Making more of process and materials with sensors innovation
08 October 2013
Manufacturers are tapping into the benefits that more capable sensors and instrumentation can provide, says Jesse Bonfeld, Sherborne Sensors' VP business development. More capable sensors enable manufacturers to drive significant improvements in process and plant efficiency, product quality and safety.
However, while an increasing number of organisations are recognising the need to implement more capable sensors within their processes and facilities, there are several potential challenges to increased sensor deployment.
Most facilities have an existing process and physical layout and any necessary modifications to add additional sensor capabilities could impact system safety, time and cost – all of which can negatively affect production and the projected return on investment from the sensor programme.
It is difficult to deploy sensors without shutting down an existing process. Practical considerations include availability of power to operate the sensor, and how to transmit the signal from the sensor back to a local or plant wide monitoring system. Installing new power supply points and signal cabling to support sensor implementation can also be a costly undertaking.
A wireless solution
Wireless sensors – and wireless sensor networks in particular – are becoming increasingly popular in manufacturing and industrial facilities. According to analysts at MarketsandMarkets, the global industrial wireless sensor networks market will grow by almost 16% annually to reach 2.85 billion euros by 2017, with WirelessHART, ISA100.11a, and 6LoWPAN being the major technologies employed, as well as IEEE 802.11, ZigBee, Bluetooth, and cellular (GPRS, GSM, and CDMA).
A wireless sensor network consists of ‘nodes’, that can range from a few to several hundreds or even thousands, with each node connected to one or several sensors. This model provides a practical solution for bridging information systems and the physical world. One of the major potential benefits is that often a large number of individual wireless sensors can be monitored using a single display device, or with a wide variety of fixed base stations and hand-held readers that are already available.
Wireless solutions are shown to dramatically reduce installation costs and sensor installation times. They also increase safety levels because they can often be configured remotely or prior to installation, and swapped out easily for calibration, cleaning and maintenance. Conversely, the more permanent a sensor installation, the more costly the maintenance requirement tends to be.
Because a variety of wireless solutions, using different communications protocols, are now available, it is worth noting that mixed installations can be more difficult to manage, where these different standards are employed. A solution based on an open format, licence-free wavelength is preferable, to ensure that it does not compromise other systems using wireless standards such as WiFi and Zigbee. These standards are often found within manufacturing and industrial facilities, and are employed to reduce the challenges and costs of implementing proprietary solutions. Moreover, a solution that combines both wireless data transmission and battery operation with low power consumption is preferable, as this eliminates many of the potentially disruptive aspects of sensor installation and operation commonly associated with wired solutions.
One example is the wireless radio telemetry inclinometer, which is seeing growing adoption in the manufacturing sector as it is suited to use in permanent angle measurement installations. It is also suited for troubleshooting or checking the accuracy of angle measurements and alignments occurring across the production environment. Several applications for this technology are now employed, including the use of such a system by a leading manufacturer of heavy over-the-road trucks in the US for accurate caster measurement of the rear drive wheels. The implementation of a wireless inclinometer in this facility improved first pass yields by over 34%.
Wireless sensors measuring flow, pressure, or temperature are proving ideal for process trouble shooting, in scenarios where manufacturers want to monitor performance of a process in a specific area for a short period of time and then move on to another location until the problem is identified. Here, the mounting scheme for the sensor is a consideration, since a temporary mounting scheme (where the sensor can be used and then removed easily) ensures a fast, efficient and robust install.
One of the most vital roles for sensor technology is to provide the data necessary to enable manufacturers to realise a new level of production capability. Data acquisition and analysis has become central to enabling the culture of continuous improvement and lean manufacturing to which most companies now aspire. Continuous improvement not only allows for productivity enhancement and frees up capacity, it also serves as a foundation for driving innovation and growth.
The aircraft industry, for example, is continually looking to develop new composite materials to offer viable alternatives to aluminium, titanium and steel. This requires raw material production methods and manufacturing processes at different conditions to those used traditionally, and this is driving adoption of more capable sensors and instrumentation throughout the production process – and also in areas where they were not previously employed.
In another example, metal processing, particularly the steel industry, is becoming more capital-intensive, driven by concerns regarding energy consumption, emissions, and new standards and regulation. Increased use of sensors allows a manufacturer to better control and analyse emissions, improve operational efficiency, and adhere to best practices, standards and regulations.
Analysts at Frost & Sullivan valued the market for sensors in the metals industry at around 460 million euros in 2011, and noted that the market was growing rapidly, with advances in sensing and instrumentation and the agility with which steel makers adopt and implement these improvements expected to have a significant positive impact on their operations.
Even sensor manufacturers can benefit from advances in sensor technology to improve their processes and realise new levels of production capability. Sherborne Sensors, for example, has a calibration system that has been in commercial operation for many years. It was upgraded recently using several types of sensors in order to deliver new levels of precision required by increasingly demanding customer applications.
Acquiring data about processes and equipment is relatively straightforward using a well implemented programme of sensors. Programmes of continuous improvement and initiatives to reduce power and carbon footprints are key drivers for sensor adoption. The opportunity to consider extending the commercial life of fully depreciated plant and machinery by retro-fitting them with sensors can be significantly less costly than building a new facility, which may not even be viable commercially in today’s restrictive regulatory environment.
Manufacturers might also be able to lower operating costs through sensor implementation and upgrade. For example, by closely monitoring the performance of plant equipment and product specifications, manufacturers can implement predictive maintenance activities that ensure these costly procedures are conducted only when necessary. They may also be able to identify and address potential issues before they occur. Such an approach helps to avoid costly unscheduled downtime, as well as excessively proactive maintenance schedules.
Similarly, for a relatively modest investment in equipment and retrofit of more capable sensing devices, manufacturers are able to make more efficient use of raw materials to increase production volume, reduce lead times, improve product quality, or expand the range of products they are able to produce.
The implementation of more capable sensors and wireless solutions can also be of benefit at green-field sites. The initial capital outlay for the sensors would be offset by lowered future operational and maintenance costs, while the plant operator would have greater production flexibility as the plant ages and production requirements change.
The use of wireless sensors almost always enhances the benefits of an expanded sensor programme, due to the reduced costs associated with the installation and on-going maintenance of the sensors themselves.
As more capable sensors are deployed, the opportunity exists for manufacturers to find even more efficient and effective ways to acquire data, analyse the vast volumes being stored, identify areas for improvement and most importantly, act on the intelligence they provide.
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