing and jerk control are all necessary techniques to avoid shocks in high-speed motion control. The calculation accuracy of the interpolator should be increased from 1 um to 1 nm, the calculation word length should be increased by three digits, and the effective calculation accuracy should be increased by three orders of magnitude. The software platform must support the calculation of the corresponding word length. On the other hand, the control of the beat also needs to be improved accordingly, otherwise the accuracy of the simple command is not meaningful. This of course has a higher demand for the computing load of the system, and the system hardware platform must have a higher speed. It is not enough to implement this resolution only in the controller, and this control amount is also sent to the servo drive. Due to the expansion of the effective word length, the control beat is improved, and the demand for the corresponding communication generation width is also increased. The servo communication problem must be digital, and the pulse mode and analog plus position pulse feedback cannot meet the requirements. On the servo side, it is clear that a higher precision control problem is to be pursued. The first is the need for a more accurate position feedback original. At present, the international high-precision servo device sensor has been upgraded to 2 million lines - 4 million lines, in order to cooperate with existing mechanical devices to achieve nano-scale control. Most of the sensors in our domestic controller products are around 2000 or 2500. The gap in this sensing technology directly leads to the speed regulation of our drive units, and the speed stability is different. Another problem with high-resolution sensors is the sensor interface problem. Obviously, this type of resolution cannot be interfaced with an AB pulse. A high-speed digital communication protocol that ensures simultaneous sampling of the controller is a problem that must be solved. The problem of high precision control of the servo itself is also a problem that must be solved. FANUC emphasizes HRV (High Response Vector Control), and Mitsubishi emphasizes that OMR (Optimized Mechanical Response Control) directly points to the core problem of high-precision servo control. High-precision, fast-responding current loop design. Only good current loop characteristics can lay the foundation for good speed control and position control. Many control techniques can make a difference in the process of solving this core contradiction, including various state recognition, synovial control and variable parameter control.
To achieve high-precision control, it is not enough to rely solely on the controller and servo drive. Motor design itself is an important factor that directly affects the effects of motion control. For a permanent magnet synchronous servo motor, a good back EMF positive rotation, a small cogging force will be very beneficial to the servo drive to achieve low speed smooth control. Many manufacturers of high-precision drive devices are themselves motor manufacturers. In many domestic research institutions, motor technology and servo drive technology are separated by departments, and some even do not have motor technology support for servo drives. In the study of high-precision motion control, simulation technology will greatly shorten the time and implementation cost of our research in control algorithms. While supporting the simulation technology, it is also necessary to develop a test platform to evaluate the effects of motion control and evaluate the performance of servo drives and motors. For example, how to evaluate low speed stationarity and stiffness.
The high-speed high-precision motion control technology is taken as an example to illustrate that the high-end controller technology is a closely coupled technical discipline group. As a high-tech numerical control technology innovation system should have the integrity of the technology chain, so we call this technology innovation system a "technical innovation platform." The investment in the construction of such a technological innovation platform is enormous. Take Japan FANUC as an example, staying ahead in technology and ranking first in the world in terms of output. The company has 3,674 employees, more than 600 researchers, and 7,000 sets of monthly production capacity. Sales account for 50% of the world market. R&D investment is 10% of sales, and annual research and development costs are hundreds of millions of dollars. Obviously, supporting the above platforms is very difficult to rely on a company or unit under the existing research conditions in China. We can only integrate technological resources through the integration of technical resources, including the institutions of higher learning and other research institutions, with the industrial chain and technology linkages, to form a new type of industry-university-research innovation organization, which is realized under the relevant national policy support and guidance. It is possible to achieve technological leapfrogging with an innovative technology platform that is closely coupled with multiple technologies.
4. Grasping the development trend of CNC core technology
Make full use of the new technology in the field of general technology, grasp the development trend of CNC core technology, and do something about it. The Chinese equipment controller industry in the backward competition state must make full use of new technical means, grasp the development direction of numerical control technology, and do something according to its actual situation, forming a late-comer advantage and accelerating the pace of technological progress. In order to achieve catching up and crossing.
