In 2013, the UK Government Office for Science produced a report, entitled the Future role for energy in manufacturing. In this report, they identified two threats to UK-based manufacturers. The first was that the price of energy in the UK will rise, compared to the cost faced by competitor firms abroad, placing UK manufacturers at a significant disadvantage. Well, the price has risen but globally because of the Russia Ukraine war. Nevertheless, the threat to UK manufacturing is still valid. The second threat is that a low-carbon electricity supply will be unreliable, and that the cost of power cuts will rise. Well, that is certainly true if you rely solely on low-carbon electricity. But using multiple sources of power can be greatly beneficial.

The PSM system can be used for applications such as:

• Electrical power consumption monitoring and reporting
• Fault monitoring
• Generator control features for generator to power grid synchronization
• Demand penalty cost reduction/load shedding

The PSM system consists of:

• PSM module – A standard IC694 module that mounts in an RX3i main rack. The PSM module provides the DSP capability.
• Terminal Assembly – A panel-mounted unit that provides the interface between the PSM module and the input transformers.
• Interface cables – Provide the GRID 1 and GRID 2 connections between the PSM module and the Terminal Assembly

The image below shows how a basic PSM system can be connected.

PSM System Features

• Uses standard, user-supplied current transformers (CTs) and potential transformers (PTs) as its input devices.
• Accurately measures RMS voltage and current, power, power factor, frequency, energy, and total three-phase 15-minute power demand.
• Provides two isolated relays that close when the voltage phase relationships between the two monitored grids are within the specified ANSI 25 limits provided by the RX3i host controller. These contacts can be used for general-purpose, lamp duty or pilot duty loads. Voltage and current ratings for these load types are provided in GFK-2749, PACSystems RX3i Power Sync and Measurement System User’s Manual.
• Provides a cable monitoring function that indicates when the cables linking the PSM module and Terminal Assembly are correctly installed.
• PSM module and Terminal Assembly are easily calibrated by hardware configuration using the PAC Machine Edition (PME) software.

To find out how Novotek can help you reduce your energy consumption and manage multiple energy sources email us at info_uk@novotek.com

The UK Met Office announces a new A–Z of storm names every September, officially beginning the new storm season for the UK. In winter 2021, the Met Office named the first two storms in as many weeks, with projections from mid-December expecting that a further six storms would hit the country leading into the new year.

Despite the predictability of storm season, the impact on utilities companies routinely causes significant problems. In the wake of Storm Arwen on November 26 2021, approximately 3000 homes in northern England remained without power for more than a week. This reflects the challenge of harsh seasonal weather on utilities companies — a challenge that is only set to escalate as global climate change makes erroneous weather events a more common occurrence.

Unsurprisingly, an excessive surplus of water can cause problems in the water network. If assets such as pumping stations become flooded due to a high volume of rainfall or overflowing surface water sources, it can cause further flooding in domiciles and office spaces. It’s for this reason that water and sewage companies are obligated under the Water Industry Act 1991 to ensure their systems are resilient and that the area they serve has effective drainage.

Yet ensuring resilience in the water network is no simple task due to the size of the network and the number of distributed assets. It’s for this reason that water operators depend upon supervisory control and data acquisition (SCADA) systems at remote sites and, increasingly, an effective data management and control platform. The local control systems are necessary to accurately monitor and control equipment, but an effective overarching system makes it possible to remotely address issues as they arrive.

For example, Novotek routinely works with water companies across the country to help them establish more effective automation setups to facilitate remote decision-making in a streamlined, efficient manner. One of the challenges that arises frequently is that of data silos, where field engineers may have access to pertinent equipment health or performance data that is valuable but inaccessible to other teams. Fortunately, this is best — and easily — addressed with an overarching system that collects data once and presents different views to different stakeholders.

Not every system will be well positioned to provide flexible data views to users and be capable of ensuring effective response to floods. Ideally, an industrial automation platform should also feature effective data visualisation, as well as predictive analytics that can use locally collected data to anticipate the likelihood of asset damage or outage. These attributes allow operators to easily coordinate an effective and rapid response to seasonal flooding as it occurs, at the most vulnerable or at-risk parts of a network before further problems ensue.

