6 Reasons to Choose Brooks SLA Series Mass Flow Controllers

As firms migrate from Fieldbus to Ethernet networks, EtherNet/IP™ and PROFINET are the fastest growing digital communication technologies in industrial automation. They ship the newest industrial ethernet nodes, almost 64% of the market. EtherNet/IP ™and PROFINET enable users to collect relevant data that helps keep essential systems on track by linking devices to a single network. Information sent across EtherNet/IP™ and PROFINET networks provides better diagnostics, deviation alarms, and predictive maintenance, maximizing system uptime and lowering costs. 

As a result of this collaboration, Brooks Instrument has added EtherNet/IP™ and PROFINET protocols to its industry-leading SLA Series mass flow controllers (MFCs). The SLA5800 and SLAMf mass flow controllers support EtherNet/IP™ or PROFINET protocols and include advanced alarm and diagnostic capabilities.

Industry's Leading Ethernet Protocol Adoptions: EtherNet/IP™ and PROFINET 

The value proposition for EtherNet/IP™ and PROFINET is standard Internet and ethernet protocols. 

• Options for star, ring, or daisy chain topologies. 
• Operators can monitor real-time performance and network data by complying with IEEE Ethernet standards. 
• Flexible network architecture compatible with ordinary Cat 5 cabling and routers simplifies network setup and guarantees all devices interact and exchange data. 
• EtherNetIPTM and PROFINETTM enabled devices can provide rich data for process control, monitoring, diagnostics, and predictive maintenance.

REASON 1: OPEN, NON-PROPRIETARY, AND FUTURE-PROOF. 

Because EtherNet/IP™ and PROFINET use the Common Industrial Protocol (CIP™), support exists from a vast ecosystem of solution providers for industrial process automation. EtherNet/IP™ and PROFINET readily connect to a wide range of DCSs and PLCs, including: 

• Allen-Bradley
• Emerson 
• Siemens
• Rockwell

REASON 2: INTEROPERABLE WITH INDUSTRY-LEADING CONTROL SYSTEMS THROUGH ETHERNET/IP™ AND PROFINET

Due to the ability of contract manufacturers and end-users to use the EtherNet/IP™ and PROFINET protocols to: 

• Cut operating costs 
• Boost process efficiency, quality, yield, and output.

REASON 3: PLUG & PLAY INTEGRATION WITH ROCKWELL AUTOMATION (ALLEN-BRADLEY) PLCS. 

Brooks Instrument engineers worked with Rockwell Automation to provide an upgraded device profile that simplifies the setup and integration of the MFC into the Rockwell Automation (Allen-Bradley) PLC. The SLA5800 and SLAMf are now compatible with EtherNet/IP™ from renowned automation manufacturers. 

The upgraded device/add-on profile: 

• Setup or edit any of the attribute tabs or parameters. The user determines which attributes are appropriate for their procedure. 
• Removes the requirement for programming expertise to connect the MFC to the network.

REASON 4: SLA5800 AND SLAMF FULLY INTEGRATE ETHERNET/IP™ AND PROFINET. 

On the SLA5800 and SLAMf with EtherNet/IP™ or PROFINET, we deliver on our promise to provide value without losing equipment space. Brooks Instrument designed EtherNet/IP™ and PROFINET directly into the mass flow controller, eliminating the need for add-on adapters or modules. The SLA5800 and SLAMf MFCs completely integrate EtherNet/IP™ and PROFINET. The EtherNet/IP™ or PROFINET equipped SLA5800 and SLAMf MFCs have the same footprint as the regular SLA5800 and SLAMf. They also link to your EtherNet/IP™ or PROFINET networks, eliminating the need for additional hardware such as gateways, analog I/O cards, or bespoke cabling and wires. All you need is standard ethernet wiring to get your device running and linked to the network.

REASON 5 : EASY WEB-BASED CONFIGURATION OF ETHERNET/IP™ AND PROFINET NETWORK SETTINGS IN SLA5800 AND SLAMF.

The SLA5800 and SLAMf with EtherNet/IP™ or PROFINET have a user-friendly TCP/IP configuration. A web-based interface connects the MFC to the user's EtherNet/IP™ or PROFINET networks. Once on the network, the user can quickly identify individual MFCs, saving time if the system has several MFCs.

REASON 6: THE LATEST DIAGNOSTICS AND PREDICTIVE FUNCTIONS, SOME EXCLUSIVE TO BROOKS INSTRUMENT MFCS, ARE ENABLED BY ETHERNET/IP™ AND PROFINET PROTOCOLS. 

Intelligent and data-rich mass flow controllers, the SLA5800 and SLAMf with EtherNet/IP™ or PROFINET may improve operational efficiency in equipment automation, metrology, and maintenance. 

For example, limiting the upstream gas input pressure may affect MFC accuracy. The alarm data could be supplied to an operator via the built-in restricted flow alarm.

    

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

Miller Energy Is a Premier Manufacturer's Representative and Distributor of Process Instrumentation, Valves and Process Equipment

Miller Energy is an Industrial Instrumentation and Process Control Equipment Manufacturer's Representative and Distributor. We have been committed to exceeding our customers' expectations by providing unrivaled customer service and local technical support since 1958. We currently offer the most comprehensive range of measurement, control, and communication solutions in the industry.

Miller Energy provides a wide range of instrumentation and control solutions to many markets, including refining, water treatment, chemical production, and food and beverage. Miller's products are useful in applications that require measuring, controlling, monitoring, and analyzing pressure, temperature, level, flow, pH, O2, CO2, and various other process variables.

Miller Energy comprises the most technically savvy salespeople in the industry. All Field Sales Engineers are factory trained on all of our product lines. All Inside Sales/Technical Support Engineers are responsible for a specific product line and support our entire customer base. Intelligent geographic product distribution provides the most timely delivery for greater customer satisfaction.

Miller Energy has four office locations:

• The South Plainfield, NJ, corporate headquarters serves Northern New Jersey, New York, and Fairfield County, Connecticut. 
• The Exton, PA office serves Southern New Jersey, Eastern Pennsylvania, Delaware, and Maryland. 
• The Pittsburgh, PA location serves Western Pennsylvania, Western Maryland, and West Virginia. 
• The Cleveland, OH office serves Ohio. 

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

Vaisala K Patents Refractometers - Refractive Index Measurement

Vaisala K-PATENTS Process Refractometers provide in-line solids and density measurement  for liquids for process control and industrial automation. 

Vaisala K-PATENTS Process Refractometers are commonly used to determine the liquid concentration or density. This measurement has been an essential element in the processing industries for over a century in all sectors, including refining, paper production, pharmaceuticals, food and beverage, and chemical manufacturing. , 

The measurement principle is critical angle measurement. The refractometer has three main components: a light source, a prism, and an image detector.  

The light source sends light rays to the prism and process interface at different angles. Rays with a steep angle are partly reflected in the image detector and partially refracted to the process. The angle from which the total reflection starts is called the critical angle. A CCD camera detects a bright field and a dark field corresponding to partly reflected light and totally reflected light. The borderline position between the bright and the dark area correlates with the critical angle which is a function of the refractive index and therefore correlates with the concentration of the solution.

For more information in New Jersey, New York, Pennsylvania, Delaware, Ohio, West Virginia and Western Maryland contact Miller Energy. Call 800-631-5454 or visit https://millerenergy.com.

Happy Holidays from Miller Energy, Inc.

New White Paper from Brooks Instrument: Satisfying the Increasing Need for 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 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