Providing problem solving and educational information for topics related to industrial steam, hot water systems, industrial valves, valve automation, HVAC, and process automation. Have a question? Give us a call at (800) 892-2769 | www.meadobrien.com
Showing posts with label Texas Panhandle. Show all posts
Showing posts with label Texas Panhandle. Show all posts
Stall can most easily be defined as a condition in which heat transfer equipment is unable to drain condensate and becomes flooded due to insufficient system pressure.
Stall occurs primarily in heat transfer equipment where the steam pressure is modulated to obtain a desired output (i.e. product temperature). The pressure range of any such equipment ( coils, shell & tube, etc....) can be segmented into two (2) distinct operational modes, Operating and Stall.
Operating: In the upper section of the pressure range the operating pressure (OP) of the equipment is greater than the back pressure (BP) present at the discharge of the steam trap. Therefore a positive pressure differential across the trap exists allowing for condensate to flow from the equipment to the condensate return line.
Stall: In the lower section of the pressure range the operating pressure (OP) of the equipment is less than or equal to the back pressure (BP) present at the discharge of the steam trap. Therefore a negative or no pressure differential exists, this does not allow condensate to be discharged to the return line and the condensate begins to collect and flood the equipment.
You can read the entire Armstrong technical paper below.
Reverse osmosis (RO) is one of the most popular methods for effective water purification. It has been used for years to purify contaminated water, including converting brackish or seawater to drinking water.
Reverse osmosis is a process in which dissolved inorganic solids (such as salts) are removed from a solution (such as water). This is accomplished by pushing the water through a semi permeable membrane, which allows only the water to pass, but not the impurities or contaminates.
Reverse Osmosis can deliver bottled-water quality safety and taste by removing over 99% of dissolved minerals, chlorine and contaminants. Many leading bottled-water companies actually use large-scale RO to produce their water.
Reverse osmosis systems are found in several drinking water applications from restaurant, food and beverage equipment to grocery store produce misting.
The ASCO Series 212 solenoid valve is designed for these type systems. The valves come with NSF approvals for use in drinking water systems and also is design with unique “FasN” quick connection system. The valves are designed to handle 150 psi up to 180 deg. F. and has low wattage coils in both AC and DC.
See the video below for an illustration of where these valves are used in RO systems.
The patented family of Foxboro vortex flowmeters has the high accuracy and rangeability of positive displacement and turbine flowmeters without the mechanical complexity and high cost. Maximum rangeability up to 100:1 is possible as compared to 3:1 for a nonlinear differential pressure producer (orifice plate).
Because these Flowmeters have no moving parts, they are very durable and reliable. This simplicity of design ensures low initial cost, low operating and maintenance costs, and therefore contributing to an overall low cost of ownership.
In the oil and gas industry, “sour gas” refers to natural gas that is contaminated with hydrogen sulfide (H2S or “sulfide”). “Sour crude,” similarly, is crude oil that contains hydrogen sulfide. These are naturally occurring conditions, but definitely not desirable. Aside from the environmental pollution problems with “high-sulfur” fuels, there are some serious corrosion problems that can affect many materials. Liquid drainers (drain traps) and strainers are the most common Armstrong products ordered for sour gas service. A few other products are sometimes specified, notably inverted bucket air traps. An inquiry may be accompanied by an extensive specification of H2S concentrations; there may be a line indicating “Sour Gas Service;” or may only be the note “NACE.” This is a reference to Standard MR0175-93 published by the National Association of Corrosion Engineers (NACE).
What is the problem?
H2S under pressure permeates into the crystalline structure of the metal and strains the structure of the crystal. This reduces its ability to deform in a ductile manner. The net effect is to make the material brittle. In the presence of external stresses due to applied pressure or loads, or internal stresses due to cold working or welding, parts may fail by cracking without any warning. This process is called Sulfide Stress Cracking (SSC). SSC is affected by many parameters, including: · Composition, strength, heat treatment, and microstructure of the material; · Hydrogen ion concentration (pH) of the environment; · Hydrogen sulfide concentration and total pressure; · Total tensile stress; · Time and temperature. Choice of products and their limitations. Inverted bucket traps (primarily for air trap service) should be selected from the Series 300 traps. The bucket and mechanism (except valve and seat) will be annealed to eliminate the locked-in stresses from the stamping operations. The valve and seat will be made from Type 316 stainless, without additional heat treatment. Cast iron bucket weights are permitted, since they are not stressed in tension. Special bolting is required only if the sour environment is also outside the trap.
