Technologies

A subsystem is a self-contained module within a larger system. Often in the life sciences marketspace, manufacturers look for partners that specialize in a specific industry to design and supply subsystems for their larger system. This allows their engineers to focus on other aspects of their device while outsourcing subcomponents inside a larger system. When looking for a partner to provide subsystems and components one should look for expertise in the field with decades of industry experience. A single provider of the components is ideal too as this makes less work when managing inventory and ordering, as well as minimizing time coordinating with a partner's customer service team.

Parker Hannifin's Precision Fluidics Division is unique in the customized subsystem solutions it can provide. Precision Fluidics is the global leader in providing miniature fluidic components and is predominantly focused on the life science market. The Precision Fluidics portfolio includes miniature pneumatic proportional and liquid control valves, diaphragm pumps, thermal mass flow controllers/meters, electronic pressure controllers, high-precision regulators, and rotameters. Parker can integrate the full range of its technologies into engineered subsystems. This can reduce an OEM’s technical risk, as well as lower its development cost and time. Precision Fluidics engineers have the industry expertise along with the manufacturing and project leadership knowledge to ensure our solutions work seamlessly in your product. This will allow you to focus on your core science and technology and leave the fluidic control systems to Parker.

At Parker Precision Fluidics the engineers get involved in the early design process to provide the greatest value from collaboration and to provided successful product integration. Since we are a single solution provider that can design, prototype, and manufacture, your team benefits from shortened design and production cycles with convenient customer service and single point of contact.

 

What we do

Parker Precision Fluidics is a collaborative engineering partner, working with you throughout your OEM design cycle from concept to design through production and sustaining. Learn about our typical stage-gate project management process:

 

Throughout the entire product lifecycle, Parker works to ensure our customers' return on investment and to drive advancements in the life science industry. 

 

OEM applications experts

Parker Precision Fluidics employs engineers and scientists with extensive experience in the life science market. This enables them to collaborate with customers on an engineer-to-engineer and scientist-to-scientist level, allowing us to clearly understand the requirements and develop solutions in Automation & Motion Control, Miniature Solenoid Valves & Diaphragm Pumps, and Filtration & Gas Generation. Working with Parker Precision Fluidics will ensure low risk/complexity, access to all Precision Fluidics' products, integrated manifolds, fittings, tubing, and check valves.  

With a single solution provider that can design, prototype, and manufacture, you benefit from shortened design and production cycles. By working with a lean enterprise, you will simplify your procedure and enjoy convenient customer service and a single point of contact. 

 

To learn more about Parker Precision Fluidics custom solutions for the analytical chemistry market, visit our webpage.  

 

Service and support

Parker Precision Fluidics lean manufacturing allows them to respond quickly to orders and special requests. PPF's industry experienced sales force, knowledgeable application engineers, and friendly customer service representatives are available for your technical assistance and ordering needs. Parker's worldwide support ensures that your system, plant, or equipment can be serviced and supported anywhere. 

Parker offers customers more than precision-manufactured, reliable parts; they offer a diverse knowledgebase of engineering expertise, as well as the assistance of dedicated customer service representatives. Precision Fluidics has the experience, history of performance, and uncompromising commitment to quality that you can rely on to meet your project schedules. 

Our applications engineering team is always available to provide recommendations and customize equipment to customer specifications.

To learn more, visit Parker Hannifin Precision Fluidics Division or call +1-603-595-1500 to speak with an engineer

 

This blog post was contributed by Bill Schaeffer, senior applications engineer, Parker Precision Fluidics. Bill has been an employee at Parker Precision Fluidics for 25 years. 

 

 

 

 

 

Related content:

Developing Custom Motion Control Solutions

Point-of-Care Testing Requires Microfluidic Precision

How OEMs Can Improve Life Science Instrumentation Performance

 

Battlegrounds Coffee is a small, community-oriented coffee shop in Haverhill, MA. The owners were challenged to find a more efficient and consistent way to deliver Nitro Coffee to their customers.

 

Nitro coffee is the new smooth brew

According to Battlegrounds Coffee, Nitro coffee is the new trend.

It has a soft smooth mouthfeel. It’s like sipping on a Guinness. It gives the sensation that you’ve added cream to it but you haven’t. It looks fantastic poured and cascading in a glass. Nitrogen gas enhances some of the complex coffee flavors that you find in our blends and roasts at Battlegrounds Coffee. Prior to using the generator, we were using pre-charged food-grade nitrogen tanks.

