Technologies

Polyurethanes have been around for decades as a seal material for high pressure reciprocating mobile hydraulic applications. Original equipment manufacturers select it as their “go to” seal material for mobile equipment due to fluid compatibility, cost effectiveness, long service life, and reliable sealing. These capabilities are attributable to the molecular chemistry of polyurethane that produces desirable performance characteristics such as: 

• Toughness
• Wear resistance
• Resistance to compression set
• Resiliency in retaining sealing ability

Seal manufacturers are closely dialed in to the need for equipment manufacturers to extend the overall useful life of mobile equipment. In addition, there are global expectations and owner/operator use trends pushing the envelope and driving the need for polyurethane materials capable of sealing higher temperatures and higher pressures, including:

• Shared ownership and equipment leasing trends in response to high costs of ownership that keep agricultural, construction, forestry and material handling equipment in operation for extended periods of time
• Expectations of longer operating times before required maintenance or overhaul 
• Expectations of increased durability
• Expectations of overall lengthened useful life of mobile equipment

Given the trends mentioned above, how will prolonged exposure at elevated temperatures – still within range – affect seal performance and ultimately, seal life? Seals are assigned a temperature rating by manufacturers, but how much is too much when it comes to heat exposure? 

What do temperature ratings mean?

Manufacturers like Parker quantify thermal capabilities of their engineered sealing materials by assigning them “Temperature Ratings” – from X to Y (min to max), but what does that really mean for equipment designers? 

Temperature ratings for sealing materials are generally based upon the typical physical characteristics of the material alone. A material's suitability for a specific application, however is dependent on actual use conditions which take into account wide ranging variables which include but are not limited to: hardware attributes and configuration, seal profile geometry, fluid compatibility, and expected duration and frequency of service exposure at pressure, temperature, and speed (i.e. ambient, continuous operating, intermittent, excursion). 

Assuming one has taken into account actual use conditions, specified a profile geometry, and selected a compatible material, let's next consider whether one can reasonably expect that seal performance will be constant at all temperatures within the material's broad stated range. 

Supported by exhaustive mechanical test lab data representing millions of cycles and decades of experience designing sealing systems, our application engineers know that best sealing performance with polyurethane can be expected when an application’s continuous operating temperature falls well within the maximum and minimum temperature limits for a compound. This is illustrated in Figures 1 and 2.1

As a practical example, the four scenarios in Figure 1 represent expected seal performance of Parker’s high performance Resilon® 4300 polyurethane material along its stated thermal range of -65°F to 275°F as configured in the application types and profiles shown (i.e., rod/piston, rod wiper, static O-ring/head seal, bumper/damper). Figure 2 is the key showing expected performance at each color coded interval.

A closer look at what this means

The purple range represents conditions where performance is compromised due to compound stiffness. In this extremely low temperature range, the polyurethane material is hardening and approaching glass transition and brittle point.

The blue range represents values where performance is compromised due to stiffness and compound rigidity. Polyurethane lip seals may require a low temperature energizer to offset compromised resiliency. 

The green range represents the recommended continuous operating temperature range for best performance.

The yellow range represents extended or continuous exposure under system pressure in temperatures roughly spanning 225 to 240°F. In this scenario, continuous dynamic cycling and increased frictional heat buildup compromises three critical performance characteristics of polyurethane: tensile – most closely associated with wear resistance; modulus – most closely associated with extrusion resistance; and compression set – most closely associated with resiliency (sometimes referred to as sealing force or the ability of sealing lips to “bounce-back” after being compressed).

In thermal conditions represented in the red area, the reference material Resilon 4300, is capable only for short duration before tensile, modulus, and compression set are irreversibly compromised. 

In summary, temperature ratings of polyurethane seal materials are primarily based on laboratory and service tests and should be used as a guide only. They do not take into account all of the variables that may be encountered in actual use. Seal designers will have more certainty and a better judgment of the fit of the seal material to the application. when the application’s sealing demands are in alignment with the described expected performance scenarios shown in Figure 2, there will be more certainty and a better judgment of the fit of the seal material to the application when all variables are considered and then matched to expected performance. 

1It is always advisable to test material under actual service conditions before specifying. 

The consequences of failure during downstream processing are severe. Following the Affinity Chromotography stage, the value of the product increases significantly at every step. A failure at the final bulk filling stage, therefore, could lead to the waste of millions of dollars’ worth of drug product.

 

It’s vital, therefore, to safeguard the bulk filling process. But traditional methods of conducting bulk fill operations have several disadvantages including:

 

1. Manual handling

This introduces the possibility of human error to the bulk filling process. It is also labour intensive, meaning that process operators need to divert their resources into this task.

 

2. Operator training

When bulk filling is carried out manually, investment must be made in operator training. This can be costly, both financially and in terms of the time dedicated to it by personnel.

