Sunday 3 December 2017
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SIEMENS LOGO! 8 - An Overview
Tuesday 14 November 2017
Information Technology and Control
The lines between plant control systems and Information Technology systems are blurring. Even more than I previously thought. Consider the latest from Rockwell Automation.
Rockwell Architecture and Software business grew more than twice as fast as the Control Products and Solutions group in the second quarter of 2014.
Which suggests that companies are recognizing the value of this relationship. Mid size companies can reduce their costs by 20% over 5 years by applying automation and information systems strategically in their organizations. Rockwell’s own manufacturing has been impacted by 33% reduction in inventory and 30% reduction in capital expenditures as a result of better utilization of assets. These are big benefits that businesses everywhere can relate to.
The science fiction daydream of automated factories turning out products may still be a few years away, but you can see the trend in action. Robots, now called collaborative robots, soon to be called “associates” if we’re not careful, have fallen in cost and implementation is ever easier. Control system costs continue to fall in the presence of inexpensive embedded processors.
The missing element tying them all together is not multiple layers of proprietary information systems, but inexpensive Ethernet and variants that incorporate Precision Time Protocol. The neat thing here is the Precision Time Protocol can be backward compatible with existing non-real time Ethernet. So there is no need to rip out existing hardware. In some cases, wireless infrastructures using cell phone bands and Internet provide the virtual data “pipeline”.
The estimated annual output of businesses between $10 million and $1Bil, a segment composed of 200,000 companies and 44.5 million employees, produces more than $10 trillion dollars in output annually. These are the companies that will adopting advanced manufacturing strategies to increase their profitability. On a statistical basis of 3.4% of gross domestic product, it represents a potential $340 billion in technology.
What remains is a 1+1=3 solution that combines the hardware, infrastructure, software and customization to deploy a mix of solutions that are based on as many existing components as possible. Manufacturing floor control systems will need to be able provide status reporting to customer relationship management inquiries. Scheduling programs will have to be able to estimate capacity in near real-time and optimize complex manufacturing inputs based on supply chain information about materials availability.
The next few years will be a sea of change driven by huge underlying forces. Getting more productivity and predictability.
Sunday 13 August 2017
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Tuesday 18 April 2017
How Residual Current Device (RCD) works ?
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How Residual Current Device (RCD) works ?
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Tuesday 11 April 2017
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Wednesday 8 March 2017
What is new in Data Acquisition Systems ?
From research work to modern engineering processes, high rates of encoded information in multiple signals from simultaneous processes have forced data acquisition (DAQ) systems to evolve. This article gives you insight on the latest in DAQ systems.
Data acquisition is a process of acquiring information and documenting it in a meaningful way, to analyse a process or phenomenon. Data acquisition (DAQ) systems are usually used in
Sunday 5 March 2017
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AVR Microcontrollers Programming - Exercise 3
AVR Microcontrollers Programming - Exercise 3
Welcome to TESLA INSTITUTE Facebook Page
Sunday 22 January 2017
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Introduction to PROFIBUS
Automation technology has been characterized by rapidly changing technology for many years. The driving force for this was and still is the pressure to lower production costs, the demand for high and consistent product quality, improved operat-ing reliability and the availability and flexibility of the systems, especially the consistent flow of data within a company. A visible sign of this change is the development of fieldbus technology with a transition from analog to digital communication and thus the possibility to exchange detailed information on the status of a production system and its environment very quickly. Digital communication also enables functions of the centralized controller to be relocated to decentralized field devices, which simplifies cabling considerably. The world-wide standardization of the interfaces opens up the path to consistent automation, and leaves previous solutions using a large number of proprietary systems behind.