"Tanks were the most difficult aspect of making and maintaining nitro coffee. The pressure gauges on the regulator were faulty indicating you had more nitrogen that was really left. As owners, we would get calls in the middle of the day saying 'Hey, we are out of nitrogen!'

For us, it was a hassle getting those tanks refilled. We had to drive to the local welding shop. We change out the tank 3-4 times per week so you had to assure that was done right and that there were no leaks. It wasn’t an efficient system and was becoming a hassle. The supplier was charging more than $50 per tank for food-grade nitrogen so my payback was very quick."

— Sal DiFranco, Battlegrounds Coffee

 

Nitrogen Generators with on-board compressors for low flow applications provide safety, savings, and convenience.

Parker nitrogen generators completely eradicate the danger, inconvenience, and high costs of truck delivered nitrogen. The hassles of changing high-pressure tanks and the routine interruption of nitrogen supply are eliminated. They offer long-term cost stability by eliminating vendor price increases, contract negotiations, long term commitments, transportation issues and hazmat charges.

Once installed, a continuous supply of high purity nitrogen is available within a few minutes of startup. Nitrogen, unlike CO2, imparts a small bubble that creates an attractive cascade down the side of a glass. More importantly, the small size of the nitrogen bubble creates a smooth, creamy finish on your palate. Consumers report that it is even sweeter than conventional iced coffee.

 

Watch the video interview with Battlegrounds:

 

Meeting the needs of retail coffee establishments

Building on Parker’s history of over 35 years of producing Nitrogen Generators for beverage dispense, we are pleased to offer a nitrogen gas generator specifically designed to meet the needs of retail coffee establishments. Parker Nitrogen Generators eliminate the danger, inconvenience and high costs of truck delivered nitrogen. There is no need to rely on an outside supplier. The hassles of changing high-pressure tanks and the routine interruption of nitrogen supply is completely eliminated. 

Parker Nitrogen Generators are also good for the environment because delivered nitrogen is manufactured using an energy-intensive process and then distributed in smog generating trucks. Parker generators offer long term cost stability by eliminated vendor price increases, contract negotiations, long term commitments, tank rental fees, delivery fees and hazmat charges. Once the generator is installed, a continuous supply of high purity nitrogen is available within a few minutes of startup.

Cold brewed coffee may be enhanced with nitrogenation. Nitrogen becomes infused into the coffee, much like a nitro beer. Nitrogen, unlike CO2, imparts a small bubble that creates an attractive cascade down the side of a glass. More importantly, the small size of the nitrogen bubble creates a smooth, creamy finish in your mouth. Consumers even report that it is sweeter than conventional iced coffee. Imagine the reaction of your customers to a creamy slightly sweet coffee without the need for added cream or sugar! Parker nitrogen generators are ready to operate as delivered with carefully matched components engineered for easy installation, operation and long term reliability. The generators are free-standing and housed in an attractive cabinet with casters.

 

Operation

The Parker DN-6NA Nitrogen Generator is designed to provide a constant supply of nitrogen gas, at a pre-selected purity, flow, and pressure. The system uses proven Pressure Swing Adsorption (PSA) technology with a Carbon Molecular Sieve (CMS) to separate N2 from the atmosphere and deliver it at high purity. The installation consists of simply connecting the plug to a standard outlet and connecting the nitrogen outlet to your coffee dispenser.

The onboard compressor means that there is no need to connect to a source of compressed air. Simply turn it on, and the air is then prefiltered, compressed, and passed through a 0.01 micron filter rated at 99.99%. The air is then passed through the CMS separation bed which captures the oxygen, creating a stream of high purity nitrogen. Lastly, the stream of nitrogen is passed through a sterile grade filter rated at 99.99999+% at 0.01 micron and then sent to the coffee dispenser. The CMS bed is regenerated to remove the captured oxygen and the cycle repeats.

