Pressure and Vacuum Sealed Feedthrough Fittings

multiple versions of vacuum feedthroughs, vacuum chamber feed through fitting
Several versions of vacuum chamber feedthrough fittings.
Image courtesy of Spectite, Inc.
The passage of sensor tubes, electrical conductors, or similar items through the wall of a pressure vessel requires the use of a special fitting that accommodates the physical passage through the vessel wall without compromising the vessel performance. The provision of the right connectors, mounting fitting, and sealant assure simple and effective installation of the feedthrough fitting. Vacuum and pressure feedthroughs are an important part of the physical signal path and the vessel barrier wall, maintaining the integrity of the vessel or chamber containment while facilitating the passage or placement of power, sensors, or other items.

There are countless applications for feedthroughs, resulting in a broad offering of body styles, sealants, connections, and customized arrangements to meet any challenge. Spectite manufactures a broad range of vacuum and pressure feedthroughs, any of which can be customized to meet an application challenge. Share your project requirements with a product specialist, leveraging your own process knowledge and experience with their product application expertise to develop an effective solution.



Electronic Pressure Switches

electronic pressure switch NEMA 4 enclosure
Electronic pressure switch in NEMA 4 enclosure.
Image courtesy of Ashcroft
A pressure switch is a device that detects and responds to fluid pressure. Pressure switches use a variety of sensing elements such as diaphragms, bellows, bourdon tubes, pistons or electronic sensors. In all but the electronic sensor versions, the movement of the sensing element, caused by pressure fluctuation, is transferred to a set of electrical contacts to open or close a circuit. Electronic pressure switches utilize a sensor signal and circuitry to control switch activation.

The normal status of a switch is the resting state with stimulation. A pressure switch will be in its normal state when low or minimum pressure is applied. For a pressure switch, normal status is any fluid pressure below the trip threshold of the switch.

One of the earliest and most common designs of pressure switch was the bourdon tube pressure sensor with a mercury switch. When pressure is applied, the bourdon tube flexes enough to tilt the glass bulb of the mercury switch so that the mercury flows over the electrical contacts, thus completing the circuit. the glass bulb tilts far enough to cause the mercury to fall against a pair of electrodes, thus completing an electrical circuit. Many of these pressure switches were sold on steam boilers. While they became a de facto standard, they were sensitive to vibration and breakage of the mercury bulb.

Pressure switches using micro type electrical switches and force-balanced pressure sensors is another common design. The force provided by the pressure-sensing element against a mechanical spring is balanced until one overcomes the other. The tension on the spring may be adjusted to set the tripping point, thus providing an adjustable setpoint.

One of the criteria of any pressure switch is the deadband or (reset pressure differential). This setting determines the amount of pressure change required to re-set the switch to its normal state after it has tripped. The differential pressure setting of a pressure switch should not to be confused with a differential pressure switch, which actually operates on the difference in pressure between two separate pressure input ports.

Electronic pressure switches provide some features which generally are considered advantageous to mechanical designs.
  • No mechanical linkage between sensing element and switch, all electronic.
  • High cycle rates are possible.
  • High levels of accuracy and repeatability.
  • Some models have additional features, analog output, digital display, auxiliary switches, and more.
When selecting pressure switches you must consider the electrical requirements (volts, amps, AC or DC), the area classification (hazardous, non-hazardous, general purpose, water-tight), pressure sensing range, body materials that will be exposed to ambient contaminants, and wetted materials.

Whatever your pressure measurement application, share your challenges with a fluid measurement and control specialist, combining your own knowledge and experience with their product application expertise to develop effective solutions.

Thermal Flow Meters

Thermal flow meter for industrial process measurement
Magnetrol TA2 thermal flow meter configured
for insertion mounting.
Image courtesy Magnetrol International 
There are numerous methods and technologies adapted for the measurement of fluid flow, each with its own set of positive attributes and limitations. Understanding the basic operating principles behind each is useful for effective selection of a technology to be applied on a specific application. One technology long employed for continuous fluid flow measurement is thermal dispersion. The operation of a thermal flow meter is as simple as placing a heated object into a moving stream. The amount of heat drawn away, or dispersed, from the heated object is a measurable quantity that is directly proportional to mass flow rate. This is similar in concept to a principle commonly observed in wind chill where someone perceives the temperature to be colder than it actually is at the moment of measurement.

