Fluid Power Journal May 2024

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The Power of Listening

LESSONS LEARNED FROM 'CHEERS' TO PARENTHOOD AND BEYOND

» AFTER THE 11 O’clock evening news, they’d play syndicated re-runs of “Cheers”. It started with 3 or 4 guys making “a thing” out of watching “Cheers” regularly. Later it grew out of the standing-room-only space, in Doug and Kyle’s dorm room, and morphed into the TV room in the lobby.

Of course, Cheers eventually ended, and the spin-off “Frasier” picked up.

Dr. Frasier Crane’s famous tagline was “I’m Listening”.

I’ve spent some time “pulling wrenches” doing repairs on machinery. It sounds hard. A mechanic or technician can’t always just

start replacing parts. To diagnose it correctly, you must “Listen” to what the equipment is telling you. Is the pressure low? Is something hot? Is it making a weird noise? Did something slow down? Where is that oil coming from? Does anything you do make it better? Does anything you do make it worse?

I’m listening.

I’ve also spent some time designing and specifying systems. It sounds hard. You need to listen to the desired outcome. How much will this machine weigh empty? How much will it weigh loaded? How fast do you need it to go? Does the operator want this on a joystick button or a toggle switch? Is there a safety concern when THIS happens or THAT happen?

I’m listening.

For a while now, I’ve been involved in sales. It sounds hard. If you cut through the clutter and all the self-proclaimed gurus and experts, “Sales” is nothing but getting good at listening. Why does your customer prefer this arrangement? Would it have any drawback to make this change if you got this other feature? What’s your timeline for completing this project? How will you evaluate the prototype to make sure it’s fit for production? If I went over to engineering and asked Jeff the same question what would he say? If I went out to Service and asked Terry the same question?

I’m listening.

Somewhere along the way, in those last 30 years since “Cheers” re-runs at Ohio State, there are also four little “mini-me” clones of me running around. Parenting is another area

where there are a lot of “experts”. It sounds hard. Listening is important here too. (Some of them are not so fun.) Where does it hurt? Did you fall? Did your sister kick you? (and then the better stuff) … How did you make this neat painting of Stitch? Is that papier-mâché? What do you want Santa to bring you? What do you want to be when you grow up? Who’s your best friend at school? What teacher do you like the most? Do they still have Spelling Bees? Did Uncle Steve buy you guys lunch before he brought you back home?

I’m listening.

Our industry is always changing. That crystal ball can be cloudy. It sounds hard. We can probably listen to what it’s telling us. Is there more emphasis on electrification? Is power density always going to be a thing? How do we pass on what we know? What should we pass on and what SHOULDN’T we? Who are we passing it on TO? What do THEY want to know? What do they NEED to know? What will THEY teach US? What’s going to look different in 30 years? What’s going to look the same in 30 years? What’s going to BE the same but LOOK different in 30 years?

In case you’re wondering, they did a reboot of “Frasier” this last fall, 20 years after the original run of “Frasier” ended and 30 years after “Cheers” ended.

Maybe some things don’t change so much after all. What do you think?

I’m listening.

2024 BOARD OF DIRECTORS President: Jeff Hodges, CFPAI/AJPP, CFPMHM - Altec Industries, Inc.

Immediate Past President: Scott Sardina, PE, CFPAI, CFPHS - Waterclock Engineering Corporation

» CORRECTION NOTICE

Our apologies, a mistake was made in our March 2024 Issue. The graphic shown below was missing and the solution title was incorrect. Everything is correct below and the solution to this Figure it Out, is on page 21.

NEW PROBLEM Foam Injection Machine Overheats

CFPE, CFPS, CFPECS, CFPMT, CFPMIP, CFPMMH, CFPMIH, CFPMM, CFC Industrial Training

» MANY PEOPLE DON’T quite understand “Slip in logic cartridge” valves. The attached circuit is a good example showing a solenoid unloading relief valve. When energized, the valves directional valve the relief poppet will open at its maximum 13.8 MPa (2000 PSI) setting and de-energizing the directional control valve will allow flow to return to tank with a very low pressure drop.

Vice

Marketing: Chauntelle Baughman, CFPHSOneHydraulics, Inc.

Vice President Education: Daniel Fernandes, CFPAI – Hawe Hydraulik

Vice President Membership: Brian Wheeler, CFPAI/AJPP - The Boeing Company

DIRECTORS-AT-LARGE

Bradlee Dittmer, CFPPS - IMI Precision Engineering

Brian Kenoyer, CFPHS - CemenTech

Bruce Bowe, CFPAI/AJPP - Altec Industries, Inc.

Cary Boozer, PE, CFPE - Motion Industries, Inc.

Ethan Stuart, CFPS, CFPECS - Quadrogen Power Systems

Jon Rhodes, CFPAI, CFPS, CFPECS - CFC Industrial Training

Stephen Blazer, CFPE, CFPS - Altec Industries, Inc.

Wade Lowe, CFPS - Hydraquip Distribution, Inc.

Jeff Curlee, CFPE, Cross Mobile Systems Integration

Deepak Kadamanahalli, CFPS - CNH Industrial

Steven Downey, CFPAI/AJPP - Hydraulex

John Juhasz, CFPS - Kraft Fluid Systems

CHIEF EXECUTIVE OFFICER (EX-OFFICIO)

Donna Pollander, ACA

HONORARY DIRECTOR (EX-OFFICIO)

Ernie Parker, Hydra Tech, Inc. CFPAI/AJPP

The problem with the machine overheating seemed to be caused by the relief not unloading when the solenoid operated valve is de-energized during the idle cycle. This causes the full pump flow to return to tank at 13.8 MPa (2000 PSI) pressure drop across the valve’s poppet. This was adding approximately 7° C (14 °F) temperature increase in the flow going back to the tank. The cooler was not designed for this amount of heat being generated.

Examining the directional valve and main relief poppet showed no signs of malfunctioning or sticking. What would you do next?

For the solution, see page 21.

Robert Sheaf has more than 45 years troubleshooting, training, and consulting in the fluid power field. Email rjsheaf@cfc-solar.com or visit his website at www.cfcindustrialtraining.com. Visit fluidpowerjournal.com/figure-it-out to view previous problems.

Considerations for Using Sensors to Control Cylinders

The use of magnetic or inductive sensing devices to indicate cylinder position is nothing new. These proven methods each have their strengths, which we will discuss in this article. There are several factors to consider including environmental conditions, potential for interference, and cylinder integrity.

When examining which technology to use for cylinder position monitoring, a typical starting point is what the cylinder manufacturer already offers as a mounting port for a sensor and what is installed as a potential sensing target. It is common practice to have a dissimilar metal target on the inside of the shaft. This can provide a target for either a magnetic or inductive approach. In some cases, manufacturers even install a magnetic target on the shaft inside the housing, this is however an older approach. Regardless of whether it is a dissimilar metal or magnet; you can use the sensors in different mounting methods.

