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Dr. Kathrin Rübberdt
Tel. ++49 (0) 69 / 75 64 - 2 77
Fax ++49 (0) 69 / 75 64 - 2 72
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March 2015

Trend Report No 10:

Bidirectional communication for pumps, compressors, valves and controls

Fluid Flow Machinery 4.0: a two-way conversation

·  Stricter Ecodesign regulations come into force in 2015

·  Automation and networking boost productivity

·  Distributed intelligence at the field level provides greater versatility

The leading pump manufacturer only has a 9% share of the total worldwide pump market which is estimated to be around 30 billion euros. That shows how fragmented the market is. The same is true for the compressors, controls and valves market. The companies that manufacture these products are traditionally the largest exhibitor group at ACHEMA, and this year they have booked 34,000 m² of exhibition space to showcase the potential for innovation of the “Mittelstand” (mid-sized companies). Optimized system solutions and efficiency, intelligent control concepts, reduced emissions and constructions with regard to the environment are key. Automation and networking create new opportunities to increase productivity: Flow machinery 4.0 is ready to roll.

Industrial producers have to constantly find new ways of boosting process efficiency. To effectively manage cost (energy and labor costs), quality (reproducibility) and reliability (occupational safety and environmental protection), companies need to continually increase the level of automation. ZVEI (German Electrical and Electronic Manufacturers Association) reported that sales by German process automation suppliers were up 6-7% in 2014, and growth is expected to continue in 2015. AMA (Association for Sensors and Measurement) has also reported increased order intake.

This general trend in process engineering also has an impact on pumps, compressors, controls and valves. Sufficient versatility must be designed into these products to ensure that they fit seamlessly into the overall automation strategy, and the communication capabilities need to be enhanced.

To an increasing extent, manufacturers are responding by offering system solutions or package units which go beyond the basic functionality of a “process pump”, “compressor” or “control valve”. While all relevant technology is connected to centralized process control systems, components are fitted with distributed intelligence. This reduces the load on the central control systems and makes it easier to adapt the equipment when changes are made to the process. Why is this type of versatility important? At the 2014 Namur General Meeting, the individualization of production, shorter product lifecycles, fluctuating sales and faster time to market were cited as reasons.

Intelligent, distributed, network-enabled

Industry observers expect that substantially more intelligence and functionality will be migrated to the field level. Modular design is an additional factor. Subsystems are designed to fit together like Lego bricks. Components can be combined in different ways to meet application needs, and it should be possible to swap them in no more than an hour. Versatility must be built into the equipment to allow rapid adaptation and integration into a variety of systems.

To provide connectivity to higher-level control systems, manufacturers must design enhanced communications functionality into the equipment (based on real time enabled Ethernet bus technology, etc.). In addition, on-board microprocessors and stored algorithms must be capable of autonomously executing a defined set of functions. Bidirectional data transfer must be supported. The Industry 4.0 concept is built around the flow of information from high-level control systems to field devices and between different devices (for example between a pump and a valve or a compressor and a valve).

There is another argument in favor of this approach. Equipment designed for and operated in a system context is generally more reliable and tends to be less fault-prone. This is a very significant consideration in the international OEM business. Every service call-out to repair a fault at a remote location reduces the operating margin.

Brussels continues to raise the bar

Energy efficiency is a “sleeping giant”. The goal of NAPE (German National Energy Efficiency Action Plan) that was passed in December 2014 is to wake up the giant and make it the second strategic element in the energy transition roadmap. Funding is made available for certain energy efficiency measures. NAPE places the emphasis on consultancy services and networking. The government has largely avoided the regulatory route.

The Ecodesign Directive is a different matter. At the European level, the legislative process got underway in 2005 to address the issue of electricity consumption (initially EuP = Energy using Products, currently ErP = Energy related Products) and CO2 emission.