First of all, we need to clarify the development direction of China's CNC technology needs. We can be inspired by the direction of SIEMENS CNC system export restrictions to China. Most of these functions are considered to directly affect the function of the core competitiveness of European equipment.
The CNC system of SIEMENS is divided into export type and standard type. A large number of functional groups are restricted in the export type. Non-EU users purchasing these functions require official approval from Germany or the European Union.
Analysis of the above functions can summarize several important technical directions of high-end controllers:
Control technology for complex motion laws. The "spiral interpolation 2D+6", "5-axis machining package", and "multi-axis interpolation (4 axes)" in the above table all belong to this technical direction. The motion control of complex profiles and curves belongs to the basic technology in the numerical control foundation, and is also the actual demand for the process equipment. In particular, the five-axis machining control technology is the basic support technology for complex surface machining. This technology is a key technology related to aerospace manufacturing, weaponry manufacturing, and power equipment manufacturing.
Multi-axis coupling relationship motion control. “Handling (robot) conversion package†in the above table, “1D3D gap control in position control loopâ€, “overhang compensation, multi-dimensionalâ€, “active numerical coupling and curve list interpolationâ€, “electronic gear unitâ€, “ The continuous correction" and "measurement level 2" all reflect the above characteristics. The common feature of the above functions is that a coordinate axis motion is no longer performed by the planned trajectory, but has some coupling or synergistic relationship with the motion or logic of other axes, that is, the real-time interpolation process also introduces other control factors. The above functions are obviously necessary for complex equipment and are an important supplement to the classical interpolation motion control. Open structure. The "open architecture NC core compilation loop" and "synchronous operation" in the above table belong to this technical direction. The "Open Architecture NC Core Compilation Cycle" engine allows users to add their own control functions to the system and execute them periodically according to the specified execution frequency. The "synchronous operation" is that the user stipulates execution conditions and execution actions in the form of a high-level language. These two functions respectively reflect the opening of different levels of the control system, one is the opening of the execution engine, and the other is the opening of the user language level. This type of technology is obviously beneficial to the rapid response process requirements of the OEM, integrating its own proprietary technology into the controller, and secondary development of its own unique controller, greatly expanding the control capabilities of the controller.
Integration with servo control technology. The "internal drive variable evaluation" in the above table belongs to this technical direction. The performance of the servo drive directly affects the control performance of the entire CNC system and the performance of the entire equipment. Therefore, servo drive related technology has become an important foundation for the high-end controller technology group. Due to the characteristics of the servo drive embedded system, the limitation of computing resources, storage resources and human-computer interaction capabilities, the visualization and optimization of servo system parameters need to be realized by the upper digital controller. Therefore, the technology integration of controller technology and servo drive technology has become an important direction for the development of CNC technology. This technical feature can be seen in many controller products.
The above four technical directions are very important for the advancement of digital equipment. China's numerical control technology basically has a large gap in the above direction, and should be the direction of our efforts.
5. Break through the technical strategy of technology containment
In the strategy of technology implementation, it is an important technical strategy to make full use of new technologies in the field of general technology. The advancement of computer hardware and software technology in the past decade has provided important support for us to achieve catch-up and leapfrogging in the field of numerical control technology. The high-performance CPU provides more computing resources for control computing and simplifies the hardware architecture of the system. A variety of embedded operating systems provide a convenient application interface for controller software. Computer communication technology, including industrial fieldbus technology, has greatly increased the internal interconnect and external interconnect information bandwidth of the controller. The maturity of software engineering technology provides guidance for the guarantee of software quality and the sustainable development of software architecture. Advances in power electronics technology provide safe and reliable support for more powerful servo drives. The above-mentioned technology is only a small part of the progress in the field of engineering technology in the past ten years. It pays full attention to the advancement of general technology in the field of engineering technology, making new technology become our late-coming advantage, and it is of great significance for us to accelerate the technology to catch up with technology.