  Nitrogen generator package includes

• Nitrogen generator, filters, controls, and an on-board compressor
• Floor mount on casters
• Automatically shuts down if there is no demand
• Stays in standby mode until more nitrogen is needed
• Environmentally friendly
• Compact - frees up floor space
• Eliminates unexpected shutdowns
• Hassle-free operation
•  Safe and reliable
• UL, NSF, & CE listed
• CB Scheme, CSA, EMC and IEC certified

 

 

 

 

"The Parker DN-6 provides nitrogen without any interruption. It’s always ready. Saved us at least four man-hours per week. It is awesome! We use nitrogen to push Kombucha too. Plug and play. It’s always working and saves us a lot of time. We also pour wine and we keep the wine bottle purged with nitrogen to keep it fresh. We are also looking at using it to pour our beer too.”

— Sal DiFranco, Battlegrounds Coffee

 

"We were always fighting with the tanks to work properly to pour the perfect pour for a nitro cold brew. Since we’ve had the nitrogen generator it has been easy breezy. With a generator, you don’t have to worry about it. You set and forget. We never have to tell customers 'Sorry we aren’t pouring today.' The pour looks great, tastes even better.”

— Dana, Battlegrounds Coffee

 

To learn more about self-contained nitrogen generators for nitro iced coffee, download a copy of the case study and call Parker today at 1-800-343-4048. 

 

Article contributed by the Gas Generation Team.

 

Additional articles on this topic:

Nitrogen Gas Generators Save Winemakers Time and Money

Consumers and Roasters Benefit from Coffee Packaging with Nitrogen

Top Frequently Asked Questions About Nitrogen Generators

Careful and correct sensor installation is vital if accurate and reliable information is to be measured and communicated from the sensor. 

What all engineers want when it comes to sensor installation is a simple, secure and rapid assembly process, without complicated processes such as the need for additional mountings. 

The P8S proximity sensor offers universal use, flexible integration and excellent form. Its square design is also suitable for rapid installation in industry-standard T-slots, regardless of cylinder profile or brand. The upshot of this direct, drop-in design – as opposed to ‘turn-in’ or ‘slide-in’ concepts – is a significant reduction in installation time. 

Among the innovations with the P8S are retaining ribs on the side of the sensor body that enable simple mounting, including hard-to-reach locations or overhead assemblies. These ribs ensure the sensor conveniently holds its position in the T-slot even before the screw is tightened.

To begin the installation, simply slide the sensor into the T-slot. When in the desired position, a quarter-turn of the eccentric stainless steel screw is all that is required to secure the sensor. To further simplify mounting, the screw head design is such that it accepts either a flat-blade screwdriver or Allen key. The mounting screw even features a knurled head that helps to withstand shock or vibration.

Of course, not all cylinders have T-slots. With P8S sensors this is not a problem as they also mount externally to cylinders. As a result, fitment to round, tie rod and profile cylinders are straightforward.

To make life as simple as possible, every P8S sensor is delivered with a specific adaptor to suit dovetail grooves. Also available are special brackets for round and tie-rod cylinders. The concept is to provide one sensor for all actuator types and brands - not just Parker units.

Cables are be supplied in three or 10 metre lengths (flying lead) or 0.3 metres with an M8 rotating plug, as standard. 

Ultimately, automation demands excellent functionality and precision, which in turn requires solid expertise and knowledge at all levels, including best-practice installation. 

 

Learn more

To discover more about Parker P8S sensors and benefits they can deliver, watch this video:

 

This article was contributed by Franck Roussilon, product manager, Pneumatic Division Europe, Parker Hannifin Corporation.

 

 

 

 

Related content

Three Things to Consider When Choosing a Smart Sensor

Easy Steps to Installing and Configuring a CPS Sensor

Know Your Pneumatics: Continuous Position Sensing

How to Install Pneumatic Cylinders to Maximise Life and Performance

Know Your Pneumatics: Selecting a Pneumatic Cylinder | Operating Environments

Not everyone is familiar with all the intricacies of HVACR as we are at Parker Sporlan and that’s okay. Whenever you have questions, you can always contact our world class Technical Support team or check Parker.com/Sporlan for in-depth information and guidance. Our Climate Control Blog has many of the answers you need for questions on most topics, so dig in. Below, we’ve answered some of the most frequently asked Thermostatic Expansion Valve (TEV) questions – you’ll find easy answers to your need-to-know questions.

  Where should the TEV external equalizer be installed?