PROFIBUS contributed considerably to the de-velopment of fieldbus technology. It links control-lers and control systems with sensors and actua-tors on the field level (field devices) and also ena-bles simultaneous consistent data exchange with superordinate systems. PROFIBUS is the fieldbus-based automation standard of PROFI-BUS & PROFINET International (PI). PI has also developed the PROFINET Ethernet-based auto-mation standard and launched it successfully on the market. PROFIBUS and PROFINET use iden-tical device profiles, thereby creating investment security and investment protection for the users and manufacturers of these technologies. Both systems cover the fields of production and pro-cess automation and therefore also enable mixed (hybrid) applications, which are often seen in the pharmaceutical, food and beverage industries.
PROFIBUS consistency is based on the standard-ized "PROFIBUS DP" communication protocol, which supports a variety of applications in produc-tion automation and process automation as well as motion control and safety-related tasks. This integration makes planning, installation and ser-vice easier. Training, documentation and mainte-nance need only be carried out for one technolog-ical aspect.
Market position
The first fieldbus systems, which were proprietary, were introduced to the market in the 1980s. With the objective of far-reaching standardization, 21 companies and institutes came together in 1987 to create a joint project with the task of developing and testing an open fieldbus standard. This pro-ject was the starting point for the development of PROFIBUS. After the joint project was complete, the PROFIBUS Nutzerorganisation e.V. (PNO) was founded in 1989 to continue the work. This organization was comprised of 10 companies, four scientific institutes and ZVEI. Two years later, it grew to over 100 members, and today (2010) there are about 1,400 members who have jointed together under the globally positioned PROFIBUS & PROFINET International (PI) fieldbus organiza-tion, which was founded in 1995. Today, there are 27 regional PI associations in countries on every continent. The common goal is the continuous development and global distribution of PROFI-BUS and PROFINET technologies. With well over 30 million devices installed in the field, PROFI-BUS is a global market leader in the field of indus-trial communication systems.
The success of PROFIBUS is equally due to its advanced technology and the successful activities of the organization, which was founded to repre-sent the interests of manufacturers and users.
In addition to the many measures employed for technological development and its propagation, additional global support services for members (users and manufacturers) are available in the form of consulting, information and measures for quality assurance and standardization of the technology in international standards.
PI forms the largest user group for industrial communication in the world, which offers oppor-tunities for the future and at the same time comes with certain obligations. The opportunities are in the creation and propagation of market-leading technologies which are beneficial to the user. The obligation is for those responsible for this user group to fully maintain PROFIBUS's goals of openness and investment protection in the future as well. This obligation serves as a guideline for everyone involved.
Modular design in system building blocks
PROFIBUS's module concept is what has allowed it to reach its top position in the global market. The communication protocol can be combined with a variety of application-specific technology modules which are compatible with one another (transmission technologies, application profiles, integration technologies). This ensures complete consistency with a large breadth of applications. With such a "system building block" (Figure 1), all the applications of automation technology can cover tasks in the production and process indus-tries, including safety-related ones.
The core of the system building block is the PRO-FIBUS DP (Decentralized Peripherals) commu-nication protocol, which is the same for all appli-cations and is used for communication between centralized automation devices and decentralized field devices.
A number of different data transmission alterna-tives are available, depending on the usage case. RS485 transmission technology is intended for use in the production industry and in the process industry in applications without explosion protection. RS 485-IS (Intrinsically Safe) covers uses in explosion protected areas. The MBP (Manchester coded Bus Powered) and MBP-IS transmission technology is specifically oriented toward the pro-cess industry and also handles power supply to devices on the bus, in addition to data transmis-sion. Several optical transmission technologies are also available.
PROFIBUS application profiles are specified for standard data exchange between field devices on the user level. The use of such profiles guaran-tees interoperability in the data exchange be-tween field devices from different manufacturers. These profiles specify application-typical device features, and "profile devices" must comply with them. They might be cross-device-class features (e.g. safety-relevant behavior) or device-class-specific features (e.g. to be exhibited by process devices or drives). Field devices with different application profiles can be operated in the same automation system. Simple devices with univer-sal functionality, e.g. decentralized binary I/O de-vices, do not usually use application profiles.