In the technical implementation strategy, the full realization of the integration of manufacturing technology, control technology and computer technology is an important technical strategy. The integration of manufacturing technology, control technology and computer technology is in line with the technical characteristics of the CNC technology chain. Manufacturing technology is the source of the demand for numerical control technology. The development of controllers that conform to the characteristics of China's industrial model and manufacturing technology is an important driving force for the advancement of domestic controller technology, and is also the basic starting point for the competitive advantage of controllers. Control technology is the main content of CNC technology and the core of the technology chain. Computer technology is an important support for CNC technology. On the one hand, with the support of computer simulation technology, through the physical process simulation of the manufacturing process, the basic control model and control strategy are provided for the control technology; on the other hand, computer technology is also an important carrier for the implementation of control technology. Therefore, the integration of manufacturing technology, control technology and computer technology should be fully realized in the construction of the numerical control technology discipline group and the technology chain linking process.
6 Conclusion
In addition to the problems of technology itself, the advancement and development of China's numerical control technology requires the encouragement and support of national policies and the support of manufacturing equipment manufacturers. In particular, it is necessary to solve the first application demonstration project of the first set. On the one hand, it quantifies the difference in the level of CNC technology at home and abroad, and clarifies the efforts of domestic controllers; on the other hand, breaks the myth of imported brands, and is the CNC product of domestic brands. Application promotion provides opportunities. It is a long-term and far-sighted way for China's numerical control technology to catch up with the world's advanced level. I believe that under the social atmosphere of building an innovative country, we will make full use of new technologies in the field of general technology through the establishment of a new type of industry-university-research innovation model with enterprises as the core. To achieve the integration of manufacturing technology, control technology and computer technology, through persistent efforts, independent innovation, and gradually breaking the technical blockade and containment, and accelerating technological progress, there is great hope.
1. The international competition environment curbs the rise of China's numerical control technology
It is precisely because of the characteristics of dual-use CNC technology, the international competition environment has obvious intention to curb the rise of China's numerical control technology. From the "Batumi" to the technical blockade stage of the Cox report, to the establishment of factories through joint ventures, local production, low-end product dumping, and the independent research and development of China's domestic research and development forces can reflect the intention to contain. Quite a number of facts prove that we are trying to introduce the technology, the good intention of "changing technology with the market" is just wishful thinking. The result is often that the market is lost, but the technology has not been exchanged. At present, the controller giants headed by Japan FANUC and SIEMENS monopolize more than 80% of the products, and high-end products not only monopolize but also restrict Chinese imports. Through nearly 20 years of continuous technological research and market cultivation, China has created a number of CNC manufacturers, opening up the situation in the low-end market and forming a certain market scale; but in the technology-intensive mid-to-high-end controller market, the scale of domestic controllers Always in a compressed state, profit margins are compressed, and R&D systems cannot support sustainable technological advances.
Industry experts admit that "the level of China's CNC machine tools and the world's developed countries are at least 15 years." Japanese international economics parent Tanikawa Taro, published an article entitled "China's future depends on Japan" in the May 2005 issue of Japan's "Huasheng". According to the article, in the automobile manufacturing industry, the average working time of machine tools for producing auto parts is as high as 3,500 hours, and only Japanese-made machine tools can guarantee the performance for five consecutive years. "Without Japan's machine tools, China's auto industry will be difficult to move." Hasegawa Kyotaro predicts that China’s dependence on Japan will only grow stronger and will not weaken. This means that "Japan is increasingly capable of controlling China." Objectively analyzing this article and abandoning the arrogant mentality of a few Japanese scholars, the article's point of view is that it should arouse our sense of urgency in terms of the gap between the key components of the manufacturing equipment and the products in the equipment manufacturing industry.
