Thank you to our team members for their hard work and dedication to our success. Without you, our success would not be possible.

Happy Labor Day!

Labor Day, celebrated on the first Monday of September, has evolved beyond its historical roots of advocating for workers' rights and fair working conditions.

In today’s modern work environment, it serves as a vital reminder of the invaluable contributions made by our employees at all levels. This day allows us to pause and reflect on the efforts of our workforce, recognizing that the success of our organization is deeply intertwined with the dedication and hard work of our employees.

Western Integrated Technologies recognizes the importance of our employee's well-being, work-life balance, and job satisfaction. Labor Day is not just a holiday; it is an opportunity for us to show our appreciation and reaffirm our commitment to creating a supportive and rewarding work environment.

Our business's achievements and milestones are a direct result of the collective efforts of our employees. From innovative ideas to relentless execution, our employees are the driving force behind every success story. Labor Day provides a perfect occasion to say thank you to all our team members—you make it all possible.

 

In August 2024, Parker announced changes to several styles of their Ultra-High-Pressure hoses. The changes are highlighted below.

PFX40 Series Hose Replaces 2840D Series Hoses

Effective September 1st, Polyflex PFX40 Ultra-High-Pressure series hose will replace 2840D-03V34 (Red Cover) and 2840D-03V36/14 (Red Cover) hoses. 

Parker will accept orders for the current part numbers until the end of August 2024. 

PFX40 is approved with 2X series permanent crimp fittings. A Toughjacket version is available upon request. The PFX40 hoses offer improved service life and reliability and are ISO 23384/ EN 1829-2 compliant. Also, the PFX40 series hose complies with the WJTA color coding standard with a red cover for 4000 bar-rated hoses.

The table below shows the part number replacement along with updated specs. 

PFX25 Series Hose Replaces 2440D & 2640D Series Hoses

Effective September 1st, 2024, Polyflex PFX25 Ultra-High-Pressure hose will replace 2440D-025V32, 2640D-03V32, and 2640D-04V32 hoses in three sizes:

• 2440D-025V37-TC will be replaced by PFX25-025 
• 2640D-03V37 will be replaced by PFX25-03 
• 2640D-04V32 will be replaced by PFX25-04

Parker will accept orders for the 2440D-025V32, 2640D-03V32, and 2640D-04V32 the end of August 2024. 

PFX25 hose series offers improved service life and reliability and complies with ISO 23384/ EN 1829-2 specs. The PFX25 series hose is also compliant with the WJTA color coding standard with a blue cover for 2500 bar rated hose. Additionally, the part number structure is simplified.

Below is a chart showing the part number replacement along with updated specs. PFX25 is approved with the same fitting series as the replaced products: PFX-025 uses LX series fittings, and PFX25 -03 & -04 uses 2X series fittings.

PFX30 Series Hose Replaces 2740D & 2840D Series Hoses 

Effective immediately, Parker PFX30 Ultra-High-Pressure series hose replaces 2740D-025V30 (Black Cover), 2740D-03V35 (Orange Cover) and 2840D-08V30 (Black Cover) series hoses.

PFX30 is approved with 2X series permanent crimp fittings. If a Toughjacket version is needed, it is available in size -025 upon request. 

PFX30 series hoses offer improved service life and reliability and are ISO 23384/ EN 1829-2 compliant. The PFX30 series hose is also compliant with the WJTA color coding standard with an orange cover for a 3010 bar-rated hose. 

Please see the table below for the sizes and specifications of the PFX30 hose.

2580N-32V80 Series Hose Fittings Conversion

Effective immediately, the new Hammer Union fittings for the 2580N-32V80 hose will replace the 6HE5X-32-32-FLATTC and 6HN5X-32-32-TC Hammer Union fitting options.

The new Hammer Union fittings' part numbers are 1HEBL-32-32-FLAT and 1HNBL-32-32. They will not require the hose to be skived before attaching the fitting to the hose end. They are functional replacements, but there are some dimensional differences.

Please refer to the table below to review the dimensional changes.

