Michael Hüske, Sales Manager Germany, is especially looking forward to introducing the NIMU to the visitors. It's not the first non-invasive signalling device for rupture discs, but the latest and therefore state-of-the-art technology.
Conventional signalling devices require cables to be mounted on the rupture disc, which must then be routed out through the rupture disc holder. This is not the case with the NIMU. Here, a signal indicator is attached to the rupture disc during the manufacturing process. The actual sensor is screwed into a blind tapping in the rupture disc holder, where it monitors the position of the signal indicator on the rupture disc. This means that the wiring only starts outside the rupture disc holder.
The system is leak-proof, and back in operation quicker
After an overpressure event, and the associated opening of the rupture disc, the outlet part of the rupture disc holder must be removed, the rupture disc replaced, and afterwards the system can be put back into operation. The days when the signalling cables also had to be routed again to the respective switching box are finally over. This allows colleagues from the electrical department to devote their attention to other tasks.
Additionally: The process is absolutely leak-tight. The blind tapping in the holder replaces the tapping which is usually required. The absence of cable glands (required for the holder tappings for conventional signalling cables) means that the cable glands used cannot become porous, thus preventing an escape of the process media.
NIMU, the non-invasive signalling: Sensor in a blind tapping in the rupture disc holder, and signal indicator on the rupture disc.
When the KUB® rupture disc opens, the NIMU sensor will output information to the process control unit of the system.
GRX® - cool and hot
If the process temperature is between -180 °C and 1,500 °C, the process involves corrosive media, and the rupture disc must already respond at a relatively low pressure, then the REMBE® graphite rupture disc GRX® is ideally suited to relieve the pressure. Thanks to a specially developed coating, the GRX® does not require polymeric sealants, and is able to withstand the aforementioned demanding process conditions, while still guaranteeing absolute leak-tightness. This in turn reduces the emissions of the system.
REMBE® graphite rupture disc GRX®
We are looking forward to meeting you at ACHEMA (11.06.-15.06.2018) in hall 9.1 booth C4.
REMBE® and CSE will also provide you with support for the design of your process. The CSE Sizing Service will calculate and determine the ideal safety concept for your system. As a solution, you will be provided with a design and evaluation of the safety devices, as well as customized and customer-specific safety reports or expert opinions. REMBE® will provide you with precisely the right products and support, if necessary, as well as installation and maintenance.
In the event that new systems are created, or the development of a new building or system parts, component tests and the associated certifications will be essential. CSE Engineering and REMBE® will conduct these tests and certifications for you, determine the necessary safety-related characteristic values and, if necessary, carry out the fluid examinations. For this purpose, the REMBE® engineers from the team of Dr. Stefan Rüsenberg, the employees of CSE, as well as other well-known companies in the industry have developed a unique test circuit that enables measurements at pressures of up to 3,400 bar and more.
You can benefit from the REMBE® & CSE cooperation and work with the crème de la crème of the German process safety industry! For optimum system safety, reliable pressure relief, and minimal downtime!
For more information on CSE Engineering, please visit http://cse-engineering.de/
Do you have a specific concern? Contact the right contact person directly:
Dr. Stefan Rüsenberg
email@example.com, Tel. +49 2961 7405-148
Prof. Jürgen Schmidt
firstname.lastname@example.org, Tel. +49 721 6699 4780
The original of the flameless venting devices, the Q-Rohr®, is now certified for gas explosions. Originally developed for organic dusts, it has also been approved for different types of metal dusts, dual-fuel and gas engines for some time. In the field of gas applications, a broad range of plants in the chemical industry, as well as various test rigs have already been equipped with the Q-Rohr®.
Roland Bunse, responsible for new applications and upgrading (further) development of the Q-Rohr® since the 1990s: "The Q-Rohr® can be used anywhere, where gas-air mixtures could enable an explosion. This is the case in many industries and factories, whereas test benches are only one example thereof. I am looking forward to the upcoming inquiries - of which there are several interesting challenges currently available with very different applications, which we can all protect with the Q-Rohr®."