The purpose of the external equalizer is to sense the pressure in the suction line AT THE BULB LOCATION and transmit it to the TEV diaphragm. This usually means installing the external equalizer immediately down stream from the bulb. This ensures the correct pressure is signaled to the TEV. In some situations, this “ideal” location may not be possible. In these cases, an alternate location could be used. However, the pressure at these locations must be nearly identical to the pressure in the line where the bulb is located. In other words, alternative locations are acceptable as long as these pressures are essentially the same as when the system is operating at full load. In the past there has been concern about installing the external equalizer “up-stream” from the bulb. This was due to the possibility of refrigerant leaking past the TEV push rods, passing through the equalizer line and into the suction line, thus falsely influencing the TEV bulb temperature. Today, with Parker Sporlan’s TEV design, this possibility is virtually eliminated.

  Where should the TEV’s bulb be located?

In general, the TEV bulb should be installed on a straight section of horizontal suction line. When the compressor is above the evaporator – Locate the bulb on a straight, horizontal line, pitched slightly down, immediately after it leaves the evaporator. A short trap should follow before the vertical line rises to be connected to the compressor suction. With the line pitched down, any liquid refrigerant and/or oil will pass into the trap, away from the bulb. As the trap fills with oil, the velocity of the refrigerant will carry the trapped oil into the vertical section and be returned to the compressor. When the compressor is below the evaporator – No trap is required after the bulb location, but the line should be pitched slightly down to prevent any liquid refrigerant or oil from being trapped at the bulb location. When several evaporators are installed both below and above the common suction line – Observing the same principles outlined above, the piping should be arranged to prevent the accumulation of oil and/or refrigerant at the bulb location. Also, traps installed in the suction lines of evaporators prevent the refrigerant from one evaporator from entering the suction line of another evaporator.

  Should a Parker Sporlan Thermostatic Expansion Valve (TEV) be adjusted after installation?

Before leaving the factory, a specific superheat setting is made on each and every Parker Sporlan TEV. A standard superheat setting has been established for every size and every thermostatic charge. This standard-setting provides the proper superheat on the average system to which the particular TEV size and charge is likely to be applied. Therefore, in most cases, a superheat adjustment on the job will not be necessary. Parker Sporlan recommends a change in the superheat adjustment only after it has been determined that it is required. Careful measurement of the operating superheat, using the recommended procedure, will establish if a change would be beneficial. To reduce the superheat, turn the adjusting stem COUNTERCLOCKWISE. To increase the superheat, turn the adjusting stem CLOCKWISE. When adjusting the valve, make no more than one turn of the stem at a time and observe the change in superheat closely to prevent over-shooting the desired setting. On adjustable TEVs, Parker Sporlan attempts to position the adjusting stem at the half-way point when it is at the standard-setting. This allows maximum adjustment in both directions. Parker Sporlan supplies a number of OEMs with non-adjustable TEVs. The OEM determines the superheat setting through laboratory testing of the unit. Some of these valves can be converted in the field to adjustable models.

  How can I tell if my TEV is adjustable?

Most of the TEVs listed in Parker Sporlan Catalog 201 or Bulletin 10-10 will be adjustable unless there is an “N” stamped in the valve body as part of the nomenclature (i.e. NSVE-5). Many of the valves made specifically for OEM customers are non-adjustable. One way to tell if a valve is adjustable or non-adjustable is to look at the bottom cap. Adjustable expansion valves will have a threaded joint between the valve body and bottom cap as well as a threaded joint between the bottom cap and a hex seal cap that is removable to expose the adjusting stem. Non-adjustable valves, on the other hand, will generally have only one threaded joint between the valve body and bottom cap. An exception to this rule is a factory adjustable valve with two threaded joints and a smooth, round non-removable seal cap. Many non-adjustable valves can be converted to adjustable by changing the bottom cap assembly. Contact Parker Sporlan’s Technical Support department for more information. They will need all the information you can get from the valve’s markings to assist you. CAUTION: Never attempt to determine if a valve is adjustable by removing the bottom cap assembly unless the system has been pumped down, it could result in serious injury.

  Can I replace the powerhead on my Parker Sporlan TEV and how do I know what to get?