PFXGAS10 Ultra-High-Pressure Hose Now Available from Certified Distributors

Effective August 1st, 2024, certified distributors will have the ability to place orders for the PFXGAS10 series hose. The PFXGAS10 series hose is designed for use in general gas applications and NOT gas dispensing/fueling HGV 4.2 applications. There are two options listed below, rated for different pressures, which are to be used with the LX fittings series:

• PFXGAS10-08: 55,825 PSI
• PFXGAS10-04: 60,000 PSI

The PFCGAS10 series has:

• A low permeation rate for gas applications
• A pin-pricked cover to minimize the risk of damage to the hose
• A water test certificate that will be supplied with assembly. Distributor-fabricated hoses are not approved for Hydrogen dispensing or where an application has a mandatory gas test of the Parker-supplied hose.

For more information, download the Parker-Thermoplastic-Hoses-for-Ultra-High-Pressure Catalog.

Recently, Parker Hannifin’s Hydraulic Pump and Power Systems engineers offered a webinar to the OEM Off-Highway readers describing the conversion process from an Internal Combustion Engine (ICE) powered hydraulic system to an electrically powered one.

Here is a recap:

Increased RPM

Increased RPM is a significant factor for OEMs and end-users to consider when moving to electric power. Permanent magnet electric motors can run at much higher speeds than what a hydraulic pump is subjected to when powered by ICE. Plus, they can accelerate and decelerate very quickly and be turned on and off to save energy. 

But more than just speed needs to be considered. Overall hydraulic component performance must be evaluated. For example, cavitation concerns, longevity, or maintenance issues could now occur. Correctly matching the hydraulic pump, electric motor, and inverter in electrified work functions is critical to transitioning to a fully electrified system. Unique operating conditions of any application will also factor into the transition. Extensive testing of components in the system against all these factors can assure system performance and the life of the pump. 

Size

Because electrified systems can spin faster, you can downsize the hydraulics, which will impact the overall size of the hydraulic system versus a traditional internal combustion engine (ICE) system.

Noise

Noise can be a factor after the ICE is removed from the system. The hydraulics or the work function tends to become the loudest part of the application.

Cost

Key considerations are component cost and total cost of ownership (TCO) for the life of the product. For example, more energy-efficient solutions will require a higher up-front investment, but future energy savings will likely offset the higher cost.

Robustness

The pump's life must be aligned with the end user’s expectations.

System Complexity

Understanding all the nuances for the specific electro-hydraulic unit, whether that is displacement control, different cooling loops, etc.

Efficiency

Hydraulic efficiency has always been a high priority in design, but not always the top priority. With battery power being crucial to electro-hydraulic systems, efficiency is a key consideration when determining either battery sizing or runtime.

Available Hydraulic System Architectures and The Pros and Cons of Each

Internal Combustion Engine (ICE) Centralized Architecture

Today, most equipment has either gas or diesel-powered ICE. ICE units have continuous high idle of around 2000 rpm and are sized for the peak power requirement for both work function and driving traction needs. From the work function perspective, these systems have one pump that supports all its functions.

The advantage of the ICE centralized architecture is that it is a proven, robust system with plenty of economical hardware choices. In addition, the ICE architecture has been unchanged for decades, so the industry is highly familiar with it.

The ICE system's cons are the compounding hydraulic and combustion engine losses (such as exhaust and noise) that add to inefficiencies. Couple that with government regulations driving the need to move to a carbon-free energy source, like electricity, and the trend to move away from this type of architecture increases.

Electrically Powered Centralized Architecture.

Another type of architecture that is a good fit for future electric power is a centralized architecture with an electric motor drive. One benefit of this system is the ability to share a significant amount of the existing work function through your valves, cylinders, and hoses. While you cannot simply remove a diesel engine and replace it with an electric motor, and system analysis is required, you can still reuse a lot of your work function system.

A centralized electric pump commonly powers these types of systems. Permanent magnet AC motors can spin from 0 RPM during a shutdown case to up to 8,000 RPM. In some cases, you can fully decouple the traction and work circuits so that when one circuit is not needed, the unused system can be shut off to increase the power of the other. For example, when the traction circuit is not needed, all the power can be used by the work circuit. 