 

3. Supply chain complexity

By using a range of components from several different suppliers in the bulk filling process, there is more potential for variation – and more time must be spent on sourcing and ordering suitable components.

 

4. Laminar air flow (LAF) maintenance and validation

In traditional bulk fill operations, laminar air flow must be maintained and validated to protect the products from contamination. This requires time and resources.

 

5. Shipping issues

At the shipping stage, poor handling of bottles – and the use of unsuitable containers – can lead to damage to products before they even arrive at their destination.

 

6. Non-standard operations and process variability

Traditional methods of bulk filling introduce variability into the process. If bulk filling operations aren’t standardized, they can be subject to a number of factors which can impact the final product. Factors such as different flow rates applied by different operators come into play.

 

The solution

Automating and enclosing bulk fill operations can address the challenges detailed above and increase safety for operators. Parker Bioscience Filtration has developed the SciLog® SciPure FD system as an automated and integrated single-use system for final bulk filtration, filter integrity testing and dispensing into final bulk product containers.

 

Here are some of the benefits:

 

Automation

This reduces the risk of human error from manual handling and allows operators’ resources to be spent on other tasks.

 

Standardization

Standardizing operations means that training can be simplified and variations in the process can be eliminated.

 

Enclosure

Enclosing the process allows operators to process highly potent molecules and protects both the operators and the process. And, as the flow path is completely enclosed, both filtration and dispensing can be performed in areas of lower classification, eliminating the requirement for vertical laminar flow cabinets.

 

The SciLog® SciPure FD system

The SciLog® SciPure FD system benefits from innovative component selection based around material science studies, improved filling accuracy (+/-1%), and greater flexibility in the scale of filling (from 50ml samples to 20L).

 

The system features include a barcode reader for manifold tracking, reverse flow and purge options to maximize product recovery and fully programmable alarms and interlocks to product and process.

 

 

A validated shipping solution

To reduce the risk of damage to the product when shipping, Parker Bioscience Filtration has designed a fully validated shipping solution to complement and extend the capabilities of the SciLog® SciPure FD System. Parker Bioscience Filtration has created a unique bottle design that offers manufacturers the confidence that bulk drug products will arrive at their final destinations without contamination.

 

Parker Bioscience Filtration drew on its extensive material science knowledge during the development of the bottle and material selection was based on an FMEA study. The bottle integrity has been validated down to -89˚C.

 

Parker Bioscience has also developed an anti-foaming device that eliminates foam and enables a higher filling speed.

 

Conclusion

The development of the SciLog® SciPure FD System is an example of the change in the vendor/end user relationship: by using a vendor such as Parker Bioscience Filtration, which can provide a complete solution, end users can increase their productivity and gain greater control and protection over their processes.

 

This post was contributed by Graeme Proctor, product manager (single-use technologies), Parker Bioscience Filtration, United Kingdom

Parker Bioscience Filtration specializes in automating and controlling single-use bioprocesses. By integrating sensory and automation technology into a process, a manufacturer can control the fluid more effectively, ensuring the quality of the final product. Visit www.parker.com/bioscience to find out more.

 

 

 

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In every manufacturing industry, machine safety is always a top priority. When operating in Europe, utilizing machinery and components with CE certification is the best way to ensure the reliability of the equipment that benefits both production and the operators who use the equipment. 

What is the Machinery Directive?
First published in 1989, the Machinery Directive was designed to provide freedom of movement across Europe for machinery and safety of workers in an effort to reduce injuries. 

In 2009, the Machinery Directive 2006/42/EC became law in Europe, and its primary role is to ensure common safety levels of machinery placed on the market and put into service. 

Today this directive lays down the foundation and regulatory basis for the harmonization of Essential Health and Safety requirements (EHSR) in the field of machinery. It is unified with CE requirements and covers almost 21 distinct EN Standards to guide machine builders on safety requirements and has worked to harmonize with other safety organizations. Ultimately becoming the foremost authority on where to go to design a safe piece of equipment globally.

Directive qualities
A unique quality of the Machinery Directive is its broad coverage for machinery design. The standards start at concept of design or designing out risk. The directive mandates a technical file be kept on the machine to show its inception and what risk avoidance was implemented to create a safer machine. 

Guidance is provided to the machinery builder in the form of EN standards which mandate a risk assessment be conducted on machinery. Finally, the directive includes information on disposal at end of life of machinery. While broad, the directives do a great job of ensuring safety is addressed at every level and even account for “unintended use of machinery” at the design stage.

Safety
Another interesting note is given that one of the primary purposes of the Machinery Directive is to ensure common safety, the directive does not mandate the use of safety rated products. It does clearly differentiate standard components used in a safety application versus those products built and intended as safety rated products.

Safety rated products are classified separately and are subjected to more rigorous requirements, testing and expectations for performance. 