Magnetic sensors locate the target through the cylinder housing; therefore, they are typically strapped to the outer housing. This makes them popular because they are easier to install. A possible shortcoming of this approach may be that they are not as accurate in determining position as a sensor that is built into the housing. Another potential problem with magnetic sensors is that they can magnetize the housing they are attached to over time. This can lead to a position deviation, which can increase with temperature variations. However, these are only possibilities, as this technology is tried and tested and has been in use for over forty years.

Inductive sensors are installed in the cylinder at the end of travel. Most cylinder manufacturers pre-drill sensor ports today, so it is simply a case of understanding the required process dimensions. This approach has also proven to be very effective and accurate. Possible disadvantages of using inductive sensors can be that there are no current mounting ports. Drilling holes in cylinders can cause major problems, affect the warranty, and incur additional costs. There may also be problems with the required installation location of the sensor or the operating pressures. All of these concerns need to be considered, but again, this technology is proven and has been used for over forty years. A third method is less invasive; the use of linear potentiometers or linear variable differential transformers (LVDTs). These are precise, proven, and sometimes the most inexpensive approach. These linear potentiometers are made up of cylinders with transducer rods having the same travel as the cylinders being monitored. They are mounted on the outside of the cylinder. The transducer rod is attached to the cylinder rod, tracking its movement. These devices monitor the position of the cylinder rods by measuring the change in resistance as the transducer rods change position. They are very effective, but also susceptible to damage to the exposed transducer rod. They are the oldest of the sensor technologies and have been used in the paper and textile industries for over eighty years.

The latest method is also non-invasive. It combines the precision and repeatability of an inductive sensor with the simple mounting of an LVDT. Linear inductive sensors came onto the market around twenty-five years ago. Unlike the aforementioned devices, only a target is mounted to the cylinder rod. The linear sensor is mounted next to the cylinder near the target. As the cylinder shaft travels over a row of sensor coils, it provides position feedback. As a rule, it can also provide end of travel or preset positions. Although this may not be the solution for everyone, this approach is becoming increasingly popular.

Once the sensing method has been selected, a decision must be made as to what type of control system is desired. While programmable logic controllers (PLCs) are the most common in industrial control, microcontrollers (MCUs) or dedicated process controllers are not uncommon in fluid control. Each of these devices can process sensor data and make decisions based on predefined logic. To choose the right sensing method, you need to know what is required in terms of discrete or analog inputs.

You now have determined the preferred type of position sensing and the type of signal processing that will be used to monitor and control the system. From here, a general understanding of the available sensor outputs will help finalize the application design. For a magnetic sensor, a mechanical Reed switch or dry contact is typically used. The two-wire circuit is energized, and when the magnet is applied, it closes the contact, creating a complete circuit.

An inductive sensor is a solid-state device that provides a discrete transistor output. This can be in the form of a voltage/current change for a two-wire sensor or a separate output signal for a three-wire sensor. Discrete two-wire sensors are older in design and have a simpler wiring scheme, but they have a constant voltage and leakage current flowing through them. While a single sensor in a no-load state will not generate enough leakage to send a false input to a typical modern processor, care should be taken to avoid connecting several of these sensors in series as leakage levels can multiply. For inductive three-wire sensors, this problem is avoided by the addition of a third output wire.

Another consideration with inductive sensors is the fact that their processing circuits are built with bipolar junction transistors for amplification and switching. These transistors come in two main types: NPN (negative-positive-negative) and PNP (positive-negative-positive). When choosing the right sensor for your control system, it is important to understand the differences in the application. A good way to understand is to look at the current flows for both. In an NPN transistor, most of the charge carriers are electrons, with current flowing to the positive side. In a PNP transistor, most of the charge carriers are positive and current flows to the negative side. Your control system will indicate which type of signal it requires as an input, so always confirm this.

We have now looked at sensing methods and outputs. We should discuss the typical control logic of a standard cylinder circuit. In most cases, sensors are used to indicate the end-of-stroke operation of the cylinder. This tells the system and the operator whether the cylinder is fully extended or fully retracted. In some systems, an analog signal is used to indicate a variable extended position, but the basic method of operation remains the same. The process begins with a start signal provided by either a sensing point, a manual switch, or even a PLC signal. Once the signal is received at the control device, either a PLC or a dedicated controller, a sequence of operations begins. These operations activate a directional control valve that controls the direction of air or liquid. The control valve determines whether the cylinder extends or retracts.

In response to this start signal, the control element sends a signal to the directional control valve of the cylinder, causing the cylinder rod to move to the desired position.

As soon as the cylinder rod is in motion, the sensors detect the position of the rod and

give the control element feedback about the full extension or retraction. This "feedback loop" determines the exact positioning of the control element and enables decisions to be made as to whether it should continue, stop, or change direction. The control element then acknowledges the end of the cycle and generates a stop signal.

This typical control circuit offers the option of adding safety features such as emergency stops into the circuit. Now reset circuits and redundant circuits may be added based on the

functional safety requirements of the application. Through the use of visual indicators, such as lighting or an HMI, system maintenance and training can be integrated. The use of “intelligent sensors”, provides information that is useful for predictive maintenance. Such a well-tested control design is far from obsolete. New advances in sensor and control technology enable reliable, precise control of cylinders with many mounting options. It all starts with the question: What do you want to do? •

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In the unique world of mobile and industrial hydraulics we often find ourselves needing to synchronize torque and speed when using multiple motors. This sounds like a simple idea, and in a perfect world there would be a simple solution. However, we all know that very few things in hydraulics are as simple as they appear, fortunately, with the use of 1:1 ratio counterbalances, torque and speed synchronization can be easily accomplished.

One of the earliest fundamentals we learn as we enter the world of hydraulics is the difference between parallel and series circuits. Once we have identified an application requiring speed synchronization of motors the first idea that pops in our minds is a series circuit. Simple right… Problem solved?

Fortunately, around the same time we learned about series and parallel circuits, we also learned about efficiencies. Hydraulic motors are great at transmitting large amounts of power in a small package, but nothing is perfect in hydraulics and there are mechanical and volumetric inefficiencies to consider. As hydraulic designers, we must account for these inefficiencies. Electronic and proportional technologies are rapidly advancing, and we often use them for precise speed and/or force control. By using speed sensors, we could electronically close-the-loop and achieve precise

control. This sounds great at first, but these solutions are typically expensive and require expertise to apply.

So how can we achieve speed synchronization in applications that are sensitive to price pressures? Let’s consider an example of a four-wheel machine that is propelled via two hydraulic motors. We would like both motors to turn at the same RPM with the same amount of torque. Once again, this sounds simply accomplished by using two motors in series with some means of controlling speed. The flow out of the first motor will be supplied to the second motor and they should have identical RPMs, correct? Unfortunately, due to ever present inefficiencies, this solution will have limited performance. The second motor will not be supplied the same amount of flow as the first due to volumetric losses internally through a case drain. Due to the flow loses, we would expect the second motor to turn slower than the first.