One example of a thermal mass flow meter is a hot wire anemometer, with which air speed is measured via a metal wire charged with an electric current. The faster the air moves around the wire, the more the temperature of the wire will correspondingly drop. The electrical power required to keep the temperature of the wire constant is directly proportional to the flow rate of the air moving past the wire. However, thermal flow meters are inherently used to measure mass air flow and not volumetric air flow.

A common application of thermal flow meters is mass air flow measurement for combustion control, such as in engines and boilers. Maintaining fuel to air ratios in a range resulting in efficient combustion is essential to controlling fuel costs and the level of regulated emissions. Keeping combustion efficient relies on a controller’s ability to modify the combustion air mass flow rate to match the demand for fuel under changing load and input conditions. Thermal dispersion technology can be applied to gases or liquids, making the range of applications very broad.

Typically, thermal mass flow meters used in processing industries will have a flow tube or insertion probe with two temperature sensors, one which is heated and the other which is not. The heated sensor serves as the mass flow sensor, meaning it will cool at a rate directly dependent on mass flow. The purpose of the second temperature sensor is to deliver an accurate measure of fluid temperature. Various processing methods are employed to determine the degree of thermal dispersion, but all are related to the same basic principal.

One of the best applications for thermal mass flow meters is at a particular point of a flow stream, where the flow meter can be inserted or installed to measure a specific amount of fluid being used in the process, such as the amount of gas being sent to a flare. Their design simplicity and ease of production allows thermal flow meters to be very compact. Some are even coupled with built-in throttling mechanisms and other control devices, incorporating measurement and control functions into a single integrated device.

Share your flow measurement requirements and challenges with an instrumentation specialist, combining your own process knowledge and experience with their product application expertise to develop an effective solution.

Motion Detection For Materials Conveying Equipment

Instrument for detecting loss of motion in material conveying system
Loss of motion detector for use in material
conveying systems
Image courtesy Ronan Engineering
Processing equipment in many facilities involves moving materials along a conveyance system from one point to another. Continuous processing requires that the conveyance machinery keeps moving materials through the process. Monitoring movement at selected points along the conveyance can provide immediate notification when machine motion stops.

One motion monitoring unit from Ronan Engineering has been in the market for many years, evidence of its durability and reliability for detecting loss of motion. The X25 has a very simple operating principle. A detector head is located adjacent to a rotating shaft, spoke wheel, screw conveyor, bucket elevator, or other moving part of the equipment. It functions as a pickup with an output signal corresponding to movement of the target. A remotely located housing contains the signal processor with adjustable sensitivity and time interval controls, as well as output relays for signaling loss of movement in the targeted area.

There are a number of adaptations that can be made for installations subject to low rotational speed, high temperature, and other special conditions. The device is simple, rugged, and reliable.

More detail is provided in the data sheet included below. Share your potential applications with process measurement and control specialists. Leverage your own knowledge and experience with their product application expertise to develop an effective solution.



Automatic Self Cleaning Strainer for Fluid Processing

cutaway view of automatic self cleaning strainer
An automatic self-cleaning strainer is suitable for many
applications and reduces manual maintenance.
Strainers and other filtration equipment reduce the burden of targeted unwanted solids in a fluid system. Potentially damaging particulate material is trapped and held for removal from the system. Keeping fluid systems clean helps to maintain long term design performance and potentially extends the operating life of pumps, valves, and other mechanical devices in the system.

Strainers generally consist of a heavy duty housing and a contained screen with controlled opening size designed to disallow the passage of particles exceeding a targeted size. Trapped particulates remain on the screen, or within a shape created by the screen such as a basket (see basket strainer). The continuing collection of solids will eventually impede the free flow of the process fluid, so the strainer must be emptied or cleaned periodically. The frequency of cleaning is a function of the solids content of the incoming fluid and may not necessarily be a regular interval. A simple strainer, to be cleaned, requires temporary shutdown of the flow or bypass of process fluid around the strainer assembly. A duplex strainer consists of twin strainers, usually housed in a common assembly, with a diverter valve that allows the inlet flow to be directed to one of the strainers while closing off the other from the system. This allows for cleaning of one of the strainers while the other is in active service, maintaining continuous fluid flow.
A third solution provides the continuous operation of a duplex strainer, but without the need for manual cleaning. 
An automatic self-cleaning strainer, such as the MCS 500 from Eaton provides uninterrupted operation without a duplex configuration or regular manual cleaning. It's form is essentially a housed strainer with a built-in scraper blade that moves along the inlet surface of the strainer media, moving accumulated solids to a collection chamber at the bottom of the pressure housing. Automatic controls regulate the operation of the scraper and discharge valve on the purge chamber that removes the collected solids from the system. The automatic self-cleaning strainer provides a cost effective time saving solution for the filtration of compatible fluids.