2. CNC technology has technical conditions and industrial conditions for breakthrough containment
Breaking the foreign main means of curbing our CNC technology is to reduce the dependence on foreign technology, choose the key technology with technical support conditions as a breakthrough, and take the initiative to break through, in order to win the initiative in the competition. With the support of computer hardware and software technology and communication technology advancement in the past decade, CNC technology has the key technology breakthrough conditions. From the perspective of industry, the basic characteristics of CNC controller products can be summarized as dedicated industrial computers; the characteristics of servo drive system products are industrial power supplies for driving motors; the characteristics of servo motor products are high with high-precision position feedback originals. Precision motor. In view of these product characteristics, from the industrial point of view, China is fully equipped with high-end CNC system industry conditions, and some products with similar industrial characteristics are world-leading. Therefore, jumping out of the narrow sense of motion controller manufacturing, from the perspective of China's industry as a whole, the CNC system industry breakthrough is industrial support conditions. Another feature of the CNC system industry is the softwareization of technology. Software running on digital controllers and servo drives carries the main functions and performance of the system. Therefore, competition in this industry will be more transformed into an intellectual level competition based on software technology, control technology and manufacturing technology, and an engineering level competition characterized by technology integration.
3. The key to breakthrough technology containment is to establish an independent innovation platform suitable for the growth of core technology systems.
The key to anti-containment is to build an independent innovation platform suitable for the growth of core technology systems, from passive technology catch-up to active technology confrontation. High-end CNC technology is not only a problem of controllers, but a group of technical disciplines related to motor, drive, measurement, communication, computer hardware and software technology, and machine tool testing and simulation. These technical aspects will have an impact on the final device control effect.
This problem is illustrated by taking high-speed, high-precision, high-response motion control as an example. From the material published by FANUC, the control resolution is increased to nanometer to double the precision of the processed product and double the surface quality. But this result requires a comprehensive technical upgrade of the controller. For the implementation of high-speed motion control technology, motion trajectory analysis and prediction based on the advance read mechanism is required. This mechanism will place higher demands on the architecture of the system. Trajectory smoothing and jerk control are all necessary techniques to avoid shocks in high-speed motion control. The calculation accuracy of the interpolator should be increased from 1 um to 1 nm, the calculation word length should be increased by three digits, and the effective calculation accuracy should be increased by three orders of magnitude. The software platform must support the calculation of the corresponding word length. On the other hand, the control of the beat also needs to be improved accordingly, otherwise the accuracy of the simple command is not meaningful. This of course has a higher demand for the computing load of the system, and the system hardware platform must have a higher speed. It is not enough to implement this resolution only in the controller, and this control amount is also sent to the servo drive. Due to the expansion of the effective word length, the control beat is improved, and the demand for the corresponding communication generation width is also increased. The servo communication problem must be digital, and the pulse mode and analog plus position pulse feedback cannot meet the requirements. On the servo side, it is clear that a higher precision control problem is to be pursued. The first is the need for a more accurate position feedback original. At present, the international high-precision servo device sensor has been upgraded to 2 million lines - 4 million lines, in order to cooperate with existing mechanical devices to achieve nano-scale control. Most of the sensors in our domestic controller products are around 2000 or 2500. The gap in this sensing technology directly leads to the speed regulation of our drive units, and the speed stability is different. Another problem with high-resolution sensors is the sensor interface problem. Obviously, this type of resolution cannot be interfaced with an AB pulse. A high-speed digital communication protocol that ensures simultaneous sampling of the controller is a problem that must be solved. The problem of high precision control of the servo itself is also a problem that must be solved. FANUC emphasizes HRV (High Response Vector Control), and Mitsubishi emphasizes that OMR (Optimized Mechanical Response Control) directly points to the core problem of high-precision servo control. High-precision, fast-responding current loop design. Only good current loop characteristics can lay the foundation for good speed control and position control. Many control techniques can make a difference in the process of solving this core contradiction, including various state recognition, synovial control and variable parameter control.
To achieve high-precision control, it is not enough to rely solely on the controller and servo drive. Motor design itself is an important factor that directly affects the effects of motion control. For a permanent magnet synchronous servo motor, a good back EMF positive rotation, a small cogging force will be very beneficial to the servo drive to achieve low speed smooth control. Many manufacturers of high-precision drive devices are themselves motor manufacturers. In many domestic research institutions, motor technology and servo drive technology are separated by departments, and some even do not have motor technology support for servo drives. In the study of high-precision motion control, simulation technology will greatly shorten the time and implementation cost of our research in control algorithms. While supporting the simulation technology, it is also necessary to develop a test platform to evaluate the effects of motion control and evaluate the performance of servo drives and motors. For example, how to evaluate low speed stationarity and stiffness.
