New White Paper from Brooks Instrument: Satisfying the Increasing Need for Flexibility in Bioprocess Equipment

Flexibility in Bioprocess Equipment

A new level of device flexibility significantly improves the flexibility of the entire bioreactor unit operation with the Brooks Instrument SLA Series Biotech mass flow controller – essential for process development and biomanufacturing. 

Learn about the key benefits of mass flow controller flexibility for your bioprocess in this new white paper: 

  • With accurate and repeatable gas flow control, you can achieve a wide usable flow range for your single-use bioreactor. 
  • With multi-gas/multi-range (MG-MR) capability, you can meet the needs of multiple applications. 
  • Utilize the concepts of cardinal ranges and range slices to allow hardware to be "reconfigured" rather than replaced. 
  • Overcome limitations in regulated and non-regulated industries by providing supporting documentation.

GET THE WHITE PAPER HERE

Miller Energy, Inc.
https://millerenergy.com


Calibration of a 4-20 mA Transmitter in a Hazardous Area Using a Portable Calibrator

This video demonstrates how to calibrate a 4-20 mA transmitter in a hazardous environment using a portable calibrator, in this case, the WIKA CPH7000 Ex.

Before you do calibrations in a hazardous (Ex) space, you must be aware of several things. There are many levels of dangerous areas, as well as various levels of calibrating equipment to choose. A hazardous location includes or may contain combustible substances (whether indoors or outdoors). It could be a liquid, gas, vapor, or dust that is combustible. Depending on the hazardous area classification, a flammable substance may be present all of the time, a particular percentage of the time, or just in specific instances, such as during shutdowns or accidents. 

In the best of circumstances, calibration can be a challenging task. Doing so in an area with a risk of explosion raises the complexity level to a new level, requiring the technician to have the necessary training and equipment. The WIKA CPH7000 Ex process calibrator is a precise, easy-to-use portable instrumentation calibrator that tests process transmitters in hazardous areas.

For more information WIKA products, or about instrument calibration in general, contact Miller Energy, Inc.

Miller Energy, Inc.
800-631-5454
https://millerenergy.com

Pulse Burst Radar Level Transmitters

Pulse Burst Radar Level Transmitters

Pulse Burst Radar sends short bursts of energy to the surface of a liquid. The time it takes for a signal to be reflected off the liquid surface is measured by ultra-high-speed timing circuitry. 

Filtering out false reflections and other background noises is accomplished through sophisticated signal processing. The precise level is then calculated by taking tank height and additional configuration information into account. Because the circuitry is highly energy-efficient, no duty cycling is required, as with other radar devices. This enables the device to track rapid level changes of up to 4.5 m/minute (180"/min). 

Magnetrol uses Pulse Burst Radar for Radar level measurement rather than frequency modulated continuous wave (FMCW), which is today's more common operational technology. Pulse Burst Radar operates in the time domain and does not necessitate the complex and costly processing required for FMCW. 

Pulse Burst Radar is more efficient at sorting through extraneous echoes and selecting the one reflected by the actual level because echoes are discrete and separated in time. Pulse Burst Radar also has excellent averaging characteristics, vital in applications where the return signal is affected by the factors described in "Don't Forget the 3 D's of Radar" below. 

Unlike actual pulse devices, which send a single sharp (fast rise-time) waveform of wide-band energy, Pulse Burst Radar sends out short bursts of 6 GHz or 26 GHz energy and measures the transit time of the signal reflected from the liquid surface. The following equation is used to calculate distance:

Distance = C x Transit Time/2, (where C = Speed of Light)

The level value is then calculated by taking tank height and other configuration information into account. The sensor reference point – the bottom of an NPT thread, top of a BSP thread, or face of a flange – is the exact reference point for distance and level calculations. 

Remember the 3 D's of Radar 

Three fundamental conditions influence radar applications: 

  • The process medium's dielectric; 
  • The application's distance, or measuring range; and 
  • A wide range of disturbances can weaken or distort the radar signal. 

Low dielectric media can weaken radar's return signal, reducing the effective measurement range of a device. Pulse Burst Radar provides accurate measurements even in low dielectrics. However, when the dielectric is extremely low, as with liquid gas, fuels, and solvents, or when boiling and/or flashing can occur, Guided Wave Radar (GWR) may be the better choice in radar technology. 

The distance, or measurement range, of Pulse Burst Radar, is determined by the antenna used, the dielectric constant of the medium, and the presence of signal interference. Turbulence, foam, false targets (interior tank obstructions causing false echoes), multiple reflections (reflections off the tank roof), and a frequent level change rate can all weaken, scatter, or multiply radar signals. Excessively high or extremely low liquid levels can also be problematic. 

The Processing of Signals 

Because radar exhibits interference effects similar to those seen in light, the signal processing function is critical. The quality of a device's signal processing is what distinguishes today's cutting-edge radar transmitters from the rest. 