Now imagine we have 100% volumetrically efficient motors. If we have the same amount of flow entering motor number two as motor number one, should we not expect the same torque out of both motors? Unfortunately, motors are hydromechanical devices and even with advances in materials and machining technologies, having two motors with identical mechanical efficiencies is highly unlikely, if

not impossible. Therefore, we must assume that the pressure drop required across each motor just to get it to turn without a load will be different. In a perfect world the pressure drop across each motor will be half of the pressure drop supplied to the first motor. In reality this is not the case.

TM1lbf-ft=p1-p2VD [psi∙cm3rev]1235

TM2lbf-ft=p2-p3VD[psi∙cm3rev]1235

The torque output form M1 and M2 are not equal since the flow into M2 is less than the flow into M1 because of losses like the case drain. Therefore, in order to have equal torque on both motors, some compensation for losses must be considered. Similar to hydraulic fan drives, another approach to motor speed control is to use pressure control instead of flow control. If we again imagine a 100% volumetric efficient motor and we were somehow able to get identical mechanical efficiencies, we should expect identical torque and speed if each motor is supplied the same flow. By using 1:1 pilot ratio counterbalance valves we can supply the same torque to each motor.

The circuit above shows two bi-directional motors in series with the addition of a 4-port vented 1:1 pilot ratio counterbalance valve with a mechanical setting of 400 psi. The counterbalance is used as a relief or compensator between P1 and P2. Port 4 is connected to port 2 which causes downstream pressure to be additive to the setting by a factor of two (1+Pilot Ratio) * Back Pressure. With a low setting of the counterbalance, the pressure at port 1 is

continued on page 12

continued from page 11

2 times greater than the pressure on port 2. The counterbalance will open when pressure between the two motors falls below the pressure upstream of the first motor, ensuring equal pressures and equal torques from each motor. The checks in the circuit prevent a short circuit back to tank and they also allow for a single counterbalance to be used for bi-directional motors in series.

To further explain how this circuit performs, let’s assume both motors have a 1,000 psi induced load. When the directional control valve is shifted and flow is directed to port A and Motor 1, pressure will build to overcome the induced loads of both motors. If our motors were 100% efficient, we would expect to see 2,000 psi on G1 and 1,000 psi on G2, with 1,000 psi ΔP across each motor, creating identical torques and speeds. As reminded earlier, motors are not 100% efficient, therefore, we will closely examine the benefits of adding the 1:1 counterbalance valve. The scenarios below assume the system relief or pump compensators are set higher than the maximum achievable effective setting, and a return line pressure of 200 psi.

In Figure 4, as both motors begin to rotate, Motor 2’s 1,000 psi load

However, in this case we have a vented counterbalance valve and pressure at port 4 has the same effect to the setting as backpressure on a non-vented counterbalance. We are using this to the modulate flow as the loads change by dynamically changing the effective setting of the counterbalance to maintain the p1 and p2 within a small difference in pressure. Starting with a 400 psi mechanical setting, we would expect the counterbalance to have an effective setting of 2,800 psi = (400 psi setting + ((1:1 +1)*1,200)). The counterbalance will remain closed as long as the pressure at G1 is below 2,800 psi. If both motors are rotating at the same rpm and torque with all forces in equilibrium, we would expect the counterbalance to remain closed with 2200 psi at the inlet of the first motor, 1200 psi at the inlet of the second motor and 1,000 psi pressure drop across each.

Considering volumetric losses due to motor leakage, the torque at motor B will be less than the torque of motor A because it has less flow available. Torque is a function of pressure, flow and RPM, and the counterbalance helps maintain torque and rpm by controlling pressure and flow through modulating makeup flow to the second motor in the series. This helps keep the torque nearly equal on both motors.

Tlb-ft=p[psi]∙5252N[rpm]

Php=p[psi]∙Q[gpm]1714

T[lb-ft]=p[psi]∙Q[gpm]1714N[rpm]∙5252

Since the torque available from motor 2 B is less, the torque requirement on Motor 1A and the pressure at G1 will increase. Simultaneously, the pressure at G2 will decrease due to less pressure drop at the lower flow, causing the effective setting of the counterbalance to lower. Once the effective setting is equal to G1, flow will be directed to Motor 2 through the counterbalance valve. The counterbalance will modulate as the effective setting varies due to changes in speed or loads, providing additional flow to Motor 2 while ensuring that G1 is two times greater than G2. By maintaining the same pressure drop across each motor, both motors achieve the same torque and RPM.

Application of hydraulic motors in series is useful when designing equipment but the hydraulic circuit must be carefully considered. Without some means of ensuring that torque is shared between motors, one motor could be overloaded and cause premature failure. The use of a vented counterbalance valve in a novel way provides a means of torque division to load the motors nearly equally in series. •

UNDERSTANDING BREAK-AWAY, RUNNING, & STARTING TORQUE

Amotor has a certain amount of mass that must be accelerated to the speed required to do the work. The object being moved also has some mass. The force to accelerate this mass is referred to as starting torque. There also may be some other resistance that must be overcome. This combination of starting torque and any additional restriction is referred to as break-away torque. For example, an auger moving feed to cattle must overcome its own mass and also the natural stiction of the feed. Once the motor gets up to speed, the resistance drops, and a lower torque is required to keep the load moving. This is running torque.

The stall torque is the maximum motor force, based on the pressure available and the displacement of the motor. It is the resistive force that will cause the motor to stop turning. The stall torque must be higher than the break-away torque but must be limited for the safe operation of the equipment and/or the limitations of the motor.

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The geometry of most hydraulic motors is such that there are variations in torque as the motor rotates. This is called torque ripple. A 9 piston, high speed/low torque, axial piston motor will have 9 pulses of energy for every revolution. At 1,550 rpm, the pulses would be at 232 Hz and may have very little impact. A 6 lobe, low speed/high torque motor at 50 rpm will have a torque ripple of 5 Hz. At this low rpm, this torque ripple sometimes referred to as cogging, may influence process control.

When specifying a motor, it is important to include the maximum necessary starting torque as well as the running torque. If only the running torque is calculated, the motor may stall or be very slow in reaching the proper working velocity. When specifying a motor, it is important to include the maximum necessary break away torque as well as the running torque. If only the running torque is calculated, the motor may stall or be very slow in reaching the proper working speed.

For example, given an auger with a running torque of 400 Nm (3,540 lb-in) at 1,200 rpm, and an available pressure of 21 MPa (3,045 psi), a hydraulic motor must be chosen that can accelerate its own mass as well as overcome the stiction of the of the product being transferred. The manufacturer's specifications say the motor will require an additional 10% pressure for start-up. The product stiction will require an additional 15% torque.