Ethanol, the common name for ethyl alcohol, is fuel grade alcohol that is produced through the fermentation of simple carbohydrates by yeasts. Fueled by growing environmental, economic, and national security concerns, U.S. ethanol production capacity has nearly doubled in the past six years, and the Renewable Fuel Association (RFA) projects another doubling of the industry by 2012. Ethanol can be made from renewable feedstock’s such as grain sorghum, wheat, barley, potatoes, and sugar cane. In the United States, the majority of the ethanol is produced from corn.
The two main processes to produce ethanol from corn are wet milling and dry milling.
Wet milling is more versatile as it produces a greater variety of products, including starch, corn syrup, and sucralose (such as Splenda®). However, with this versatility come higher costs in mill design, building, and operation. If ethanol is the primary product produced, dry mills offer the advantages of lower construction and operations costs, with improved production efficiency. Of the more than 70 U.S. ethanol plants currently being built, only a few are wet mills.
The efficiency of ethanol production has come a long way during the last 20 years. As more large-scale facilities come on line, ethanol producers are faced with the growing challenge of finding innovative ways to maintain profitability while this market matures. An increasingly accepted solution is process automation to assist ethanol producers in controlling product quality, output, and costs. Because sensing and analytical instrumentation represents what is essentially the eyes and ears of any automation system, careful evaluation of instrumentation, at the design phase can reduce both equipment and operating costs significantly, while improving overall manufacturing effectiveness.
The following document, courtesy of Foxboro, provides a good overview of instrumentation and the production of ethanol.
Limitorque factory trained technicians, support and parts. It's only factory authorized when the work is done by a Blue Ribbon Repair Center.
Your Limitorque actuators were a major investment. Don't take chances with an unknown. Choose only a Flowserve Limitorque Blue Ribbon Distributor to assure you're getting factory authorized service. It's just not worth the risk.
Author: Steve Huffman VP Marketing & Business Development, Mead O'Brien
This article began as a coy reply to Bill Lydon’s interesting “Talk to Me” column (www.isa.org/intech/201512talk) about Leonardo da Vinci’s accomplishments as an artist applying engineering principles to create engineered works of art. Lydon noted that da Vinci saw science and art as complementary rather than as distinct disciplines. I stated that the word “STEAM,” really STEM + art, was not a new concept. The most recent iteration started sometime within the first decade of the 21st century, gaining traction with the efforts of such influencers as the Rhode Island School of Design beginning in 2010. Lawmakers with whom the Automation Federation met while advocating for our profession on Capitol Hill saw the concept as a way to reach elementary school children who would not otherwise be interested in math, science, and engineering.
My point was why use the word “steam” and create confusion with the engine of the American industrial revolution—and still the most efficient turbine driver and heat transfer media in prominent use to this day? Ironically, I find a declining knowledge base regarding steam systems used in industry, especially in process control, as the baby boomers are now retiring at very high levels. New practitioners, automation or otherwise, who either work on or are charged with engineering or maintaining these utility systems for process are generally not well prepared from a knowledge or educational perspective. This issue really adds to the negative financial impact that poorly designed or poorly maintained steam systems contribute to product quality, throughput, and energy loss.
For the artistic, it seems someone should have realized that the word, with all its thermodynamic glory, was already taken. So is it right to add “art” to the critical-thinking process of STEM and to the engineering curriculum to add another dimension to the student’s education? A number of artists and engineers disagree, but mainly because they only view their “discipline” as a tool that makes the other “discipline” superior. In short, it does go both ways, and purists on both sides probably resent that art and engineering go together. Because we come from the engineering side of the fence, I feel that art probably does broaden the horizons of engineers, but bringing art into engineering certainly does nothing to diminish art in and of itself. As art teaches us, there are many ways to comprehend the same thing.