This system’s purpose is to provide better energy input with more efficient outputs. This is achieved by using your electric motor’s controls and finding optimum shaft speeds of pumps and motors to reduce system losses.

One disadvantage of this system is that the inefficiencies of a centrally powered system still exist. Pump and valve losses and the need to cool the hydraulic circuit will still occur. With that said, the electrically powered centralized architecture is still a good compromise between a traditional ICE and a fully electric-powered system.

Electrically Powered Decentralized Architecture

The most efficient architecture option moving forward is a decentralized electrically powered architecture.

The architecture with multiple point-of-use electrohydraulic pumps, electric motors, and hydraulic motors located at the actual load where power is required provides significant efficiency gains, as well as opportunities for better matching the electrohydraulic pumps with the requirements of working circuits they power.

This system includes the ability to regenerate energy and achieve overall better energy efficiency through cooling losses and the reduction of components, including pumps and valves. The top benefit is better system control and more ideal energy utilization.

The con, however, is that OEMs must consider a significant amount of hardware rework and changes to controls. In addition, the ability to turn on and off individual electrohydraulic actuators or pumps at each load will present a significant learning curve to all involved.

The advantages of a decentralized system

A decentralized system is more efficient than both an ICE system and an electrically powered centralized system. It provides point-of-use power, and each component can be optimized for its specific task rather than sharing requirements with a single pump. Decentralizing these systems also allows for reductions in the line, pumping, and relief losses, which can reduce the amount of non-value-added work.

In addition to improving or optimizing system efficiency, a decentralized system can provide longer battery life. For example, if a full battery electric system is needed, reducing or regenerating energy like a hybrid or fully electric car can be achieved with a decentralized system.  

Depending on the load cycle, a decentralized system can dramatically improve the battery life, and reduce the need for larger batteries or the quantity of batteries used on equipment. 

Finally, a decentralized system offers separate shut-off systems, allowing the ability to turn off any function when not in use, resulting in less energy waste and greater overall system efficiency. 

You can view the webinar here: How To Take a Calculated Leap to an Electrified System with Electro-Hydraulic Pumps (parker.com)

Parker Hannifin’s Hose Products Division announced phase two of the launch of the 807 Push-Lok EPDM-P Hose. Phase two adds 1/2 inch, 5/8 inch, and  3/4 inch sizes to the 807 series hose with black cover, in addition to the already available 1/4 inch, 3/8 inch, and 1 inch sizes.

The phase three release is coming soon. It will introduce the 807 series hose in all sizes with blue and red covers.

The 807 Push-Lok EPDM-P hose facilitates the transfer of air, water (including PCW), and coolant solutions. It features an engineered peroxide-cured EPDM tube, that is designed to ensure fluid purity, thermal resistance, and superior sealing capabilities within thermal management systems. The synthetic rubber cover is specially compounded for flame and ozone resistance. And of course, the 807 Push-Lok EPDM-P hose features the unique Push-Lok seal system for easy assembly and to ensure reliable, durable, and leak-free service.

807 Push-Lok EPDM-P Hose Specifications

• Tube: Black EPDM, peroxide-cured
• Reinforcement: One fiber braid
• Cover: Black, synthetic rubber; smooth finish
• Temperature Range: -40°F to +212°F (-40°C to +100°C)
• Brand Method: White ink
• Brand Example: Parker 807-16 PUSH-LOK EPDM-P 
• WP 1MPa (100 psi) 25,4mm (1”) 
• UL94 V-0 HOSE COVER MADE IN THE USA
• Engineered to work with Parker 82-series couplings

Parker Fluid Connector Group (FCG) has recently announced a material change to a another group of fittings. The 250IFD fittings will now be manufactured from forgings instead of extrusion, with the new part number being 150IFD.

This strategic move towards complexity reduction by transitioning to forged fittings will result in some minor changes in appearance, dimensions, and weight. However, there will be no impact on the product's function or performance. Part comparison drawings can be accessed on MyParker or requested from FCG.