The required breakaway torque for this application is arrived at by multiplying the running torque required by the manufacturer’s data stating that 10% additional torque is necessary to overcome the inertia and mechanical friction internal to the motor which is the starting torque. This starting torque value of the motor is then multiplied by the additional amount of torque that is required to overcome the feed auger at rest which was given at 15%.

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NACOL Accumulators

Wilkes and Mclean is Nacol Accumulators’ North American distributor. Nacol manufactures high quality accumulators that are built to last a very long time. There are many standard features built into Nacol accumulators that make them superior to other manufacturers, such as their one piece pleated bladder. We stock Nacol Accumulators and parts from 1/5 of a pint up to 15 gallons, in our Schaumburg, Illinois facility.

PRODUCT SPOTLIGHT

Electric Clutches for Pumps

Ogura produces a wide variety of electric clutches for mobile applications. These clutches provide simple on/off operation for a variety of pumps. Remotely engaging the pump through the clutch reduces drag on engine start-up, increases pump-life and allows multiple pumps to be used off one engine. Various belt types as well as pump shafts can be accommodated.

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Ogura Industrial Corp.

100 Randolph Road • Somerset, New Jersey 08873

Phone: 732-271-7361

• Fax: 732-271-7580

www.ogura-clutch.com

• info@ogura-clutch.com

DIN Compression Fittings

World Wide Metric offers a wide selection of DIN 2353 compression fittings. These fittings are a high quality product used for fluid power systems joining tubes together. Available in carbon steel and stainless steel with sizes ranging from 4mm–42mm.

Contact them for more information

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sales@worldwidemetric.com

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PMC A&E, INC.

PMC manufactures a wide selection of hydraulic devices, such as pump, motor, valve, and transmission. Items are used for construction equipment, farm equipment, special vehicles, and ships. Various models are available with displacement up to 173cc. All items are made in South Korea.

info@pmcane.com

+1 (213) 221.4556

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3435 WILSHIRE BLVD. STE 2370 LOS ANGELES CA 90010 USA

Accumulators Suppressor

Hydraulic Noise and Shock Suppressor

Wilkes and McLean manufactures an In Line Noise and Shock Suppressor for hydraulics and is a stocking distributor of Nacol Accumulators. Our suppressors eliminate pulsations, which greatly reduces noise and vibration from applications from a few gallons up to 200 gallons. We stock all of our suppressor sizes as well as Nacol Accumulators and parts from 1/5 of a pint up to 15 gallons, in our Schaumburg, Illinois facility. 877.534.6445 | info@wilkesandmclean.com | www.wilkesandmclean.com

Extended Series Breathers

Combining new technology with field-proven product designs, the EX Series disposable desiccant breathers deliver: higher air flow up to 27cfm, larger housing for more desiccant increasing life and capacity, hybrid reliable check-valve technology and new honeycomb oil mist reducer.

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555 Centennial Ave

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• FAX (717) 698-1610

1-800-BEACH-85 • www.beachfilters.com

Proximity position sensing flexibility in one robust package for savings.

Available in reed or electronic sensing elements, the 7000 series features normally open, normally closed or SPDT switch types all in one enclosure. Engineered for successful applications, these sensors are easily mounted with a self-adjusting clamp for 2 to 8 inch bore tie rod cylinders or a band clamp for ¾ to 4 inch round cylinders reducing stocking requirements.

ES Series Electronic Valves

The ES 2-Way and 3-Way valves feature ultra-low leak rates, fast response, multiple flow rates and cycle life of over 1 billion. Clippard’s proven spider technology utilizes one moving part enabling the ES to operate with exceptional reliability

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A4V Piston Pumps & Parts

FluiDyne carries a complete line of A4V piston pumps that are available in displacement of: 40, 71, 125, 180, 250. Our units are used in many different applications: agriculture, forestry machinery, construction, on-highway, commercial vehicles, offshore, marine, wind/ocean energy, automotive and more.

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Stainless Steel Flange Type Ball Valves

Inserta® Products Flange Type, 2-Port Ball Valves, Stainless Steel, provide a simple means to install a ball valve in a circuit that uses SAE J-518 4-bolt flange patterns in both Code 61 and Code 62 patterns.

Internal and external metallic components are stainless steel for use in corrosive environments, or with fluid media that would typically be incompatible with the materials of the standard Inserta® IBF Flange 2-Port Ball Valves. These valves are designed for high pressure service with a 4:1 safety factor to burst. Fastener clearance holes are compatible with either UN or metric fasteners. Product is available to ship from stock.

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Blue Bell, PA

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215.643.0192

Flange Type Bodies For Slip-In Check Valves

Inserta® ICF check valve bodies, flange type, provide a simple means to install a check valve or fixed orifice flow control in a piping system that utilizes SAE 4-bolt flange patterns. These bodies may be used with either the Inserta® ICS disc type or IGS guided disc type check valves. The flange body accepts a valve of one nominal size larger than the nominal size of the flange pattern, and may be considered for low pressure drop application requirements. The valve element may be installed with free flow in either direction. These valve assemblies may be installed on pumps, valves, manifolds, or other components having SAE 4-bolt flange ports. They are all-steel construction.

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J/T Hydraulics & Service Co. Inc.

1601 W. 25th Street • Houston, TX 77008

Local: 713.984.9727 • Toll Free: 800.591.8280

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» HERE IS THE SOLUTION TO FIGURE IT OUT ON PAGE 05

One major problem when troubleshooting logic slip-in valves is that there are exceedingly small orifices found in various areas. Orifice “A” controls the closing speed of the main poppet, while the “C” orifice controls how quickly the main poppet opens. If the “C” orifice, as small as 0.1 mm (0.004 in), is blocked by contamination, the relief will not open as designed causing the overheating problem.

The correct answer to Test Your Skills on page 15 is 1C.

IUnlocking Efficiency

VACUUM CLAMPING FOR DIVERSE APPLICATIONS

have authored numerous articles on vacuum pick and place, a widely used application in fluid power circles for vacuum components. However, another common application for these products is material hold-down or vacuum clamping. Industries like sign manufacturing, glass production, fiberglass fabrication, aerospace CNC machining, and automotive trim finishing utilize vacuum hold-down. This article explores the basic methodology for achieving a secure, safe, and energy-efficient system for these diverse applications, emphasizing the need for rigid hold-down, ease of product capture, release, and cost-effectiveness.

CNC routers, as shown in Fig 1, often use a porous vacuum bed made from porous MDF (medium-density fiberboard) for holding workpieces, like cabinet manufacturing. A large flow vacuum pump, typically an oil-free sliding vane pump or high-performance regenerative blower, connects to a chamber beneath the MDF sheet, creating a vacuum to secure the workpiece. The greater the surface coverage, the higher the vacuum level and holding force. As depicted in Fig 2. to minimize leakage, the uncovered MDF area may be covered with a thin plastic sheet.

