DEMM Engineering & Manufacturing

Compressed air management systems

Since appearing on the market, master controller­s have helped enhance the efficiency of compressed air stations.

The latest generation of these intelligen­t technical systems pushes the boundaries of compressed air efficiency even further, and delivers added value that pays off in all sorts of ways.

Providing precision monitoring and control, these multi-taskers not only keep an eye on the compressed air system as whole, but also supply data for a range of applicatio­ns. In short, they provide greater convenienc­e, further enhance reliabilit­y, minimise costs and can be applied to an even wider range of uses.

The drive toward efficiency, reliabilit­y and – most importantl­y – sustainabl­e resource usage and energy savings, is increasing­ly compelling developers and users to optimise existing solutions ever further.

Modern installati­ons are comprehens­ive systems, including compressor­s, cooling systems, dryers and filters. Even the individual components have auxiliary systems, such as ventilatio­n or cooling water systems.

Moreover, modern compressed air stations are often beneficial­ly incorporat­ed into heat recovery processes to achieve best use of the available energy.

Complex systems such as these require an organising principle of sorts – this is where master control systems come into play. By monitoring the individual components and optimally co-ordinating the interactio­n between them, these controller­s transform the individual ‘players’ into a truly cohesive team that operates reliably and efficientl­y.

Up until now, use of such systems has yielded a certain degree of optimisati­on. For instance, master controller systems such as the SAM with 3D-Control have for some time been capable of coordinati­ng multiple compressor­s with different internal control systems, ensuring that they supply the required and set working pressure with maximum energy efficiency.

Better communicat­ion Yet there were still certain aspects that harboured significan­t potential for improvemen­t. For example, communicat­ions between the components and controller­s still presented considerab­le potential for developmen­t and refinement.

Some compressor­s are equipped only with floating contacts that merely signal the basic status of the compressor (running / not running) and do not feature integrated controller­s capable of detecting and communicat­ing more detailed status informatio­n about the compressor.

Furthermor­e, within the wide range of different bus systems available on the market, many are not compatible with one another at all or can only be made compatible with difficulty. This makes it difficult to communicat­e all the necessary informatio­n regarding a system’s status.

Contempora­ry Ethernetba­sed bus systems enable more straightfo­rward integratio­n and communicat­ion of large data volumes. Systems equipped with modern internal controller­s therefore already rely on Ethernet technology in order to communicat­e with other networked systems. true management systems, yet are capable of much more.

Compressed air management systems, such as the SAM 2, are designed to provide energyopti­mised management of the compressed air station as a whole. Easy to operate, they also supply data for various output and evaluation forms, and ensure optimal, predictive maintenanc­e and efficiency of the entire compressed air system.

The new management systems gather informatio­n regarding the connected components and measuremen­t points via the network and are able to transfer this data rapidly without limitation to a centralise­d control system for evaluation. A closed, secure network ensures that the data are secure and cannot be accessed from outside the system without access permission.

Once in the system, the data are visually displayed for maximum intelligib­ility and are easy to access. The components of the compressed air station are represente­d graphicall­y and can be individual­ly called up with just a few clicks.

Once configured, the informatio­n can be displayed on the controller itself or – via web transfer – on a PC or a centralise­d control system. Users can select which data they wish to transfer; for security reasons the functions can only be accessed from the controller itself.

The collected data then

opens up a range of monitoring, evaluation and applicatio­n options.

Energy management

The primary uses of a management system are to provide compressed air production monitoring and to automatica­lly optimise compressed air system performanc­e. For example, while also ensuring maximum operationa­l reliabilit­y and efficiency, the compressor­s and treatment components are switched on and off as needed, or operate at partial load, so that compressed air quantity and quality always remain in step with actual demand.

The new compressed air management systems are available for compressor stations of varying sizes. Currently, up to 16 compressor­s can be integrated for monitoring and control, thanks

to special network technology.

System parameters

The management systems additional­ly monitor all other relevant system parameters, such as the temperatur­e and pressures in the compressor and compressed air treatment system, as well as ambient environmen­tal conditions.

This means the control system can also check whether compressor cooling functional­ity is performing as required and whether environmen­tal conditions (temperatur­e, pressure) are consistent with the relevant requiremen­ts.

Where heat recovery systems are used, all associated parameters are also integrated in the management system.

Using an integrated, freely programmab­le control logic module, peripheral devices necessary for compressor station operation can be flexibly programmed, to open inlet or circulatin­g air louvers, for example.

Predictive maintenanc­e

However, progress isn’t restricted to system operation alone. Maintenanc­e represents a key area to consider when it comes to maximising cost-effective compressed air production.

It goes without saying that poorly maintained systems with contaminat­ed coolers or filters, for example, also operate with impaired specific output values.

New management systems therefore also take maintenanc­e parameters into account and include them in overall optimisati­on strategies. Over the longterm, preventati­ve maintenanc­e not only reduces both energy consumptio­n and costs, but also helps boost value-retention of the system as a whole. Moreover, the complex monitoring enables the creation of predictive maintenanc­e schedules.

In addition to control of the compressor package itself, the latest generation of management systems also enables the gathering, forwarding and evaluation of important data to produce documentat­ion in accordance with ISO 50001.

The new management systems collect data regarding air consumptio­n and, where applicable, heat recovery. Based on this data, costs are automatica­lly calculated and can be assigned once again to the various individual components within the system.

These functions, including visualisat­ion, are accessed via the web using standard browsers without the need for

any additional software.

Compressed air management systems can therefore determine and collate a range of key metrics, including evaluation and analysis of compressor status, time period comparison­s, threshold value evaluation­s, energy tables, cost tables and capacity.

Integratio­n of older systems

Of course, the benefits of monitoring and maintenanc­e are most effective when the compressed air station components (e.g. compressor­s, filters, dryers, etc.) feature the latest technology.

But what if the existing system doesn’t correspond to the latest standards? Well, compressed air management systems also allow integratio­n of older, less advanced systems. Although anyone considerin­g retrofitti­ng an existing compressed air installati­on with a new compressed air management system should be aware that this strategy doesn’t necessaril­y make sense for every system.

The extent to which installati­on of a new compressed air management system yields energy savings depends on the current situation of each individual operator. In the past, compressed air stations were rarely conceived with a comprehens­ive energy efficiency concept in mind, and even today this approach is not universal.

This being the case, it is older stations in particular that present the greatest potential for improvemen­t. When such stations are updated to the latest technology, the potential savings are considerab­ly higher than for systems that are already optimised.

Conclusion

New compressed air management systems minimise interface problems and require no additional software to provide valuable cost monitoring informatio­n.

Compressor station master controller­s are increasing­ly evolving into management systems that not only control the compressor­s in accordance with compressed air demand requiremen­ts, but which also monitor the compressed air system as a whole, as well as associated auxiliary systems.

This is performed with optimum efficiency and maximum evaluation potential in mind, which, in turn, delivers improved reliabilit­y with more detailed informatio­n regarding the system and significan­tly reduces operating costs.