Pulse Burst Radar extracts accurate levels from false targets and background noise through its sophisticated signal processing capabilities. Because pulse burst radar circuitry is highly energy-efficient, no duty cycling is required to achieve effective measurement. As a result, Pulse Burst Radar can track high rates of change that would be impossible to track with other loop-powered radar transmitters. Although Pulse Burst Radar has a robust false target recognition and rejection routine, proper installation significantly minimizes false target reflections. 

Antennas 

The radar signal is transmitted and received by the antenna on the transmitter. Each antenna's maximum measuring range is primarily determined by dielectric constants and the degree of turbulence. Horn antennas can measure dielectric media as low as 1.4, whereas rod antennas have a minimum dielectric of 1.7. 

Benefits 

Pulse Burst Radar measures a wide range of media accurately and reliably in a wide range of process conditions, from calm product surfaces and water-based media to turbulent surfaces and aggressive hydrocarbon media. As a non-contact device, Pulse Burst Radar is immune to the complications that can occur when a probe comes into contact with the process media, such as coating from high viscosity media or corrosive attack from aggressive chemicals. Given the cost of extended probe lengths, the greater the measuring range, the more radar proves to be the cost-effective solution. Temperatures, pressures, the presence of vapors, and air movement within a vessel's free space have little effect on the radar. Specific gravity, conductivity, and dielectric constant changes do not affect measurement accuracy. The lack of moving parts in a 100% electronic instrument translates into low maintenance costs, and, as a two-wire, loop-powered device, power requirements and installation are greatly simplified.

Miller Energy, Inc.
https://millerenergy.com

In New York Metro and Northern NJ
Phone: 800-631-5454

In Eastern Pennsylvania and Delaware:
Phone: 610-363-6200

In Western Pennsylvania:
Phone: 412-257-0200

In Ohio:
Phone: 440-735-0100

Magnetic Level Indicators and Controls for Industrial Process Applications

Magnetic Level Indicators and Controls

Fluid process control operations frequently involve the storage of liquids in a vessel or tank. The continuous and accurate indication of the liquid level within the tank is an important data point for process control decision making and safety. Several tank level measurement methods and instrument types are available, each with its own set of characteristics that may be advantageous for a specific installation. 

A tank liquid level indicator's selection criteria often include: 

  • Does the process require direct or indirect measurement of level?
  • What level measurement accuracy and reliability is needed?
  • What is the tank shape, regular or irregular?
  • Are there concerns with media compatibility with measurement device materials of construction?
  • How often will maintenance or calibration be needed?
  • Is the instrument capable of operating at the process temperature and pressure for the application?
  • Does the application require local display and visibility or remote?
  • Are control signals from the level indication required? What type and transmission protocol?
  • What kind of redundancy and safety devices, such as additional switches, are needed?

Magnetically coupled liquid level indicators, or MLIs, are widely used in the process industry. They are accurate, consistent, and reliably indicate liquid level. These units are completely sealed and do not require any maintenance. MLIs also eliminate the vapor or liquid emission issues that plague sight and gauge glasses. 

Most Compelling Reasons for Using MLI's:

  • Level measurement is continuous. 
  • Operable without the use of electricity. 
  • Regardless of tank shape or profile, they provide a direct visual tank fluid level indication. 
  • They are available in wide operating temperature and pressure ranges. 
  • MLI construction is resistant to breakage.
  • A variety of materials are available to accommodate corrosive media. 
  • Externally mounted measuring indicators, switches, and transmitters do not come into contact with the process media. 
  • MLI's provide a continual operation that requires little maintenance. 
  • The level indication is viewable from a greater distance than glass sight gauges. 
  • With a single instrument, it is possible to measure large fluid level ranges.

Magnetic level indicators have a strong presence in tank liquid level measurement and should be considered a candidate for meeting those application requirements. There are numerous options for customizing the level indicator for each application.  Work with your local Sales Engineer,  a specialist in level measurement, about your application challenges and positive outcomes. 

For more information, contact your local Miller Energy, Inc. regional office:

South Plainfield, NJ Office
Serving Northern NJ, New York, and Fairfield County Connecticut
South Clinton Ave.
South Plainfield, NJ 07080
Phone: 908-755-6700
Toll Free: 800-631-5454
Fax: 908-755-0312

Exton, PA Office
Serving Southern NJ, Eastern PA, Delaware and Central and Eastern Maryland
505 Gordon Drive
Exton, PA 19341
Phone: 610-363-6200
Toll Free: 888-631-5454
Fax: 610-524-7254

Cleveland, OH Office
Serving Ohio
555 Golden Oak Parkway
Cleveland, OH 44146
Phone: 440-735-0100
Fax: 440-735-0123

Choosing the Right Industrial Level Technology In Foaming Situations

In the chemical, manufacturing, food and beverage, life sciences, and other process industries, foam is sometimes a problem in liquid tanks. There is no "one-size-fits-all" level measurement option for foam because of its fluid nature. Understanding the properties of the foam and the type of measurement required is critical. Foam can form in a tank for various causes, including injecting air or gas into the liquid or agitator/mixing blade activity. Understanding the nature of the foam and the process is essential to minimize potentially costly errors when choosing a level measurement technique, regardless of the source.