The holding force is determined by the vacuum level achieved. High flow pumps are employed, as seen in CNC routers, where the theoretical holding force per square inch is 64N at 100% vacuum. However, lower vacuum levels may reduce the holding force, necessitating additional measures like covering the open MDF area with plastic sheeting.

For applications involving parts with higher cutting forces, such as aluminum machining or marble and granite countertop manufacturing, vacuum "pods" (Fig 3) are commonly used. The parts of the pods are shown in this illustration. 1, vacuum port for workpiece, 2, vacuum port for machine table, 3, high lateral force grip pad (to prevent work piece of machine table movement

in side load conditions from cutting tools) and finally 4, which is a vacuum seal to create the vacuum.

These pods, connected to a vacuum pump or venturi, are used in groups as shown in Fig 4. In cases of thin sheets or non-flat profiles, custom vacuum beds or tools (Fig 5 and 6) may be required.

The vacuum pod, illustrated in Fig 3, boasts a substantial holding force. In this specific example, the model measures approximately 200 mm (8 inches) square, resulting in a holding force of around 3200 N (719 lbs.) at 24” Hg (152Torr). Combining two of these units would naturally double the holding force to 6400N and so forth. It's essential to note that machine coolant on the gripping surface could pose challenges by creating a liquid film, significantly impacting side load resistance. The cusp design of the vacuum pods, depicted in Fig 3.1, effectively mitigates this risk, facilitating the easy dispersal of trapped coolant at each node.

End users often employ continuous "ON" vacuum pumps or venturis for long production cycles. However, for non-porous products like flat aluminum billets, turning off the vacuum once a safe level is achieved offers substantial energy savings. Fig 7 illustrates a multi-stage air-powered vacuum generator with an energy savings "kit" for efficient air control. This cycles on and off as vacuum is required or as the level falls due to a small leak. This can have considerable energy costs savings.

In summary, the landscape of vacuum clamping applications is diverse, with efficiency, user-friendliness, and operational expenses emerging as shared priorities. Through a thoughtful consideration of vacuum tool performance and the adoption of energy-saving practices, users can make well-informed decisions for optimal solutions. The provided examples shed light on various approaches to address the principles of vacuum clamping applications. •

This article, a collaborative effort between Daniel Pascoe, President of Davasol Inc, and Vacuforce LLC, a leading manufacturer and distributor of vacuum components, provides valuable insights. For additional details, please visit www.vacuforce.com or reach out to Daniel at www.davasol.com or dpascoe@davasol.com. Stay connected with Vacuforce on twitter.com/vacuforce.

Small Burrs Create SignificantProblems

Think about "mission critical manifolds" in high productivity, no downtime world.

Windmills and especially offshore installations are excellent examples of costly component failure. Hydraulic elevator platforms are also good examples of critical systems that can be life-threatening in case of failure. But these risks also pertain to various industries or any large machinery.

Leave nothing to chance and use thermal deburring (TEM) to get rid of burrs and particles to ensure that manifolds and valves will deliver without any issues.

By the way, TEM stands for Thermal Energy Method.

After reading that article, you will understand how thermal deburring works, where this technology works best, the pros and cons, and how it compares to other deburring methods.

TEM accommodates materials like cast iron, steel, stainless steel, zinc, aluminum, brass, and some thermoplastics.

Thermal Deburring can take away burrs like a breeze. That breeze is a super heat wave, reaching 3,300°C (6,000°F) in just a few milliseconds.

Methane, a readily available fuel with good energy content by volume, is the most common fuel gas used for thermal deburring. Methane may be supplied technically pure in bottles or through the Natural Gas networks where available.

Hydrogen is also a suitable fuel gas for the TEM process, although less frequently used. Higher volumes are required compared to Methane, incurring higher costs. Hydrogen produces water as the main by-product and can be considered a more environmentally friendly option.

The first benefit of that technology is speed.

Because the burrs or flashings are much smaller than the component, they reach their auto-ignition point instantly. The burrs oxidize in the oxygen-rich chamber without any harmful impact on the element.

Compared to manual deburring, you have the insurance that the deburring operation will run without further inspection. That's reliability. In addition, you remove the burden of finding skilled labor by relying on a machine. You are a perfectionist; the machine can be automatically loaded and unloaded.

The third benefit of that technology is low cost per part.

What does Burrs mean?

Nobody wants burrs. But even with a tremendous effort in design, process planning, and manufacturing, it is hard to ensure that finished parts are completely free from burrs consistently.

The second benefit of that technology is integrity.

The burr? It's vaporized, gone!

Burrs can ruin the design integrity of the part, require additional processes to fix it, cause safety hazards, and result in a malfunction of the product. That generates additional cost, re-manufacturing, warranty, service, and recall, saying nothing of collateral damage to the company's image. No choice. You need to

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workpiece material. The sharpness of the burr may be the most essential criterion for safety concerns.

Burrs Impact.

Today, fluid power is at the heart of many critical areas. It's present in some of the most challenging tasks - control, maneuver, lift, dig, brake, steer, adjust, and many more. At the same time, the demand for higher power, faster response, finer control, and compact sizes has driven modern-day fluid power toward higher operating pressures, intricate designs, and compact dimensions. h

burr-free

burr theoretical workpiece edge overhang sharp-edged

DIN Definition of Burr

Characterization of Burr hr r r bg

h = burr height

hr = burr root thickness

bg = burr thickness

rr = burr radius

In demanding applications, a minor leakage or a total breakdown could be devastating and potentially life-threatening.

continued on page 26

applied in the fluid power industry. Steel, cast iron, and aluminum are suitable materials for TEM. Thanks to the existing large chamber, largesize manifolds can be processed.

The Thermal Energy Method (TEM) of deburring utilizes energy generated in the combustion of gases to oxidize burrs. This method differentiates burrs from the component by the ratio between surface area and mass. Burrs, which are high in this ratio, absorb most of the heat and get vaporized in oxidation.

TEM produces intense heat energy by igniting a pressurized mixture of combustible gas and oxygen within a sealed, specially controlled chamber. Due to the sudden release of heat energy, a high-temperature blast up to 3,300°C (6,000°F) is generated for a few milliseconds. As a result, burrs and flashes catch fire, burn, and vaporize till heat gets dissipated into the body of the workpiece. In the process, the workpiece also gets heated but to such a limited extent that there is no change in its metallurgical properties.

TEM is known to deburr components in and out in one go. Deburring of multiple parts is a possibility as gas flows around them. The cycle time of the process, excluding component loading and unloading, is typically less than a minute, making this technology a very productive method.

In TEM, the volume of gas injected into the chamber, the thickness of the burrs, the heat transfer rate of the processed material, and the ratio of fuel to oxygen define the amount of removed burr.