With a few exceptions, most Parker Sporlan thermostatic expansion valves manufactured after 1993 have replaceable thermostatic elements. The exceptions are valves with an “H” before the valve nomenclature (i.e. HSVE-10), the now obsolete Platform valves, and the relatively new HX valve. The Platform and HX valves can be identified by a stainless steel element. The valves with the “H” in the nomenclature have had the elements soldered to the valve body at the customer’s request. Parker Sporlan makes replacement element kits that are available through Authorized Sporlan Wholesalers. The thermostatic elements on Parker Sporlan expansion valves are identified by a series of numbers and letters. The number (i.e. 33, 43, 83, etc.) identifies the element size, while the letters (i.e. VGA, RC, JCP, etc.) identify the refrigerant and thermostatic charge. A replacement element kit can be obtained based on that information. For example, a valve with markings on the element of 83 and VCP100 will require a KT-83-VCP100 element kit. (For more information on element identification, consult Bulletin 210-60.) If markings on the element are no longer legible, contact Parker Sporlan’s Technical Support team for help in selecting a replacement element. They will need all the information available from the valve body, and a description of the application. To completely identify a Parker Sporlan thermostatic element the following information is required:

• Element size number

• Refrigerant Thermostatic charge

• MOP (Maximum Operating Pressure) if other than standard E

• Capillary tubing length

• Bulb size if other than standard

For more information on Thermostatic Expansion Valves (TEVs) download a copy of Bulletin 10-10. For more troubleshooting information download a copy of 12 Solutions for Fixing Common TEV Problems - Form 10-143.

 

HVACR Tech Tip Article contributed by Jason Forshee, application engineer,  Sporlan Division of Parker Hannifin

 

 

 

 

 

Additional HVACR Tech Tips helpful for you: 

HVACR Tech Tip: Basic Troubleshooting Given Three Measurements

HVACR Tech Tip: Principles of Thermostatic Expansion Valves

HVACR Tech Tip: Where Should the TEV External Equalizer Be Installed?

Not everyone is familiar with all the intricacies of HVACR as we are at Parker Sporlan and that’s okay. Whenever you have questions, you can always contact our world class Technical Support team or check Parker.com/Sporlan for in-depth information and guidance. Our Climate Control Blog has many of the answers you need for questions on most topics, so dig in. Below, we’ve answered some of the most frequently asked Thermostatic Expansion Valve (TEV) questions – you’ll find easy answers to your need-to-know questions.

  Where should the TEV external equalizer be installed?

The purpose of the external equalizer is to sense the pressure in the suction line AT THE BULB LOCATION and transmit it to the TEV diaphragm. This usually means installing the external equalizer immediately down stream from the bulb. This ensures the correct pressure is signaled to the TEV. In some situations, this “ideal” location may not be possible. In these cases, an alternate location could be used. However, the pressure at these locations must be nearly identical to the pressure in the line where the bulb is located. In other words, alternative locations are acceptable as long as these pressures are essentially the same as when the system is operating at full load. In the past there has been concern about installing the external equalizer “up-stream” from the bulb. This was due to the possibility of refrigerant leaking past the TEV push rods, passing through the equalizer line and into the suction line, thus falsely influencing the TEV bulb temperature. Today, with Parker Sporlan’s TEV design, this possibility is virtually eliminated.

  Where should the TEV’s bulb be located?

In general, the TEV bulb should be installed on a straight section of horizontal suction line. When the compressor is above the evaporator – Locate the bulb on a straight, horizontal line, pitched slightly down, immediately after it leaves the evaporator. A short trap should follow before the vertical line rises to be connected to the compressor suction. With the line pitched down, any liquid refrigerant and/or oil will pass into the trap, away from the bulb. As the trap fills with oil, the velocity of the refrigerant will carry the trapped oil into the vertical section and be returned to the compressor. When the compressor is below the evaporator – No trap is required after the bulb location, but the line should be pitched slightly down to prevent any liquid refrigerant or oil from being trapped at the bulb location. When several evaporators are installed both below and above the common suction line – Observing the same principles outlined above, the piping should be arranged to prevent the accumulation of oil and/or refrigerant at the bulb location. Also, traps installed in the suction lines of evaporators prevent the refrigerant from one evaporator from entering the suction line of another evaporator.

  Should a Parker Sporlan Thermostatic Expansion Valve (TEV) be adjusted after installation?