The high-speed high-precision motion control technology is taken as an example to illustrate that the high-end controller technology is a closely coupled technical discipline group. As a high-tech numerical control technology innovation system should have the integrity of the technology chain, so we call this technology innovation system a "technical innovation platform." The investment in the construction of such a technological innovation platform is enormous. Take Japan FANUC as an example, staying ahead in technology and ranking first in the world in terms of output. The company has 3,674 employees, more than 600 researchers, and 7,000 sets of monthly production capacity. Sales account for 50% of the world market. R&D investment is 10% of sales, and annual research and development costs are hundreds of millions of dollars. Obviously, supporting the above platforms is very difficult to rely on a company or unit under the existing research conditions in China. We can only integrate technological resources through the integration of technical resources, including the institutions of higher learning and other research institutions, with the industrial chain and technology linkages, to form a new type of industry-university-research innovation organization, which is realized under the relevant national policy support and guidance. It is possible to achieve technological leapfrogging with an innovative technology platform that is closely coupled with multiple technologies.
4. Grasping the development trend of CNC core technology
Make full use of the new technology in the field of general technology, grasp the development trend of CNC core technology, and do something about it. The Chinese equipment controller industry in the backward competition state must make full use of new technical means, grasp the development direction of numerical control technology, and do something according to its actual situation, forming a late-comer advantage and accelerating the pace of technological progress. In order to achieve catching up and crossing.
First of all, we need to clarify the development direction of China's CNC technology needs. We can be inspired by the direction of SIEMENS CNC system export restrictions to China. Most of these functions are considered to directly affect the function of the core competitiveness of European equipment.
The CNC system of SIEMENS is divided into export type and standard type. A large number of functional groups are restricted in the export type. Non-EU users purchasing these functions require official approval from Germany or the European Union.
Analysis of the above functions can summarize several important technical directions of high-end controllers:
Control technology for complex motion laws. The "spiral interpolation 2D+6", "5-axis machining package", and "multi-axis interpolation (4 axes)" in the above table all belong to this technical direction. The motion control of complex profiles and curves belongs to the basic technology in the numerical control foundation, and is also the actual demand for the process equipment. In particular, the five-axis machining control technology is the basic support technology for complex surface machining. This technology is a key technology related to aerospace manufacturing, weaponry manufacturing, and power equipment manufacturing.
Multi-axis coupling relationship motion control. “Handling (robot) conversion package†in the above table, “1D3D gap control in position control loopâ€, “overhang compensation, multi-dimensionalâ€, “active numerical coupling and curve list interpolationâ€, “electronic gear unitâ€, “ The continuous correction" and "measurement level 2" all reflect the above characteristics. The common feature of the above functions is that a coordinate axis motion is no longer performed by the planned trajectory, but has some coupling or synergistic relationship with the motion or logic of other axes, that is, the real-time interpolation process also introduces other control factors. The above functions are obviously necessary for complex equipment and are an important supplement to the classical interpolation motion control. Open structure. The "open architecture NC core compilation loop" and "synchronous operation" in the above table belong to this technical direction. The "Open Architecture NC Core Compilation Cycle" engine allows users to add their own control functions to the system and execute them periodically according to the specified execution frequency. The "synchronous operation" is that the user stipulates execution conditions and execution actions in the form of a high-level language. These two functions respectively reflect the opening of different levels of the control system, one is the opening of the execution engine, and the other is the opening of the user language level. This type of technology is obviously beneficial to the rapid response process requirements of the OEM, integrating its own proprietary technology into the controller, and secondary development of its own unique controller, greatly expanding the control capabilities of the controller.
Integration with servo control technology. The "internal drive variable evaluation" in the above table belongs to this technical direction. The performance of the servo drive directly affects the control performance of the entire CNC system and the performance of the entire equipment. Therefore, servo drive related technology has become an important foundation for the high-end controller technology group. Due to the characteristics of the servo drive embedded system, the limitation of computing resources, storage resources and human-computer interaction capabilities, the visualization and optimization of servo system parameters need to be realized by the upper digital controller. Therefore, the technology integration of controller technology and servo drive technology has become an important direction for the development of CNC technology. This technical feature can be seen in many controller products.