In my own experience with the brewing industry in St. Louis over the past 40 years, the process mix includes engineering, science, and the application of the art of brewing, which goes back to the ancient Greeks. Modern brewing evolved over the past 150 years with people from those disciplines working together, some even using the “glue” of automation to turn their processes into highly automated, high production, and sophisticated dynamos with dozens of new products released yearly, all of them starting with four basic ingredients.
I project that art in STEM (STEM+A if I were chief acronym maker) is absolutely necessary for automation professionals to better appreciate process and better visualize what the future holds. It is also essential for thinking more abstractly, and in homage to the next big thing, developing a critical eye to analyze, put to practical use, and translate from “production-speak” to meaningful “management-speak” the massive amount of data coming our way with the Industrial Internet of Things revolution of which we are on the cusp. Dealing with disruptive technologies in process and factory automation will require digital skills far in excess of what we can even see on the horizon today. It seems that steam may be creating some buzz, but in the future the real kinetic energy will be created by digital engineers.
The Armstrong Intelligent Monitoring Model ST5700 is a wireless monitoring technology that efficiently monitors and evaluates steam trap operation. It identifies the conditions of a steam trap to determine significant problems that could put your operation at risk and can accurately detect potential issues such as plugged and blow thru steam traps.
The AIM®ST5700 helps identify the root cause while you minimize production losses and reduce energy consumption. Using non-intrusive technology combined with WirelessHART, the AIM®ST5700 is the ideal solution for any temporary or permanent 24/7 steam trap monitoring.
For more on its operation and use, please read the document below.
In electrical engineering terms, "explosion-proof" or "hazardous" areas are defined as locations where the possibility of fire or explosion exists because of the presence of flammable gasses, liquids, vapors, dusts, or fibers. As a result, electrical equipment must be installed in such a way where any electrical current or signal; a) does not provide enough energy to support an electrical arc (intrinsically safe); or b) is contained in an enclosure and associated conduit that are designed to suppress further ignition by sufficiently cooling escaping gases.
So its important to understand that when describing hazardous area enclosures, "explosion-proof" doesn't mean the enclosure can withstand the forces of an external explosion, but rather that the enclosure is designed to cool any escaping hot gases (caused by an internal spark or arcing contacts) sufficiently enough as to not to allow the ignition of combustible gases or dusts in the surrounding area.
This is a short video that explains what an explosion-proof enclosure looks like, how it works, and why it is safe to use in explosive or combustible atmospheres.
More than 1 million Limitorque actuators have been installed around the world, and some have been in operation for more than 50 years. The ruggedness and reliability of Limitorque electric actuators are among the primary reasons that customers continue to select Limitorque products.
Actuators requiring 90° of rotation to operate are necessary for quarter-turn valves such as ball, butterfly, plug and dampers, and rotary control valves. These types of Limitorque electric actuators are available for operations such as open-close, modulating, network and rotary service.
Multi-turn actuators are required to operate various types of rising stem valves such as gate, slide-gates, globe, check and linear control valves. These types of Limitorque electric actuators are available for operations such as open-close, modulating, network and linear service.
General Safety Precautions
Warning: Read the Installation and Maintenance Manual carefully and completely before attempting to install, operate, or troubleshoot the Limitorque actuator.
Warning: Be aware of electrical hazards. Turn off incoming power before working on the actuator and before opening the switch compartment.
Warning: Potential HIGH PRESSURE vessel — be aware of high-pressure hazards associated with the attached valve or other actuated device when installing or performing maintenance on the actuator. Do not remove the actuator mounting bolts from the valve or actuated device unless the valve or device stem is secured or there is no pressure in the line.
Warning: For maintenance and/or disassembly of the actuator while installed on the valve, ensure that the actuator is not under thrust or torque load. If the valve must be left in service, the valve stem must be locked in such a way as to prevent any movement of the valve stem.
Warning: Do not attempt to remove the spring cartridge cap, housing cover, or stem nut locknut from the actuator while the valve or actuated device is under load.