The Q-Rohr® consists of a explosion vent with a burst indicator, as well as a stainless-steel mesh filter. In case of an explosion the explosion vent of the Q-Rohr® will open, the inserted special mesh filter will efficiently cool down the flames of the explosion and reduce any escaping pressure to a safe minimum. System and environment are therefore ideally protected.
Jan Cleijne comes with a wealth of experience, having spent more than 22 years in the Explosion Safety Industry. As well as bringing extensive industry knowledge, Jan is formally certified for Dust Explosion Prevention and Limiting Systems, as an expert in investigating Dust Explosions and in the IECEx Certificate of Personnel Competence.
“I am very excited to progress to a higher level of dust explosion safety with REMBE® and I am looking forward to working with some major global players. I am fortunate to be joining such a respected team of experts and a company which prides itself on its quality engineering solutions”
Dr Johannes Lottermann, Director of Explosion Safety said “Jan’s many years of experience makes him a key addition to the REMBE® family. He is the perfect fit in adherence with our motto of Consulting. Engineering. Products. Service. I’m extremely pleased that we were able to find someone of Jan’s calibre to join our team and I’m confident he will play a key role in supporting our customers worldwide”
Jan Cleijne will focus on Explosion Safety Projects for spray dryers, food, biomass, brewing and wood working industries in the BENELUX area and worldwide.
Gronbech & Sonner already represents some leading high quality manufacturers, mainly from elsewhere in Europe and REMBE® is a good fit for their product portfolio. Their approach of creating value for their customers - not just by providing quality components, but also safe and sustainable solutions goes together with Consulting. Engineering. Products. Service.
A good match
Jens Bang Holmgaard, sales manager at Gronbech & Sonner, says “we have long been looking for a partner in this area and when REMBE® was open for cooperation, the rest was just details. The two companies' values are close to each other and our initial conversations around how we will serve the Danish market have gone really well”
"In Gronbech & Sonner we feel that we have a partner that can handle the job and already has an advantageous position in the markets and industries we cater to," continues Claire Lloyd, Business Development, Europe, from REMBE®.
"Training of staff at Gronbech & Sonner is already well under way and the organization has already shown a great deal of commitment that bodes well for cooperation in the future. We are looking forward to a close collaboration in 2017" concludes Claire Lloyd.
If you want to know more about REMBE® products in Denmark please contact Morten Rasch on email@example.com or + 45 33266328
The successful passing of the final exam confirms the extensive experience and in-depth knowledge of all the participants regarding the (explosion) protection of industrial systems. Dr. Johannes Lottermann, Head of Explosion Safety: "To simply sell products is not the key goal in the field of explosion safety. In adherence with our motto “Consulting. Engineering. Products. Service.” we support our customers in every project stage. And to prove our superior performance capability, we had it officially confirmed with the IECEx Certificate.” Congratulation to our colleagues!
An active system is alerted to an explosion at an early stage, when an explosion begins to develop. This is done through sensors or detectors which register the rise in pressure or the formation of flames and respond by activating the relevant isolator, e.g. a quench valve.
Passive isolation, on the other hand, responds purely mechanically to the spreading or loss of pressure, on account of its structural characteristics. This also applies to explosion valves. Under normal operation an explosion valve in a pipeline is kept open by the available flow. When an explosion occurs, the valve is closed by the spreading of the pressure front, thus effectively preventing the pressure and the flames from propagating any further.
In addition to the method mentioned so far, another constructional precaution is explosion suppression. It means eliminating the explosion at its very onset. This is made possible by detectors which register the presence of sparks or flames through sensors and immediately trigger the opening of tanks containing an extinguishing agent (also installed in the system). A highly effective extinguishing agent is released within milliseconds, nipping the explosion in the bud straightaway. If required, an explosion suppression system can also be used for explosion isolation purposes.