The directive does state that common sense strategies be employed on machinery such as the use of e-stop buttons, the removal of air in a machine to protect from unexpected movement (where safe to do so) and the addition of technical measures where risk cannot be designed out. Additionally, to meet enhanced safety levels on machinery, redundancy and monitoring must be included in the controls of the machine EN ISO 13849-1 as well as validation of the system EN ISO 13849-2.

Some manufacturers offer safety rated components, such as Parker’s P33 series of safety exhaust valves, which meet the needs of the directive to remove air from machinery during either an e-stop or a faulted condition on the machine. 

Knowing that products now exist which incorporate the needs of the directive and provide an enhanced level of certified safety can bring peace of mind to machinery designers and the engineers responsible for enhanced and integrated safety on machine. 

If you would like to find out more about Parker’s P33 series of safety exhaust valves and the benefits they can bring to your machine-building projects, please download our white paper What You Need to Know About Safety Exhaust Valves.

 

Article contributed by Linda Caron, global product manager for Factory Automation, Pneumatic Division.

 

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Not long ago in hospitals and other critical care facilities, you were greeted with a large, ominous warning sign the moment you walked through the entrance doors to refrain from cell phone use due to possible medical equipment malfunction or interruption.

Today, patients and visitors are free to use mobile phones and devices without fear of interfering with medical equipment, but there’s still a long way to go to reduce electromagnetic emissions and electromagnetic compatibility (EMI/EMC) issues in medical devices.

Medical devices require complex analysis of the EMI/EMC regulations used for medical equipment and system certification. There are many new aspects that need to be addressed since medical devices are no longer used in just a hospital setting. With the increase of wearable medical tech, patients can theoretically be anywhere in the world. Therefore, EMI/EMC compliance testing needs to address the location of “end use” such as in the home healthcare environment and transportation considerations – trains, planes and automobiles.

Medical device design requirements

The primary EMI/EMC standard for medical electrical equipment and systems is IEC 60601-1-2. Developed by the International Electrotechnical Commission, this global standard applies to the basic safety and essential performance of medical equipment and systems in the presence of electromagnetic disturbances, and to electromagnetic disturbances emitted by equipment and systems. 

It also recognizes that RF wireless radio communications equipment (mobile phones, Wi-Fi and biotelemetry) can no longer be prohibited from the patient environment and medical equipment and systems.

However, the standard falls short of defining EMI/EMC test requirements for special environments and points to manufacturers addressing special environments in the risk assessment.

 

 

 

 

 

 

 

 

 

 

Remember, the difference between emissions and immunity tests are that the emissions requirement is concerned with the amount of electromagnetic energy emitted from your device, while the immunity requirement is concerned with how susceptible your device is to electromagnetic energy existing in the location of end use. This includes energy being emitted from surrounding devices.

Current EMI/EMC standards for medical electrical equipment and systems in special environments

• IEC 60601-1-2 – The basic document addresses emissions requirements for professional health care and home healthcare environments. Requirements are determined based on CISPR 11, IEC 61000-3-2 and IEC 61000-3-3 based on the environments of intended use.
• IEC 60601-1-2 – The basic document addresses immunity requirements for professional health care and home healthcare environments
• IEC 60601-1-2 – The basic document addresses immunity only in the automotive environment by including test requirements to ISO 7637-02 on direct current power inputs. This is being applied for both general automobile and ambulatory use.
• IEC 60601-1-2 – The basic document addresses immunity testing for environments near RF wireless radio communications equipment.
• Manufacturers should consider applying the emissions requirements of CISPR 25 and ISO 7637-2 for automotive environments. This is being used for both general automobile and ambulatory use.
• Manufacturers should consider applying the emissions requirements of ISO 7137, RTCA DO-160 and EUROCAE ED-14 for aircraft environments. This is being used for both general aviation and medical helicopter use.
• Manufacturers should consider applying the emissions and immunity requirements of IEC 62236-1 for railway environments.
• Manufactures should consider applying ANSI C63.27 for coexistence of wireless systems equipment (cell phones, Wi-Fi and biotelemetry). This is being used to ensure that medical devices which incorporate an RF transmitter AND are used near each other operate correctly in any environment.
• Product specific standards exist for specific types of medical electrical equipment and systems (endoscopic, infusion pumps, electrocardiograph, ultrasonic equipment etc.) that must be considered. In many cases these standards alter the basic requirements within IEC 60601-1-2.

Key takeaways

The world of medical devices is dramatically changing how medical electrical equipment and systems are being used in various environments. Many different EMI/EMC standards need to be considered to address all environments of intended use.

Parker Chomerics Test Services, in association with Parker Chomerics Applications Engineering can assist in determining what standards should be applied to your medical electrical equipment and systems and help ensure compliance to the requirements. Our extensive experience in solving EMI/EMC test failures will result in manufacturable solutions which will reduce your time to market.