For more information about applying the right instrumentation for level measurement in the presence of foam, contact Miller Energy, Inc.

In New York Metro and Northern NJ
Phone: 800-631-5454

In Eastern Pennsylvania and Delaware:
Phone: 610-363-6200

https://millerenergy.com

The Valve for Abrasive and Slurry On/Off and Control Applications: The Ball Sector Valve

Ball Sector Valve

The Ball Sector Valve is intended to perform well in harsh environments such as slurries, dry media, fluids containing suspended solids, or liquids containing fibers. When combined with pneumatic and electric actuators, it is the best choice for exact control in various process industries such as mining, pulp and paper, and the chemical industry. 

The ball sector valve comprises a hemispherical shell - the ball sector - that is securely held in place in the valve body by two large bearing stems.

Ball sector valves deliver exceptional performance in demanding applications. When conventional butterfly and ball segment valves are closed, their critical sealing components are subjected to the most wear in the valve. Because of the unique design of the ball sector, the seal seals through a surface part that is less prone to wear. The ball sector valve facilitates sealing through less exposed areas of the ball sector to avoid abrasion-caused leakage. The sealing surface is not exposed to high flow velocities significantly extends the service life of ball sector valves. A self-adjusting PTFE packing with an integrated spring element seals the shaft and protects the bearing from media particles. This innovative seal design, combined with a variety of materials and finishes for the ball sector and valve seat, significantly extends the valve's life compared to other valve technologies. As a result, it is particularly suited to abrasive, high viscosity, or fiber-containing media. 

The modified equal-percentage operating characteristic (difference pressure increases as the valve closes) combined with the outstanding rangeability of 300:1 means that the valve can be used for most control tasks. The valve body's special connection ensures that the differential pressure on the valve has little effect on the actuating torque. 

Other technologies, such as a segmented ball or rotary globe valves, employ an excentric shaft, causing the ball or plug to lift up from the valve seat when the valve begins to open. As a result, sealing areas are immediately subjected to permanent wear. Particulate can become lodged between the seal ring and the ball/plug. The ball sector valve has centric and robust trunnions that allow the ball sector to maintain constant contact with the valve seat, preventing media contamination. Changes in differential pressure have no effect on the permanent actuation torque.

For more information about Schubert & Salzer products, contact Miller Energy by calling 800-631-5454, or visit https://millerenergy.com.

Selecting Variable Area Flow Meters for Process Flow Measurement

Variable Area Flow Meters

Many industrial processes involve the movement of fluid product components, either liquid or gaseous, through pipes. Because processing is about control, an input to the facility's management, measurement, or data logging centers will answer the query, "How much is going through that pipe?" 

In the industrial process measurement and control industry, there are several ways for quantifying flow, each with unique characteristics that may be useful under certain operating situations. All flow measuring methods are indirect because the actual measurement is of a character influenced predictably by a change in the media flow. Flow measurement is a critical component that, when paired with other fluid properties, is used to calculate the total mass of a fluid passing through the measurement site. 

The variable area meter, commonly known as a rotameter and VA meter, is a tried and true flow measuring device that operates by creating an equilibrium between an upward force created by fluid motion and a downward force, gravity. A tapering glass or metal tube encases a specifically shaped float, also known as a shaped weight, in the device. VA meters must be positioned vertically, with the media flowing upward from the bottom, so that the gravity force required for functioning is correctly aligned with the flow direction. As fluid flows upward via the precisely tapered tube, drag is created on the float enclosed within the tube, pulling it upward. As the float rises, the open space between the float and the tube wall expands, causing the fluid velocity and drag force to decrease. The flow velocity within the tube will cause the weight to climb for any given flow volume until the drag force generated by the flow reaches equilibrium with the countervailing power of gravity on the float. The tube and float are well designed, allowing for an immediate indication of flow volume.

Variable area flowmeters have the following operating characteristics: 

  • There is no need for external power or fuel for functioning. 
  • Vertical installation is required, with flow arriving at the bottom. 
  • Meters are calibrated to a given chemical and temperature. 
  • The operation is stable and has a modest pressure drop. 
  • For operation, constant gravity is required. 
  • Flow rate can be read locally using a meter or a scale inscribed on the tube. 
  • The visibility of the float through the medium is required for unit flow readings using glass tubes. 
  • For industrial flow metering equipment, accuracy is relatively low. 
  • Inexpensive upkeep, simple construction, and low comparative cost.

Brooks Instrument, a world-renowned maker of flow, pressure, and level measurement equipment, created a brief paper highlighting the parameters to consider when specifying a VA meter and how each aspect influences the unit's performance. The description is realistic and straightforward to grasp. It is suggested reading for all process stakeholders who want to improve their flow measuring skills.

For more information about variable area flow meters contact Miller Energy. Call 800-631-5454 or visit https://millerenergy.com.