Process steps

1 The chamber is filled with a pressurized mixture of gases.

Loading of the components into the TEM chamber. The chamber is closed.

2 Gas is ignited.

3 Burrs are oxidized, and the component deburred.

4 The chamber is vented to de-pressurize.

5 The chamber opens, and the component is unloaded.

6 The TEM-qualified components.

• Valve bodies – with many intersecting holes, grooves, threads, and inaccessible areas, these components are a deburring nightmare. TEM is ideally suited for valve bodies. Efficient deburring makes assembly easy, spool movements free, and the entire system reliable.

• Manifolds – with challenges like valve bodies, manifolds are well suited to TEM deburring.

• Spools – precision grooves and intricate holes & notches make spools too intricate to be manually deburred. Ineffective deburring can cause inappropriate system functioning and even jamming.

• Pump and hydraulics motor elements –high-pressure pumps and hydraulics motors, characterized by minimal clearances between moving parts, are susceptible to failures requiring practical components deburring.

• Cylinder components – cylinder porting blocks and end caps are standard in TEM deburring

• Hydraulic fittings – often ignored, these are a common source of burrs. Once dislodged, burrs go to other critical areas in the circuit, causing havoc.

system. That leads to premature wear and failure. TEM does a perfect job of clearing up the tiny particles along the thread's primary diameter.

continued on page 28

Being

Let's consider post-treatment.

Most people exposed to Thermal Deburring for the first time may be surprised by the oxide layer left at the surface after the process.

MAIN’S ADVANTAGES

DEPENDABLE - 65 years of hydraulic experience

INFORMED - Main’s engineers are active on the SAE, NFPA, and ISO tech committees QUICK - Thousands of Styles and Flange Types STOCKED

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info@MAINmfg.com

info@MAINmfg.com

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No worries, this process by-product will be removed during a cleaning operation. Chemical market leaders in cleaning and degreasing offer a range of post-cleaning products designed to address the different materials.

These products are utilized in post-treatment stations typically used for cleaning and passivation. The equipment starts with straightforward dunking stations and goes up to multiple automated stations with advanced cleaning features like ultrasonic.

TEM provides superior and affordable deburring for the real world.

Thermal Deburring not only delivers on the deburring quality, the productivity, and the cost per part but also solves some of today's industry challenges like new intricate designs prohibiting manual deburring, health requirements preventing people from repeating the same motion too many times, lack of interest from workers for the deburring jobs, shortage of labor, cost of labor in some area of the world.

How do I gain access to the TEM Technology?

There are manufacturing companies on the market offering TEM equipment. Alternatively, suppose you do not have a volume justifying an investment. In that case, you can access that technology through a contract service offering.

The TEM equipment comes in different sizes; their naming is sometimes related to

Secondary

their clamping force and the chamber size. In most cases, the chamber is round, open at the bottom, and has a top featuring a bell shape. Chambers come in various diameters and heights. Recently, we have noticed an inflation in the chamber size to accommodate either larger manifolds or long shafts, the latest driving the appearance of the chamber with a one-meter length or more. Some manufacturers are using a cubic design as an alternative. TEM machines seem pricey, but their life spans for decades, especially when not running at high pressure, and their service cost is low. In addition, their efficiency delivers the lowest cost per part.

Wrap-Up: Some TEM highlights.

Deburring effectiveness. TEM Eliminate burrs, flashings, and loose particles, regardless of their location on – or inside – the component.

Process efficiency. Unlike traditional mechanical and abrasive methods, no media can become trapped in internal areas or contaminate the surface.

Ease of use. TEM is not a line-of-sight process requiring targeted media programming compared to waterjet. With TEM, the gas envelops every area of the component simultaneously.

Blockage elimination. Compared to water jet, mechanical and abrasive methods, TEM is a non-contact process; therefore, burrs and flashings cannot be folded or pushed onto the component.

Abrasion elimination. Compared to manual and mechanical methods, TEM does not generate secondary burrs, and there is no risk of scratching critical areas. Machining simplicity. Only simple baskets and workpiece-holding fixtures are required.

Extremely high production rates. Up to hundreds of parts in a 30- to 60-second cycle time is typical, and 24/7 operations are achievable.

Cost-effectiveness. TEM processing cost is less than a fraction of a cent for gas and electricity usage per component, resulting in the lowest operating costs in the finishing industry.

Quality and repeatability. Superior process stability and reasonable process control ensure precision, constant quality, and the highest repeatability.

Uniform results. Our tooling assures uniform energy distribution and protects surfaces while undergoing processing.

Customized tooling. Plate and pin fixtures are corrosion-resistant and custom-designed to suit specific applications.

Ease of automation. TEM tooling provides easy loading and unloading of components and maintenance of workpiece orientation.

TEM ensures enhanced component performance. Many customers report a reduction in component performance failures and warranty claims, leading to higher customer satisfaction. •

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Newly Certified Professionals

FEBRUARY 2024

CONNECTOR AND CONDUCTOR (CC)

Matthew Hendryx, Controlled Fluids Inc

James Chance, jr., Controlled Fluids, Inc.

Chase Strange, Controlled Fluids, Inc.

Henry Kersey, Custom Hydraulics & Design, Inc.

Jordan Kopka, Custom Hydraulics & Design, Inc.

ENGINEER (E)

Jeff Curlee, Cross Company

ELECTRONIC CONTROLS SPECIALIST (ECS)

Matthew Eckert, Gulf Controls Company

HYDRAULIC SPECIALIST (HS)

Kylie Rasinski, Air Engineering and Supply

Conrad Adams, Caterpillar Inc

Travis Dillinger, Danfoss Power Solutions

Ethan Taylor, Force America

Chet Wilson, Gerdau

Erik Dahlman, Loram Maintenance of Way

Jeff Wilson, Motion Industries

Joel Gutierrez

Jacob Lenss

Andrew Luce

Nolan Pust

Tim Rahja

Trevor Reierson

Jason Velez Pico

Industrial Hydraulic Mechanic (IHM)

Charles Foreman, Coastal Hydraulics, Inc.

Ryan Gifford, Coastal Hydraulics, Inc.

Jackson Jacoby, Coastal Hydraulics, Inc.

MOBILE HYDRAULIC MECHANIC (MHM)

Neal Carranza, AEP

Lucas Serna, AEP

Roberto Baez, Altec Industries, Inc.

Steven Bulloch, Altec Industries, Inc.

Nathan Golding, Altec Industries, Inc.

Joseph Hamrick, Altec Industries, Inc.

Isaac Hawks, Altec Industries, Inc.

Gary Olson, Altec Industries, Inc.

Andrew Smitherman, Altec Industries, Inc.

Brian Wachtel, Altec Industries, Inc.

Glenn Watson, Altec Industries, Inc.

Darin Crooks, EWEB

Eric Kruse, EWEB

Raymond McFarlen, Open Loop Energy, Inc.