Before leaving the factory, a specific superheat setting is made on each and every Parker Sporlan TEV. A standard superheat setting has been established for every size and every thermostatic charge. This standard setting provides the proper superheat on the average system to which the particular TEV size and charge is likely to be applied. Therefore, in most cases, a superheat adjustment on the job will not be necessary. Parker Sporlan recommends a change in the superheat adjustment only after it has been determined that it is required. Careful measurement of the operating superheat, using the recommended procedure, will establish if a change would be beneficial. To reduce the superheat, turn the adjusting stem COUNTERCLOCKWISE. To increase the superheat, turn the adjusting stem CLOCKWISE. When adjusting the valve, make no more than one turn of the stem at a time and observe the change in superheat closely to prevent over-shooting the desired setting. On adjustable TEVs, Parker Sporlan attempts to position the adjusting stem at the half-way point when it is at the standard setting. This allows maximum adjustment in both directions. Parker Sporlan supplies a number of OEMs with non-adjustable TEVs. The OEM determines the superheat setting through laboratory testing of the unit. Some of these valves can be converted in the field to adjustable models.

  How can I tell if my TEV is adjustable?

Most of the TEVs listed in Parker Sporlan Catalog 201 or Bulletin 10-10 will be adjustable unless there is an “N” stamped in the valve body as part of the nomenclature (i.e. NSVE-5). Many of the valves made specifically for OEM customers are non-adjustable. One way to tell if a valve is adjustable or non-adjustable is to look at the bottom cap. Adjustable expansion valves will have a threaded joint between the valve body and bottom cap as well as a threaded joint between the bottom cap and a hex seal cap that is removable to expose the adjusting stem. Non-adjustable valves on the other hand will generally have only one threaded joint between the valve body and bottom cap. An exception to this rule is a factory adjustable valve with two threaded joints and a smooth, round non-removable seal cap. Many non-adjustable valves can be converted to adjustable by changing the bottom cap assembly. Contact Parker Sporlan’s Technical Support department for more information. They will need all the information you can get from the valve’s markings to assist you. CAUTION: Never attempt to determine if a valve is adjustable by removing the bottom cap assembly unless the system has been pumped down, it could result in serious injury.

  Can I replace the power head on my Parker Sporlan TEV and how do I know what to get?

With a few exceptions, most Parker Sporlan thermostatic expansion valves manufactured after 1993 have replaceable thermostatic elements. The exceptions are valves with a “H” before the valve nomenclature (i.e. HSVE-10), the now obsolete Platform valves, and the relatively new HX valve. The Platform and HX valves can be identified by a stainless steel element. The valves with the “H” in the nomenclature have had the elements soldered to the valve body at the customer’s request. Parker Sporlan makes replacement element kits that are available through Authorized Sporlan Wholesalers. The thermostatic elements on Parker Sporlan expansion valves are identified by a series of numbers and letters. The number (i.e. 33, 43, 83, etc.) identifies the element size, while the letters (i.e. VGA, RC, JCP, etc.) identify the refrigerant and thermostatic charge. A replacement element kit can be obtained based on that information. For example, a valve with markings on the element of 83 and VCP100 will require a KT-83-VCP100 element kit. (For more information on element identification, consult Bulletin 210-60.) If markings on the element are no longer legible, contact Parker Sporlan’s Technical Support team for help in selecting a replacement element. They will need all information available from the valve body, and a description of the application. To completely identify a Parker Sporlan thermostatic element the following information is required:

• Element size number
• Refrigerant Thermostatic charge
• MOP (Maximum Operating Pressure) if other than standard E
• Capillary tubing length
• Bulb size if other than standard

For more information on Thermostatic Expansion Valves (TEVs) download a copy of Bulletin 10-10. For more troubleshooting information download a copy of 12 Solutions for Fixing Common TEV Problems - Form 10-143.

 

HVACR Tech Tip Article contributed by Jason Forshee, application engineer,  Sporlan Division of Parker Hannifin

 

 

 

 

 

Additional HVACR Tech Tips helpful for you: 

HVACR Tech Tip: Basic Troubleshooting Given Three Measurements

HVACR Tech Tip: Principles of Thermostatic Expansion Valves

HVACR Tech Tip: Where Should the TEV External Equalizer Be Installed?

Reliable cooling is a decisive factor for production, particularly in the marine industry. It is responsible for ensuring adequate temperatures in the turbine, the electronics racks and on the tool, or the machine, itself. The entire production and product life cycle of elements and machines are dependent on the efficiency of the cooling process and how it ensures ideal operating temperatures.

Parker has a broad program of thermal management components. It stands out thanks to its efficient interplay which is essential for ensuring that cooling circuits work reliably on a permanent basis. Each individual product stands for reliable functionality, durability, high material quality and compact design.