More detail for the MCS 500 is provided below. Share your fluid filtration requirements and challenges with fluid processing specialists. Leverage your own process knowledge and experience with their product application expertise to develop effective solutions.


A Little History

26 GHz radar level measurement transmitter
Pulsar® R86 Radar Level Transmitter
One of Magnetrol's recent innovations.
Some companies, through hard work, innovation, and good fortune, manage to stand the test of time and thrive for decades in a competitive environment. The manufacture of process measurement and control equipment and devices is an arena where standing still in the market is not a viable business strategy. Magnetrol has been helping process operators measure and control fluid level and flow for decades. The company recently posted an article on their own blog outlining a little of the company history as illustrated through product innovations. We include an excerpt from the blog below and encourage readers to share their fluid level and flow challenges with application specialists. Leveraging your own process knowledge and experience with their product application expertise to develop effective solutions.

This year marks the 85th anniversary of the founding of Magnetrol®. Since its very beginning, MAGNETROL has been a company focused on level and flow measurement innovation, designing cost-effective, cutting-edge solutions for its customers. In honor of 85 years of success, here’s a look back on some MAGNETROL highlights over the years. 
The Beginning
The history of MAGNETROL dates to 1932 as a Chicago-based manufacturer of boiler systems. The first MAGNETROL level control was born when the founding company, Schaub Systems Service, needed a controller for its boiler systems. Our innovative device was the first of its kind to accurately and safely detect the motion of liquid in boilers and feedwater systems. Soon the MAGNETROL name became synonymous with rock-solid, reliable mechanical buoyancy controls.

Mechanical buoyancy isn’t the only area where MAGNETROL has been a force for innovation. Our devices have changed the radar landscape as well. In 1998, we introduced the Eclipse® Model 705 as the first loop-powered guided wave radar (GWR) transmitter for industrial liquid level applications. The unprecedented reliability and accuracy of the ECLIPSE 705 set a new standard for radar devices.Innovation in Radar
We didn’t stop there, continuing to develop radar technology and adapt it to the needs of our customers. In 1999, MAGNETROL released the first ECLIPSE high-temperature/high-pressure probe, rated to 750 °F (400 °C). We developed an overfill-capable coaxial probe in 2000. And in 2001, we became the first company to incorporate GWR technology into a patented magnetic level indicator chamber, offering true redundant measurement.
In addition to these new developments in GWR, MAGNETROL created many pulse burst and non-contact radar devices for use in challenging process applications. We also secured our core capabilities in electronic technologies, including RF capacitance and ultrasonic.
 Looking Toward the Future
Most recently, MAGNETROL released the Pulsar® Model R86, a groundbreaking new 26GHz non-contact radar featuring a smaller wavelength for smaller antennas and improved 1mm resolution.
We continue to raise the bar for level and flow measurement. Whatever the future of industrial technology, MAGNETROL will be in the thick of it, developing the products that bring customers accuracy, reliability and peace of mind. We are a team of innovators—and innovators are always moving forward.

I/P and E/P Transducers

variants of I/P and E/P electronic to pneumatic transducers
I/P and E/P transducers deliver a pneumatic output
proportional to an electronic input signal.
Image courtesy Rotork Instruments - Fairchild
Converting from one signal type to another is a common challenge in process control. When the application calls for conversion from an electrical signal, current or voltage, to a pneumatic signal (pressure), this calls for an I/P or E/P transducer.

I/P and E/P transducers are electro pneumatic devices that convert current or voltage input signals to a linearly proportional output pressure. These transducers are available in a wide array of configurations to accommodate almost any industrial setting or application.

The transducers pictured use, in the pilot stage, electronic closed loop feedback and a piezoceramic actuator flapper nozzle system, controlling the signal pressure of an integral pneumatic volume booster. A control diaphragm and main valve on the volume booster section controls the flow of air at the output in response to the pressure received from the pilot stage. The output pressure of the volume booster is feed into an electronic closed loop feedback arrangement to deliver accurate pressure control.

Applying the transducer is a straight forward operation, involving matching the device input and output signal capabilities with those of the application. More detail is provided in the document included below.

Share your process measurement and control challenges with instrumentation specialists, combining your process expertise with their product knowledge to produce effective solutions.