Matthew Drummer, Terex Utilities

Chad Malsam, Terex Utilities Factory

John Morrow, Terex Utilities Factory

Binay Kumar Rout, Terex Utilities Factory

Tyler Stoltenburg, Terex Utilities Factory

Anthony Zuhlsdorf, Terex Utilities Factory

Melvin Pillow, Virginia Department of Transportation

Steve Fedt

MOBILE HYDRAULIC TECHNICIAN (MHT)

Michael Pope

PNEUMATIC SPECIALIST (PS)

Michael Osborn, Dana, Inc.

SPECIALIST (S)

Michael Osborn, Dana, Inc.

Recently Revamped Pneumatic Specialist Online Training Modules

» THE UPDATES TO the Pneumatic Specialist online training modules include a larger player, allowing the viewer to now view in full screen and adjust playback speed. Slides of text previously are now replaced with visual aids to help those studying understand the subject matter easier.

Fluid Power Support Associate Certification

Whether you're aiming to enhance your knowledge of industry terminology, understand fluid power principles, grasp basic component functions, or gain an understanding of fluid power safety, our Fluid Power Support Associate Certification offers a straightforward format to focus your efforts and achieve success. Don't miss this opportunity to elevate your expertise and join the ranks of certified professionals in the fluid power industry!

Fluid Power Support Associate Certification Study Manual

Start preparing for the Fluid Power Support Associate Certification test with our newly released comprehensive study manual. Members enjoy FREE access to study manuals –join IFPS now for this exclusive benefit! Non-Members may purchase a copy!

WHAT IS YOUR ROLE WITH IFPS?

My role with the IFPS is Certification Logistics Manager. I schedule and coordinate all the certification testing done through the IFPS.

WHAT IS YOUR FAVORITE PART OF YOUR POSITION?

I love seeing people excited about furthering their careers through certification.

WHAT IS YOUR FAVORITE MOVIE?

Lord of the Rings: Return of the King

WHAT IS YOUR FAVORITE HOBBY OUTSIDE OF WORK?

In my spare time, I enjoy cooking/baking with my girlfriend, hanging out with our dogs, reading, and playing video games.

WHICH COUNTRY HAVE YOU ALWAYS WANTED TO VISIT?

I would like to visit Japan.

WHICH BOOK OR MOVIE CHARACTER DO YOU RELATE TO THE MOST?

Kaladin Stormblessed from the Stormlight Archive by Brando. No matter how many people he helps, he never forgets that he is only a Man.

IF YOU COULD HAVE ANY SUPERPOWER, WHAT WOULD IT BE?

Flight or Teleportation. I hate sitting in traffic.

WHAT IS YOUR FAVORITE DISH?

My favorite dish is a Philly Cheesesteak.

WHICH HISTORICAL FIGURE WOULD YOU WANT TO HAVE DINNER WITH, IF GIVEN THE CHANCE? WHY?

Blaise Pascal, so I can thank him for two generations of Pollander’s in the Fluid Power Industry.

CFPSD

Tentative Certification Review Training

IFPS offers onsite review training for small groups of at least 10 persons. An IFPS accredited instructor visits your company to conduct the review. Contact kpollander@ifps.org for details of the scheduled onsite reviews listed below.

HYDRAULIC SPECIALIST

2024 certification review training dates will be announced soon.

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org)

» CFC Industrial Training – Cincinnati, Ohio – June 17-21, 2024

ELECTRONIC CONTROLS SPECIALIST

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

For dates, call CFC Industrial Training at (513) 874-3225 or visit www.cfcindustrialtraining.com.

» CFC Industrial Training – Cincinnati, Ohio – May 6-10, 2024

PNEUMATIC SPECIALIST

2024 certification review training dates will be announced soon.

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org)

CONNECTOR & CONDUCTOR

2024 certification review training dates will be announced soon.

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

MOBILE HYDRAULIC MECHANIC

2024 certification review training dates will be announced soon.

For custom training IFPS inquiries, please contact Bj Wagner (bwagner@ifps.org)

Online Mobile Hydraulic Mechanic certification review for written test is offered through CFC Industrial Training. This course surveys the MHM Study Manual (6.5 hours) and every outcome to prepare you for the written test. Members may e-mail for a 20% coupon code off the list price. Test fees are not included.

» CFC Industrial Training – Cincinnati, Ohio – December 2-6, 2024

INDUSTRIAL HYDRAULIC MECHANIC

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

For dates, call CFC Industrial Training at (513) 874-3225 or visit www.cfcindustrialtraining.com.

» CFC Industrial Training – Cincinnati, Ohio – August 5-9, 2024

INDUSTRIAL HYDRAULIC TECHNICIAN

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

» For dates, call CFC Industrial Training at (513) 874-3225 or visit www.cfcindustrialtraining.com.

MOBILE HYDRAULIC TECHNICIAN

2024 certification review training dates will be announced soon.

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

PNEUMATIC TECHNICIAN & PNEUMATIC MECHANIC

For custom IFPS training inquiries, please contact Bj Wagner (bwagner@ifps.org).

» For dates, call CFC Industrial Training at (513) 874-3225 or visit www.cfcindustrialtraining.com.

OTC 2024

1. Technical Excellence:

Presentations and Discussions: OTC is renowned for its comprehensive technical sessions, where experts delve into diverse facets of offshore technology. Expect in-depth discussions covering exploration, drilling, production, and advancements in environmental protection within the industry.

2. Cutting-Edge Exhibitions:

Innovation Showcase: The conference will host a vibrant exhibition featuring the latest technologies, products, and services. Attendees can explore cutting-edge solutions and witness live demonstrations, providing invaluable insights into the future of offshore technology.

3. Skills Enhancement:

Workshops and Training: Specialized workshops and training sessions will be available to enhance the skills and knowledge of professionals. These sessions aim to address industry challenges, introduce new methodologies, and ensure that participants stay at the forefront of the rapidly evolving offshore landscape.

4. Networking Opportunities:

Industry Connections: OTC provides a conducive environment for networking, fostering connections between professionals, decision-makers, and potential

The 2024 Offshore Technology Conference (OTC) in Houston, TX, promises to be a dynamic gathering of professionals, industry leaders, and innovators within the offshore energy sector. Attendees can look forward to a multifaceted experience that encompasses technical sessions, exhibitions, workshops, and networking opportunities.

collaborators. Attendees can engage in structured networking events, social gatherings, and business meetings.

5. Keynote Insights:

Industry Trends and Future Direction: Keynote speakers and panel discussions will offer strategic insights into current challenges, emerging trends, and the future trajectory of offshore technology. This is an opportunity to gain a comprehensive understanding of the industry's direction.

6. Global Collaboration:

International Perspective: OTC attracts a diverse global audience, promoting international collaboration. Participants will have the chance to explore innovations from around the world, fostering a global perspective on offshore advancements.