  Parker quick-action couplings are easy and fast to assemble                                                                                     

Quick-action couplings that can be used to connect cooling elements and cables are well suited to the thermal management field. Parker's RNS Series systems for block and panel installation expand the possibilities of design freedom for planning and installation. The series was initially developed for control cabinets to allow fast and reliable coupling and locking of the cooling circuits to the racks. 

It has several benefits:

• Connections made with no additional tools
• Low-pressure drop optimises energy savings without compromise to computer performance
• Greatly reduced size allows installation in small spaces, expanding design possibilities 
• Characteristic flat sealing valve design offers safety to the operator and the electronics themselves and makes an important contribution to environmental protection
• Design prevents air penetration to the medium and prevention of medium leaking during coupling and uncoupling before start of maintenance work on the electronic components or batteries
• Maintenance times are shortened significantly due to quick coupling and uncoupling
• Shut-off couplings allow the fluid to remain in the circuit during maintenance work and does not need to be drained
• Wide range of seals can be selected depending on the medium type and temperature

Another benefit of Parker's quick connection couplings is the variety of materials available. NSA Couplings, for instance, are made of aluminium and correspond with the trend towards lightweight construction. In addition, components made of nickel-plated brass or stainless steel are corrosion-free with a wide range of liquids, while offering consistent quality and long service life, just like the other couplings. Thanks to the different sizes available (3, 6, 9, 12, 16, 19 and 25 mm), couplings can be adapted optimally to the specific cooling circuit. When used in transportation systems, the couplings prove their resistance to vibration and torsional movements.

  Silicone hose minimizes maintenance costs and assembly time

The 6722 Series Silicone hose is an important system element for the heating and cooling applications as they allow to minimize maintenance cost and time and maximize the performance of the system.

The extruded hose meets SAE J20 R3 Class A specification and can be installed as thermal management solution wherever there is a cooling/heating circuit to run efficiently. The low permeation material is suitable for a wide range of coolant fluids and withstands ozone and UV attack more efficaciously than traditional solutions. The series is not only chemical and oxidation resistant but also extremely stable at elevated operating temperatures in engine compartments starting from –54°C to achieve +177°C. It maintains flexibility and elasticity over time. This reduces the risk to crack, harden, or become dry rotted and increases the possibility of installation in narrow and compact spaces, tight envelopes and around an obstruction. Additionally, it offers good ability to dampen sounds and vibrations keeping a quiet and stable profile. All these benefits contribute to an extended service life reducing costs of maintenance, downtime, warranty and logistics while sustaining the performance of circuits and equipment over the long haul.

There is no better choice for today’s trend where there are applications surpassing the temperature capabilities of other rubber solutions on the market. Silicone is the ultimate choice for extreme temperature applications and when flexibility over the lifetime is requested.

  Total system solution

The wide Parker product range for Thermal Management is enlarged by its extensive portfolio of push-to-connect fittings as an alternative to metal screw-on, clip-on and barbed connection technologies. The productivity is increased thanks to quick assembly (connection without tools; no need to weld, glue or crimp).

• Push-to-connect fittings are available in polymer/metal from diameter 4 mm to diameter 22 mm. The fittings can be combined with a variety of flexible tubing materials (PA, PE, PU, FEP, PFA)
• Push-in fittings ensure maximal flow, enable fast and easy maintenance and are 100 percent leak-tested and individually dated in production.
• Series 204-209 KL Coupling Systems stand out for their extremely low leakage rate and a minimum volume of dead space.
• SensoControl sensors help to monitor the stable function of the entire system and to indicate potential sources of error.

Conclusion

Based on its broad product range, Parker develops modular systems in close collaboration with its customers. In addition to individual products, the company also offers ready-to-install systems from coupling to screw fitting, hose or distributor. The benefit for the customers is that they can rely on the supplier’s decades of experience and they can save valuable assembly time thanks to the delivery of complete systems blocks, which in turn greatly simplifies the spare parts stocking process.

 

Article contributed by Georg Kälble, manager marketing service, High Pressure Connectors Europe Division, Parker Hannifin Corporation.

 

 

 

 

Related articles:

Hannover 2019: Partnering with Customers to Increase Productivity and Profitability through Engineering Innovation

Effective Predictive Maintenance of Rotary Machines

How to Choose the Right Quick Coupling