The directive for electric motors (EC640/2009) plays a key role in eco-friendly design. It applies to pumps as well as compressors. It effectively forces manufacturers to concentrate on high-efficiency motors and frequency converters for speed control. Later on and also as a result of EU regulations, increased emphasis was placed on the hydraulic efficiency of pumps.

Brussels introduces stricter regulations in 2015:

·  From January 1st 2015 all electric motors rated between 7.5 kW and 375 kW must either be IE3-compliant or IE2-compliant with a frequency converter. Two years later (2017) all electric motors rated between 0.75 kW and 375 kW must either be IE3-compliant or IE2-compliant with a frequency converter.

·  From January 1st 2015, certain glanded water pumps are required to have higher hydraulic efficiency (Minimum Efficiency Index MEI ≥ 0.4).

·  From August 1st 2015 glandless standalone heating and cooling system circulation pumps must have an Energy Efficiency Index not greater than 0.23 and the same applies to circulation pumps which are integrated into heating systems. By January 1st, 2020 circulation pumps integrated into existing products must also have an Energy Efficiency Index not greater than 0.23. It will then no longer be possible to replace heating circulation pumps integrated into products if the pumps were placed on the market prior to August 1st, 2015.

With the directive for electric motors which went into effect in January 2015, the EU has placed greater emphasis on the system approach. ZVEI expects that this will stimulate growth in the electric drive technology market.

Brussels has now become a “natural” development partner for manufacturers. Suppliers in the premium segment are by no means dissatisfied with Brussels. Technical complexity gives manufacturers a major market entry barrier to ward off potential competitors. Advances in technology designed to increase energy efficiency are difficult to imitate, and that creates an additional impediment to product piracy.

Energie efficiency : Regard the larger picture

Compared to standard motors, high-efficiency motors are 2% - 7% more efficient depending on the power rating. When the standard principles of good pump design are applied which is always recommended (working point close to the optimal pump operating point, hydraulically correct pipe dimensioning) and a well thought out system approach is taken including speed management, another zero can be added to those figures and energy consumption can be reduced by 30% - 70%. That puts things on an entirely different plane. Frequency converters have real advantages but they can also cause problems when they compensate for (neutralize) wear-related performance degradation. It often does not become apparent that this is happening until wear reaches the point where it causes failure.

There can be no doubt that pump energy efficiency is an important issue. However the significance can be relative depending on the particular industry and application. Energy consumption could well account for 90% of the lifecycle costs for a well pump used in the continuous extraction of ground water. 40% - 65% of the lifecycle costs of a pump which is used in an industrial process and runs under a high mechanical load are attributable to repair and maintenance (source: ReMain). According to the final ReMain report, 37% of pumps in the process industry are only operated at short duty cycles. These costs exceed the cost of the energy used to drive the pumps.

Controls and Valves 4.0: when will systems go wireless?

Besides process control systems and sensors, actuators play an important role in automation and process engineering. In its 2014 sensor trends report, AMA reports that direct sensor – actuator connectivity is on the increase.

Controls and valves can adjust material flows to regulate process parameters such as pressure, temperature, flow rates and fill level. “Intelligent” control valves with add-on modules are available which not only perform the control function but also automatically detect the need for maintenance or repair before a fault occurs. In the final analysis, these smart controls and valves improve production reliability, increase cost efficiency and help protect the environment. Suppliers expect that actuators will be used to a greater extent in control loops in the future. This could ultimately lead to wireless control. The actuator technology already exists.

Wireless sensing is a promising branch of sensor technology. Wireless measurement data transfer is not really new, but its potential in the industry has only recently been recognized. The technology looks very attractive but there are hurdles to overcome such as real time capability and reliability, and they are slowing the pace of introduction.

Actuator systems continue to rely on the traditional technologies: electric, hydraulic, pneumatic and electrohydraulic. But even here, more and more control and diagnostic functionality is being built into the drives. This is another application for distributed intelligence.