7. Holistic Experience:

Experiential Learning: Beyond traditional presentations, OTC aims to provide an experiential learning environment. Attendees can expect interactive exhibits, hands-on experiences with emerging technologies, and a comprehensive overview of the offshore industry's current state.

The 2024 OTC is an immersive and enlightening experience for professionals, offering a platform to stay informed, connected, and inspired by the latest developments in technology and industry practices.

Fluid Power Companies

Exhibiting at OTC 2024

Monday May 6th

Explore the future of sustainable energy on the first day of the Offshore Technology Conference. The itinerary covers diverse topics, including environmental footprints, offshore wind, deepwater technologies, marine energy, geothermal exploration, and more. Highlight sessions on Chevron's Anchor Project, energy transition, and international perspectives offer valuable insights. The exhibition runs all day, providing opportunities for attendees to engage with the latest advancements in the energy sector.

Tuesday May 7th

Delve into the evolving landscape of offshore energy at the conference, featuring sessions on U.S. offshore wind development, bp's perspective on resilient hydrocarbons, continuous improvement for net-zero goals, Azerbaijan's energy needs, Israeli innovation, and more. Explore marine mining, hydrogen carriers, metocean advances, and advancements in offshore geotechnics during the morning sessions. Afternoon highlights include collaborative efforts for offshore carbon sequestration, the future of offshore wind, geothermal production, digital evolution in oil and gas, and the role of floating wind power in decarbonization. The day concludes with a focus on supplier diversity and a networking social event.

Wednesday May 8th

Explore the dynamic landscape of the Brazilian offshore industry with sessions covering legacy and renewable projects, the rise of nuclear power, and the transition from offshore oil and gas to wind. Gain insights into Guyana's emergence as an energy powerhouse, Ukraine's oil and gas exploration sector, and the challenges and opportunities of broken supply chains in deepwater production. Dive into technical advancements, including mooring systems, riser and pipeline analysis, materials for sustainable energy, subsea production, and marine geoscience for offshore wind. Afternoon discussions encompass offshore CCUS, sustainable supply chains, and the evolution of petroleum engineering education. Discover innovative approaches to pre-salt drilling, project management, abandonment practices, carbon capture and storage, subsea technologies, and topside process design. The day concludes with a focus on career development and Italy's strategies for a sustainable energy transition.

Thursday May 9th

Explore offshore safety through SEMS audits, emissions reduction strategies, and the remarkable journey of Bonga Field's 1 billion barrels export. The morning includes an industry exhibition and insights into digitalization's impact on safety, offshore carbon storage, and AI applications. Afternoon sessions cover upstream R&D, Latin American independents, renewable energy regulations, well integrity, digital tools in subsea activities, and advancements in flow assurance. The day concludes with a focus on safety, machine learning in reservoir management, and geotechnical engineering. The closing reception offers networking opportunities.

www.diamondhydraulics.com

Diamond Hydraulics is a veteran owned small business that manufactures, rebuilds, and repairs hydraulic equipment including cylinders, pumps, motors, valves, power units, and much more. We were established in 1999, and have over five decades of experience in hydraulic equipment repair.

Diamond Hydraulics provides quality workmanship, extensive industry knowledge, and fast turnaround time on repairs and replacements. All repairs are brought back up to OEM standards and tested with state-of-the-art test equipment.

409-986-3957 (Office) | 409-986-7437 (Fax) sales@diamondhydraulicsinc.com www.diamondhydraulics.com

www.smcusa.com

SMC Corporation of America is a part of a global organization that supports our customers in every industrialized country and is the U.S. subsidiary of SMC Corporation based in Japan. Since its establishment, SMC has been a leader in pneumatic technology, providing industry with technology and products to support automation based on the guiding principle of “contributing to automation labor savings in industry.” Over the past 50+ years, SMC’s products have become established as a recognized international brand through sales, technical, supply and after sale services in world markets.

www.essentracomponents.com

Essentra Components is a worldwide leader in the manufacturing of plastic protection products for the fluid power industry. Essentra’s cap and plug manufacturing capabilities in Erie, Pennsylvania are complemented by additional molding facilities in Flippin, Arkansas as well as international locations in Mexico, Costa Rica, and Brazil. Essentra also operates two warehouse and sales centers in Canada. With over 45,000 standard products available for immediate delivery and additional custom molding capabilities, Essentra is the expert at making the right product to meet your most demanding requirements.

www.laman.com

La-Man Corporation is a leading manufacturer of compressed air filtration products. With over 30 years of experience, we truly understand the importance of protecting valuable machinery, tools, and finished products from dirty, wet, contaminated air. La-Man’s line of products include the patented Extractor Dryer, .01 micron filter, as well as, LA-MAN-Air Breathing Systems™, SuperStar™ Membrane Dryers, and the Refrigerated Extractor/Dryer.

PO BOX 328 • Mazeppa, MN 55956 800-348-2463

www.worldwidelectric.com

Electrical Equipment or Power Transmission Distributors, Original Equipment Manufacturers (OEM), or Solution Packagers call us to solve an immediate issue. Maybe a motor failed, or their plant, machinery, or process is down. From our website, they can quickly identify what they need and download product support information, such as technical specifications, IOM Manuals, data packs, and 2D/3D drawings.

FluiDyne Fluid Power 9, 18, 39 586-296-7200 fluidynefp.com

Gemels North America 19, OBC gemels.com

HAWE North America, Inc 7, 19 704-509-1599 hawe.com

Hunger Hydraulics 15 1-800-248-9232 hunger-hydraulics.com

Hydraulex 27 1-800-422-4279 hydraulex.com

Company Page Phone Web

Hydraulics International 25 818-407-3400 hiipumps.com

J/T Hydraulics & Service Co 20 1-800-591-8280 jthydraulics.com

La-Man Corp 38 1-800-348-2463 laman.com

Lubriplate, Inc 30 1-800-733-4755 lubriplate.com

Main Mfg Products 20, 28, 39 1-800-521-7918 mainmfg.com

MOCAP Inc 21 1-800-633-6885 mocap.com

Motion Industries 21, IBC 1-800-526-9328 motion.com

MP Filtri USA Inc 8,

At Ultra Clean Technologies we cannot overemphasize the critical role of cleanliness in hydraulic hoses for offshore wind power systems. Installing new equipment with contaminated hoses or neglecting maintenance can lead to severe failures, jeopardizing the entire wind power operation. Ultra Clean Technologies' Clean Easy Systems provide a quick an deffective solution. Our innovative technology approach ensures hoses are free from contaminants that could reduce functionality and increase downtime. By adopting Ultra Clean Technologies' cleaning and sealing solutions, you safeguard your offshore wind turbines against breakdowns, ensuring reliability and efficiency in harnessing wind power.

Safe Guard Your OFF-Shore Equipement