 

 

 

 

 

 

 

 

 

 

 

 

This blog was contributed by Jarrod Cohen, marketing communications manager, Parker Chomerics Division.

 

 

 

 

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You are working on a new design and want to incorporate the sealing system directly – in 3D including a design space proposal? In Parker Prädifa´s CAD library, 3D step files are available for you to download.

CAD models as 3D Step files for numerous standard products are available on our product pages at www.parker.com/praedifa (or via the “CAD Library” quick link).

This makes it possible for design engineers to import Parker Prädifa seals and the matching design spaces as models directly into CAD designs for a full representation of the system. The CAD bill of materials then automatically includes the seal’s part number. This creates greater transparency and allows the parts to be traced in the system.

As a special benefit the sketch of the design space proposed by Parker Prädifa for the selected profile already exists in the model. This precludes the risk of mistakes in dimensioning the design space and further facilitates the concept design of the total system for the design engineer.

 

This blog was contributed by Michael Pavlou, market unit manager fluidpower, Engineered Materials Group Europe, Prädifa Technology Division

 

 

 

 

 

 

 

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As the case is across many sectors, electronics systems are the primary drivers of innovation in today‘s agricultural industry. However, those working in this sector may have noticed that any major strides forward in past years have been somewhat hampered by a lack of compatibility between proprietary solutions from different manufacturers.

Fortunately, more recent solutions have been based on ISOBUS, bringing significant benefits to end applications and their users. And now, with the latest technology, combining HMI solutions for both ISOBUS functions and other tractor HMIs are leading to the possibility of just one, convenient, cost-effective and efficient interface for the operator.

Modern ISOBUS systems

A modern ISOBUS system comprises a multitude of components, including the tractor, terminal and implement. Taking this concept a step further, an industry first from Parker’s perspective, the ISOBUS Suite Apps enable the integration of ISOBUS functionalities into the machine HMI (Human Machine Interface), via the app-based Pro Display product family.

Using the apps, ISOBUS functions can be shown on the screen. Since the display offers full flexibility and can show comprehensive information – including machine data, notifications, camera monitors, PDFs and more – no separate ISOBUS display is required.

Changing the landscape

Farmers have been forced to toil with tractors, implements and machines from various manufacturers on a daily basis. The variety of proprietary solutions meant that many systems did not engage seamlessly or even at all. This disunity saw each implement and tractor requiring an individual terminal to allow data exchange and machine control – a situation that was far from ideal.

Systems based on ISOBUS and utilising tools such as Parker’s ISOBUS Suite apps are driving a shift in the agricultural landscape, making it possible to achieve higher levels of productivity with less operator fatigue.

Using these latest electronic systems, operators can now control and monitor practically every stage of the agricultural process, including tilling the soil, planting seeds, irrigating the land, cultivating crops, protecting them from pests and weeds, harvesting, threshing grain, feeding livestock, and sorting and packaging the products.

How it works

In its basic form, the technology facilitating this capability is ISOBUS, an international communications protocol for the agricultural sector that offers plug-and-play functionality and – importantly – only one terminal for a large selection of implements, regardless of the manufacturer. Sounds a lot easier already. Put simply, ISOBUS standardises control settings, reduces downtime and minimises installation and interface problems.

Crucially here, a standardised plug makes it remarkably easy to connect different components, while costs are reduced because it is only necessary to buy a single terminal. Who doesn’t like cost savings? A further benefit of ISOBUS is that it improves operating efficiency and optimises timings, as data can be exchanged between the farm PC and the terminal. With ISOBUS, life on the farm is certainly a whole lot easier; but it could even better.

By utilising Parker’s UX Toolkit – an apps-based software development environment that can be used to develop HMI products for mobile machines and vehicles – and the split-screen functionality, manufacturers can display further machine data and camera monitors right next to the ISOBUS information.

Machine manufacturers can expand the functionality of a device with ease. HMI apps offer an advantage when trying to make mobile machines more efficient, when guaranteeing flexibility in terms of expanding functionalities, and when simplifying processes in the driver’s cab. Less downtime is achieved via diagnostics apps for service code protocols, data capturing and analysis, GPS tracking and geo-fencing, as well as by apps that enable mobile phone hands-free functionality, driver logbooks and operating behaviour tracking.

The UX Toolkit, together with the Pro Display family, also supports functions such as automatic steering, self-levelling suspension and weighing. In addition, the robust displays with capacitive touchscreens are equipped with multiple communications and infotainment interfaces. In short, an apps-based future looks set to enhance the agriculture industry in ways never before imagined.

Learn more about Parker's ISOBUS Suite apps and Pro Display. 

 

Tommi Forsman, principal engineer, Parker Hannifin, Electronic Controls Division

 

 

 

 

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