Additionally to the layers for transmission and communication, the system building block also provides the required engineering technologies for device description and integration.
Application-specific solutions
The system building block makes it possible to cover very different applications using "solutions" specifically arranged for them by combining the appropriate components. Examples include solutions for the production industry, process au-tomation, drive engineering and safety-related systems. The structure of these modular "solutions" can be seen in Figure 2. Only the communication protocol is the same with all solutions and ensures the high consistency of PROFIBUS already mentioned.
Figure 1: PROFIBUS system building blocks
Figure 2: PROFIBUS solutions for different market segments
Hybrid automation
In the past, production automation and process automation had to be viewed as two strictly sepa-rate fields and automated using different technol-ogies. The reason for this were the different mar-ginal conditions of an automation system. Produc-tion automation is based on fast processes and an accordingly shorter system service life. Pro-cess automation, on the other hand, is character-ized by slow procedures and a longer system service life. This led to insular solutions within the overall system. Today, a user can avoid such insular solutions by using a PROFIBUS solution that is consistent for all the applications of the production chain. PROFIBUS is the only fieldbus that fulfills the requirements of such consistent (hybrid) automation of production-control (inbound and outbound logistics) and process-control process steps (Figure 3).
Figure 3: Consistent PROFIBUS solution in a single production system
Examples
In the pharmaceutical industry, the manufacture of medicines is a process-control procedure. The packaging of tablets, for example, uses produc-tion-control tasks with complex packaging machines, however.
In the food industry, at a brewery for example, the typical process-control procedures in the brew-house and fermenting cellar are followed by the production-control procedures of bottle cleaning and filling and the stacking of crates by robots.
In vehicle production, the paint shop, with its pro-cess-control requirements (explosion protection), is part of a production chain that otherwise in-volves production-control tasks.
OSI layer model as a basis
The design of the technology modules with PRO-FIBUS is oriented toward the OSI layer model (Open Systems Interconnection Reference Mod-el). Here, the communication process between two nodes is distributed over seven "layers", from layer 1 ("physical layer", trans-mission technology) to layer 7 (“application layer”, interface to the application). PROFIBUS uses layers 1, 2 and 7 (Figure 4):
• Layer 1 defines the physical transmission. With PROFIBUS, there are copper-wire versions (RS485 and MBP) and optical and wireless transmission.
• Layer 2 defines the description of the bus access method, including data security. With PROFIBUS, this is the master-slave method in conjunction with the token method.
• Layer 7 forms the interface to the application and thus represents the link between the application and communication. With PROFIBUS, the communication protocol PROFIBUS DP is used here.
• The actual application process lies above layer 7 and is not part of the OSI model.
Figure 4: References between OSI model and PROFIBUS
Figure 4 shows the definition of the seven OSI layers on the left and the implementation of PROFIBUS on the right.
Standardization
The contents of the OSI layers are specified by standards so that the openness of the system is ensured when the standards are complied with. Together with other fieldbus systems, PROFIBUS is part of IEC 61158 ("Digital data communication for measurement and control – Fieldbus for use in industrial control systems") and IEC 61784 ("Pro-file sets for continuous and discrete manufactur-ing relative to fieldbus use in industrial control systems").
IEC 61158
IEC 61158 deals with the technologies used and describes the method of functioning of the fieldbus. It is divided according to the OSI model. The individual fieldbuses are differentiated by the definition of "fieldbus protocol types" in this stand-ard. Here, PROFIBUS is type 3 and PROFINET type 10.
IEC 61784
IEC 61784 defines the subsets of the service and protocol supersets specified in IEC 61158 (and other standards) which are used by a certain fieldbus system for its communication. They are collected in "Communication Profile Families (CPF)"; for PROFIBUS, it is "Family 3" with a subdivision into 3/1 (RS485 and fiberoptics) and 3/2 (MBP). Part 3/3 is concerned with PROFINET.