Warning: Do not manually operate the actuator with devices other than the installed handwheel and declutch lever. Using force beyond the ratings of the actuator and/or using additive force devices such as cheater bars, wheel wrenches, pipe wrenches, or other devices on the actuator handwheel or declutch lever may cause serious personal injury and/or damage to the actuator and valve.
Warning: Do not exceed any design limitations or make modifications to this equipment without first consulting Limitorque.
Warning: Actuators equipped with electrical devices (motors, controls) requiring field wiring must be wired and checked for proper operation by a qualified tradesman.
Warning: Use of the product must be suspended any time it fails to operate properly.
Caution: Do not use oversized motor overload heaters. Instead, look for the cause of the overload.
Caution: Do not operate the valve under motor operation without first setting or checking the limit switch setting and motor direction.
Caution: Do not force the declutch lever into the motor operation position. The lever returns to this position automatically when the motor is energized.
Caution: Do not depress the declutch lever during motor operation to stop valve travel.
Caution: Do not use replacement parts that are not genuine Flowserve Limitorque parts, as serious personal injury and/or damage to the actuator and valve may result.
Caution: Do not lift actuator/gearbox or actuator/valve combinations with only the eye bolts in the SMB actuator. These eye bolts are designed for lifting the SMB actuator only.
General Safety Practices
The following check points should be performed to maintain safe operation of the actuator:
Eye bolts in SMB and SB actuators are designed for lifting only the actuator and not associated gearboxes or valves.
Mount the actuator with the motor in a horizontal plane, if possible.
Keep the switch compartment clean and dry.
Keep the valve stem clean and lubricated.
Set up a periodic operating schedule for infrequently used valves.
Verify all actuator wiring is in accordance with the applicable wiring diagram.
Carefully check for correct motor rotation direction. If the valve closes when open button is pushed, the motor leads may have to be reversed.
Verify the stem nut is secured tightly by the locknut and that the top thread of the locknut is crimped or staked in two places.
Use a protective stem cover. Check valve stem travel and clearance before mounting covers on rising stem valves.
Mead O'Brien Authorized
Blue Ribbon Limitorque Parts & Service
For more information, or if you need field support with any Limitorque actuator, parts, or service, contact one of the following Mead O'Brien offices:
The PH10 DolpHin® Series pH Sensors and ORP10 DolpHin Series ORP Sensors are suitable for a wide range of pH and ORP measurement applications. They are designed for use with Foxboro® brand 875PH, 873PH, and 873DPX Analyzers, and 876PH Intelligent Transmitters and 870ITPH Transmitters. Some can also be used with 873APH Analyzers. When used with 875PH Analyzers or 876PH and 870ITPH Transmitters, they provide the additional capability of on-line diagnostics to signal the user if any of several common sensor faults occur.
The sensors are available with a choice of temperature compensation and cable termination. They are available with an internal pre-amplifer for use up to 150 m (500 ft) and with a Smart sensor for use up to 100 m (328 ft) from the analyzer or transmitter. The sensors can be mounted to the process in a number of ways. They have a 3/4-inch external NPT connection on both the electrode and cable end. The sensors can be inserted directly into the process line or tank or mounted through a variety of accessories including bushings, tees, flow chambers, and ball valves/insertion assemblies.The sensors are available in both analog and Smart versions.
These industry-leading sensors are already proven in countless installations including chemicals, pulp & paper, all kinds of industry and municipal water/wastewater treatment, metals/mining, and food and dairy applications worldwide.
The Foxboro® brand Model 876PH is a 2-wire loop powered intelligent transmitter that, when used with appropriate electrochemical sensors, provides measurement, local display, and transmission of pH, ORP (Oxidation-Reduction Potential), or ISE (Ion Selective Electrode) concentration. The transmitter outputs a HART digital signal and a 4 to 20 mA analog output. Versions are available for use with both analog and Smart (digital) sensors.
This video demonstrates how to correctly configure a Foxboro® PH10 sensor using the Foxboro® 876PH Transmitter.