As winter storms continue to become more frequent and impactful, water operators must be increasingly prepared to combat the effects and maintain uptime of network assets. Automation has long been a necessity due to the scale of operations, but the effectiveness of automation deployments has never been so important.

Since the beginning of the COVID-19 pandemic, businesses across the UK have faced a surge in cybercrime. In fact, research indicates that UK businesses experienced one attempted cyberattack every 46 seconds on average in 2020. Industrial businesses are a prime target for hackers and the ramifications of a data breach or denial-of-service attack are far-reaching, making system security imperative. Here, David Evanson, corporate vendor relationship manager at Novotek UK and Ireland, explains how industrial businesses can keep their vital systems secure.

For many business leaders and engineers, it is still tempting to consider large multinational companies or data-rich digital service providers to be the prime target for hackers. However, the growing volume of cyberattacks on businesses globally show that any company can be a target of malicious attacks on systems and services.

According to research by internet service provider Beaming, there were 686,961 attempted system breaches among UK businesses in 2020, marking a 20 per cent increase on 2019. Of these attacks, Beaming noted that one in ten intended to gain control of an Internet of Things (IoT) device — something that indicates a tendency to target system continuity rather than conventional data.

Both factors together are cause for alarm among industrial businesses of all sizes. Hackers are targeting all manner of companies, from start-ups to global organisations, and focussing more on the growing number of internet-connected devices and systems that were previously isolated.

The consequences of a device being compromised range from data extraction to service shutdown, and in any case the financial and production impacts to an industrial business are significant. There is no single quick fix to bolster cybersecurity due to the varying types of hacks that can take place. Some cyberattacks are complex and sophisticated; others less so. Many attacks on devices tend to fall into the latter category, which means there are some steps industrial businesses can take to minimise risk.

Novotek has been working closely with industrial businesses in the UK and Ireland for decades. One common thing that we have observed with automation hardware and software is that many engineers do not regularly upgrade software or firmware. Instead, there is a tendency to view automation as a one-off, fit-and-forget purchase. The hardware may be physically maintained on a regular schedule, but the invisible software aspect is often neglected.

Older firmware is more susceptible to hacks because it often contains unpatched known security vulnerabilities, such as weak authentication algorithms, obsolete encryption technologies or backdoors for unauthorised access. For a programmable logic controller (PLC), older firmware versions make it possible for cyber attackers to change the module state to halt-mode, resulting in a denial-of-service that stops production or prevents critical processes from running.

PLC manufacturers routinely update firmware to ensure it is robust and secure in the face of the changing cyber landscape, but there is not always a set interval between these updates.

In some cases, updates are released in the days or weeks following the discovery of a vulnerability — either by the manufacturer, Whitehat hackers or genuine attackers — to minimise end-user risk. The firmware version’s upgrade information should outline any exploits that have been fixed.

However, it’s important to note that legacy PLCs may no longer receive firmware updates from the manufacturer if the system has reached obsolescence. Many engineers opt to air-gap older PLCs to minimise the cybersecurity risk, but the lack of firmware support can also create interoperability issues with connected devices. Another part of the network, such as a switch, receiving an update can cause communications and compatibility issues with PLCs running on older versions — yet another reason why systems should run on the most recent software patches.

At this stage, engineers should invest in a more modern PLC to minimise risk — and, due to the rate of advancement of PLCs in recent years, likely benefit from greater functionality at the same time.

Firmware vulnerabilities are unavoidable, regardless of the quality of the PLC. At Novotek, we give extensive support for the Emerson PACSystems products that we provide to businesses in the UK and Ireland. This involves not only support with firmware updates as they become available, but also guidance on wider system resilience to ensure that businesses are as safe as possible from hardware vulnerabilities. The growth in cyberattacks will continue long beyond the end of the COVID-19 pandemic, and infrastructure and automation are increasingly becoming targets. It may seem a simple step, but taking the same upgrade approach to firmware that we do with conventional computers can help engineers to secure their operations and keep running systems safely.