Gas-powered engines and the connected exhaust system for marine propulsion and power generation carry a major risk of explosion. This may be caused, among other things, by possible misfiring whereby a combustible gas-oxygen mix may reach the exhaust system. Sources of ignition mostly include hot surfaces in pipelines, turbochargers or glowing (soot) particles in the exhaust gas flow. When an explosive gas mixture meets with a source of ignition, there is the risk that pressure and flames will spread very quickly within the pipeline sections, thus usually causing damage or even uncontrolled destruction on components. This risk can lead to loss of manoeuvrability, devastating injuries and maritime distress.
The Q-Rohr® DFE is installed on the exhaust system of an engine. If an explosion occurs, it protects the engine through flameless venting technology. This reduces unacceptable overpressure, while the stainless steel mesh filter of the Q-Rohr® DFE absorbs the heat of the explosion. As a result, the explosion collapses, so that there is neither a strong shockwave nor flames. Pressure is safely relieved within the exhaust system, which remains intact. The engine room, too, receives maximum protection.
One benefit that is particularly important for ship operators is that, after an incident, the explosion vent in the Q-Rohr® DFE can simply be replaced and operation can be resumed.
Further product benefits
- 100% seal tightness to eliminate danger of asphyxiation.
- Compact, lightweight design and therefore suitable for installation within limited space
- Connection flange in accordance DIN 86044
- Corrosion-resistant: 100% stainless steel
- Substantial noise reduction, even under normal operation
“Working together with the classification societies, we classified the Q-Rohr® DFE under major explosion volumes with stoichiometrically optimal gas concentrations and a variety of response pressures. This included simulating some worst-case scenarios, and the Q-Rohr® DFE passed all the tests with flying colours. The vessels equipped with the Q-Rohr® DFE include a purely LNG-based German ferry and several DFE-based container ships. Other projects are in progress,” says Roland Bunse, Q-Rohr® DFE developer and Senior Consultant in Explosion Safety
In 2015, REMBE® GmbH Safety + Control underwent significant restructuring and a new company emerged: REMBE® Kersting GmbH.
Restructuring of REMBE® GmbH Safety + Control
REMBE® employees work in small, flexible and highly specialised teams in order to respond more rapidly and effectively to the demands of the market and the specific requirements of their customers. The company set up the following teams for every business unit: Global Sales, Technical Sales and Inside Sales.
The Global Sales team consists primarily of safety engineers with many years of experience in designing safety concepts in a wide range of industries. The Technical Sales team is composed of staff with special expertise in products and product development as well as technical documentation.
"We have made many changes over recent years. After founding eight world-wide subsidiaries, restructuring our sales department was the next logical step towards realising our unique selling proposition: Consulting. Engineering. Products. Service." says Stefan Penno, son of the company's founder Bernhard Penno and Managing Director of REMBE® GmbH Safety + Control since 2004.
The company believes that these four words sum up the difference between REMBE® and other companies operating in the same markets. REMBE® not only supplies products but also offers all the services, which plant operators require in the areas of explosion protection and pressure relief – from safety scans of existing plants and consulting services for planning new facilities to customised product development, start-up services and maintenance.
The birth of a new company – REMBE® Kersting GmbH
Over the decades, REMBE®'s Industrial Measurement division and Kersting GmbH Sampling + Grounding have independently established strong reputations as experts in the bulk materials industry. Their achievements were the inspiration behind the decision to merge the two entities into REMBE® Kersting GmbH. The new company combines all REMBE®’s specialist knowledge in bulk materials and supplies everything its global customers require for measurement, weighing, sampling and grounding. With a strong focus on productivity, it equips bulk material companies in a wide range of sectors with measurement technology, samplers and electrostatic grounding systems. At REMBE® Kersting, too, consulting, engineering and service complement the familiar product range of mass flow measurement, fill level control, sampler and ground monitoring technologies. "From measuring and weighing to sampling, our primary aim is always to make our customers' processes more efficient and productive. This requires more than high quality products. We also support our customers in planning, assembly, start-up and calibration," explains Jochen Eberheim, Managing Director of REMBE® Kersting GmbH. Dipl.-Ing. Jochen Eberheim is one of Germany's most experienced managers in the area of bulk materials and bulk material handling.