Electric valve actuators have the advantage that they can easily be connected even over large distances and they are relatively lightweight. Pneumatic systems have short actuation times and withstand long duty cycle ON times. However the actuator is large and heavy. Hydraulic systems are maintenance intensive, but a smaller actuator generates more force compared to a pneumatic system.

One supplier is currently talking about a paradigm shift in single-use technology. Manual systems can be replaced with devices suitable for automation and control which support fault-free operation and continuous documentation by the monitoring system. The valve body and the actuator on the new product are connected using a special locking mechanism. Following use, the valve body is removed and the actuator remains in the system for repeated use. If necessary, the valve actuator can send feedback to the monitoring system, adding the final element needed to fully monitor the control loop. The manufacturer claims that this approach facilitates process reproducibility, documentation and validation in pharmaceutical production.

Compressors 4.0: more efficient generation of compressed air

A big campaign took place in Germany a number of years ago to increase the efficiency of compressed air generation, and it served as a blueprint for similar campaigns by the German Energy Agency (dena). A study by Markus P. Rößler (TU Darmstadt, 2014) indicates that more opportunities exist to increase efficiency.

Between 2002 and 2012, companies were able to increase energy efficiency in the total compressed air system by an average 5% - 10%. An increase >10% would be technically possible but in most cases would be prohibitively expensive. The increased use of high-level control systems, drive motors with frequency control, gearless drives and permanent magnet motors instead of asynchronous motors could help boost efficiency.

Besides the actual generation of compressed air, the system context is also important. Users are making a greater effort to recover heat even on older compressors. They are also looking at optimization of auxiliary equipment such as dryers. From the overall system perspective, minimizing leakage yields the best cost/benefit ratio. Setting the pressure to the lowest possible level for the application can also boost efficiency. More and more companies are embracing operational energy management.

No radical change in the compressed air generation process is expected in the next ten years. The main emphasis will be on overall system optimization. The required use of IE 3-compliant electric motors will lead to further energy efficiency gains. On systems with variable compressed air consumption, users are looking for durable actuators which react quickly and continue to work reliably even in applications with frequent start-stop operation. Variable-speed compressors and higher-level controllers can reduce energy costs by substantial amounts. Energy consumption can be reduced by as much as 30% - 40%.

In the future, demand will continue to increase for oil-free compressed air and not just in the medical equipment, pharmaceutical and food industries. Greater environmental awareness will extend the horizon of oil-free technology to standard applications as well.

In the era of Big Data and Industry 4.0, systems and applications will become more and more intelligent and they will be integrated into complex industrial infrastructure, claims a leading manufacturer. One-stop shopping is an attractive option for a user base which increasingly prefers complete solutions.

Under the compressed air contracting model, users purchase compressed air at a fixed price rather than generating it with their own equipment. The industry is convinced that this business offers considerable potential.

TOP – the gateway to a systems approach

Experienced systems designers are normally able to combine functionality and efficiency. Inexperienced designers are unlikely to be able to do that. With reference to eco-friendly design, you could make the following provocative assertion: It is very possible to take a number of highly-efficient, well-designed machines and put them together in a way which creates a poorly designed system that is very inefficient. That at any rate is the opinion of Dr. Ulf Lorenz, Dr. Gerhard Ludwig and Prof. Peter Pelz at TU Darmstadt who are the originators of the TOR concept. So what is it all about?

New design strategies are needed to save significant amounts of energy on fluid systems which consume energy. A product approach or extended product approach must give way to a system approach. Like chess players, designers have to simulate and analyze various scenarios until they have found the system topology which performs a process function with minimal energy consumption. Mathematicians and engineers at TU Darmstadt are working together to find solutions, and the TOR virtual design software is being developed by the Fluid Systems Technology Department. The term TOR (Technical Operational Research) refers to both the virtual design software and the new research body. The goal is to provide a decision-making aid to support system design and operation and to assess energy efficiency.