The above four technical directions are very important for the advancement of digital equipment. China's numerical control technology basically has a large gap in the above direction, and should be the direction of our efforts.
5. Break through the technical strategy of technology containment
In the strategy of technology implementation, it is an important technical strategy to make full use of new technologies in the field of general technology. The advancement of computer hardware and software technology in the past decade has provided important support for us to achieve catch-up and leapfrogging in the field of numerical control technology. The high-performance CPU provides more computing resources for control computing and simplifies the hardware architecture of the system. A variety of embedded operating systems provide a convenient application interface for controller software. Computer communication technology, including industrial fieldbus technology, has greatly increased the internal interconnect and external interconnect information bandwidth of the controller. The maturity of software engineering technology provides guidance for the guarantee of software quality and the sustainable development of software architecture. Advances in power electronics technology provide safe and reliable support for more powerful servo drives. The above-mentioned technology is only a small part of the progress in the field of engineering technology in the past ten years. It pays full attention to the advancement of general technology in the field of engineering technology, making new technology become our late-coming advantage, and it is of great significance for us to accelerate the technology to catch up with technology.
In the technical implementation strategy, the full realization of the integration of manufacturing technology, control technology and computer technology is an important technical strategy. The integration of manufacturing technology, control technology and computer technology is in line with the technical characteristics of the CNC technology chain. Manufacturing technology is the source of the demand for numerical control technology. The development of controllers that conform to the characteristics of China's industrial model and manufacturing technology is an important driving force for the advancement of domestic controller technology, and is also the basic starting point for the competitive advantage of controllers. Control technology is the main content of CNC technology and the core of the technology chain. Computer technology is an important support for CNC technology. On the one hand, with the support of computer simulation technology, through the physical process simulation of the manufacturing process, the basic control model and control strategy are provided for the control technology; on the other hand, computer technology is also an important carrier for the implementation of control technology. Therefore, the integration of manufacturing technology, control technology and computer technology should be fully realized in the construction of the numerical control technology discipline group and the technology chain linking process.
6 Conclusion
In addition to the problems of technology itself, the advancement and development of China's numerical control technology requires the encouragement and support of national policies and the support of manufacturing equipment manufacturers. In particular, it is necessary to solve the first application demonstration project of the first set. On the one hand, it quantifies the difference in the level of CNC technology at home and abroad, and clarifies the efforts of domestic controllers; on the other hand, breaks the myth of imported brands, and is the CNC product of domestic brands. Application promotion provides opportunities. It is a long-term and far-sighted way for China's numerical control technology to catch up with the world's advanced level. I believe that under the social atmosphere of building an innovative country, we will make full use of new technologies in the field of general technology through the establishment of a new type of industry-university-research innovation model with enterprises as the core. To achieve the integration of manufacturing technology, control technology and computer technology, through persistent efforts, independent innovation, and gradually breaking the technical blockade and containment, and accelerating technological progress, there is great hope.
We started to manufacture traffic signal pole from 2001 and exported from 2002.
Our firm introduced whole set of good-sized numerical control hydraulic folding equipment(1280/16000) as well as equipped with a series of good-sized professional equipments of armor plate-flatted machine, lengthways cut machine, numerical control cut machine, auto-closed up machine, auto-arc-weld machine, hydraulic redressing straight machine, etc. The firm produces all sorts of conical, pyramidal, cylindrical steel poles with production range of dia 50mm-2250mm, thickness 1mm-25mm, once taking shape 16000mm long, and large-scale steel components. The firm also is equipped with a multicolor-spayed pipelining. At the meantime, for better service to the clients, our firm founded a branch com. The Yixing Jinlei Lighting Installation Com, which offers clients a succession of service from design to manufacture and fixing.
Traffic Signal Mast,Traffic Signal Light, Camera Pole,Traffic Signal Lighting
Jiangsu Xinjinlei Steel Industry Co., Ltd. , https://www.steel-pole.com