So what does SIL involve?
When assessing the functional safety of a protection system it is above all important to ensure that its reliability matches the risks of a plant that is in danger. Such a SIL classification is based on a risk assessment that covers the probability of failure in a safety setup within a given scenario and the potential severity of any resulting damage. The defined tables and values, which can be found, for instance, in EN ISO 13849, lead to the required SIL level for the relevant (electronic) component. The higher the probability of occurrence and/or the potential severity of damage, the higher should be the requirements on the electronic componentry and also on the necessary SIL level. Any facilities with SIL level 4 certification thus offer the best risk minimisation and must be provided wherever probability and potential severity are especially high.
The risk assessment then forms the basis for an evaluation of measures designed to help reduce those two factors: probability of occurrence and potential severity of damage. The former is mitigated through preventive action, e.g. inertisation devices to prevent the occurrence of hazardous explosion-prone atmospheres). The severity of damage can be reduced through measures (e.g. explosion suppression systems).
SIL and “passive” explosion protection – REMBE® unites elements which belong together
SIL looks at the source which produces the functional safety of (E/E/PE) systems. The overall regulatory framework on which all certification is based is IEC 61508. Statements on the so-called “average probability of failure of the protective function at the point of requirement” have been available for quite a while as active protection systems, for instance, for REMBE®’s Q-Bic™ suppression systems.
Mechanical protection systems are not covered in this directive and cannot therefore be certified under it.
This has been the theory up to now. In practice, something else is required: Many plant manufacturers and operators in a variety of industries feel committed to SIL and demand that reliability parameters should also be available for mechanical protection systems, as they are often used in combination with (E/E/PE) systems and can only produce a consistent protection policy in its “overall effect”. Moreover a number of standards such as TRBS 2152-5 will expressly require certain SIL levels for protection systems in the future.
These practical requirements prompted REMBE® to take action: “Based on our close collaboration with customers and their planning and engineering offices, we are well aware that massive practical problems are likely to occur unless attention is paid to the safety gap of mechanical protection systems when reviewing the functional safety of explosion protection. With this in mind, we have set ourselves the task of finding a practical solution to the problem. After all, we are well aware of the vehement debates on the pros and cons of SIL outside electric, electronic and programmable electronic systems,” says Johannes Lottermann, PhD (Eng), Senior Consultant on Explosion Safety at REMBE®.
Based on these findings and its readiness for change, REMBE® has worked with IQZ, the German Institute of Quality and Reliability Management, in Wuppertal. Together, they have developed a transparent and legally sound methodology to assign SIL equivalents to REMBE® products despite their purely mechanical functions. The resulting PFD values (Probability of Failure on Demand) can thus be translated into “SIL language” under IEC 61508. It turned out that the company’s bursting disks had a SIL equivalent of 4, and the flameless venting devices a SIL equivalent of 2, due to the integrated electronic components of this SIL level.
“As we worked with renowned experts on the development of transparent methods in setting up PFDs, we are confident that the PFDs will be accepted in practice. REMBE® can be proud that, for the first time, this innovative approach is finally shedding some light into the darkness when it comes to assessing the functional safety of overall plant protection.
In a recent project, thanks to the SIL-equivalent parameters of our bursting disks, we helped a customer in New Zealand calculate the overall failure probability of their vented system which was protected by electronically controlled extinguishing barriers. This was a requirement specified by the relevant authority, and it was possible to complete the approval documents which, otherwise, would probably still be outstanding,” says Johannes Lottermann.
“The results of the relatively high SIL equivalents did not actually surprise us all that much,” says Stefan Penno, CEO of REMBE®. “It should be plausible to every engineer that a simple mechanical functional principle – like that of a bursting disk – is naturally more reliable than an electronic control circuit, despite all its sophistication and redundant backup systems.”