Water Quality - Constituents That Impact Industrial Operations (Part 1)

aerial view of sewage treatment plant
Sewage treatment plants are only one of many applications
where water quality is a concern.
Of all the raw materials available for human consumption – aside from the air we breathe – the most vital component of life on earth is water. In addition to the global need for humans to drink water in order to survive, the use of water is essential in a myriad of industries relating to process control. Whether the goal is the production or monitoring of pure water for industrial use, or the processing of wastewater, the ability to measure the presence and level of certain chemical constituents of water is necessary for success.

In order to use water properly, industrial professionals combine state of the art analyzers with technical expertise to evaluate water quality for use or disposal. Two essential values of process control are ensuring elements of a control system are accurate and secure, and, furthermore, that they are accurate and secure for each product every time. By properly vetting water in industry, engineers and other personnel in fields such as pharmaceuticals, chemical, food & beverage, brewing, power, and microelectronics are able to maintain standards of production excellence and conform with regulatory requirements related to water quality.

The amount of dissolved oxygen present in water can correlate with the degree of movement at an air-water interface, also being impacted by pressure, temperature, and salinity. Excessive or deficient dissolved oxygen levels in industrial process waters may have an impact on process performance or end product quality. Likely, the most common application for dissolved oxygen measurement is in the evaluation of wastewater for biological oxygen demand. The primary function of dissolved oxygen in wastewater is to enable and enhance the oxidation of organic material by aerobic bacteria, a necessary step in treatment.

To measure dissolved oxygen, specialized sensors and companion instruments are employed that require careful maintenance and trained technical operators. The level of measurement precision varies depending on the industry employing the technology, with numerous applications also being found in the food & beverage and pharmaceutical industries. In-line continuous measurement is used in wastewater processing to determine if the dissolved oxygen remains in a range that supports the bacteria necessary for biodegradation.

Chloride concentration in wastewater is strictly regulated. Industrial and commercial operation effluent can be regulated with respect to allowable chloride content. While commonly found in both streams and wastewater, chlorides, in large amounts, can present challenges to water utilization or processing facilities. Chloride levels impact corrosion, conductivity, and taste (for industries in which such a variable is paramount). In a process system, having an essential component marred due to elevated quantities of a substance could reverberate into any end-product being manufactured. Chloride analyzers, some of which can also detect and monitor other water characteristics, serve as important tools for water consuming facilities to meet regulatory standards for effluent discharge or internal quality standards for recycling.

There are other constituents of what we refer to as “water” that are subject to measurement and monitoring for a range of institutional, industrial, and municipal applications. Those will be explored in the next part of this article series.

Analynk Wireless manufactures wireless connectivity solutions for industrial applications and process control. Making cable free connections among process control equipment and instruments, across the room, across the property, across the globe.



Continuous Liquid Level Measurement Technologies Used in Industry

crude oil storage tanks
Process measurement connectivity with wireless technology
is suitable for almost any application 
Although continuous level measurement technologies have the ability to quantify applications for bulk solids, slurries, and granular materials, this article will focus on level measurement technologies applied to liquid level measurement utilized in process control. A distinction should be made between continuous level measurement and point level measurement. Point level measurement acts like a switch, changing state when a single level condition is achieved. Called “transmitters,” continuous liquid level measurement devices employ technologies ranging from hydrostatics to magnetostriction, providing uninterrupted signals that indicate the level of liquid in a vessel, tank, or other container.

Hydrostatic devices focus on the equilibrium of dynamic and static liquids. There are three main types of hydrostatic transmitters: 1) displacer, 2) bubbler, and 3) differential pressure.

The displacer transmitters utilize a float placed within the liquid container. With its buoyancy characterized to the liquid and the application, the float, a connecting stem, and a range spring or similar counterbalance represents the liquid level in terms of the movement of the displacer (float). The displacement, or movement, of the assembly is converted into an electric signal for use by the monitoring and control system.

Bubbler transmitters are used for processing vessels that operate at atmospheric pressure. This method introduces a purge gas or an inert gas, e.g. air or dry nitrogen, into a tube extending into the liquid vessel. Precise measurement of the pressure exerted on the gas in the dip tube by the liquid in the tank is used to determine the height of the liquid.

Differential pressure (DP) transmitters rely directly on, in a basic explanation, the pressure difference between the bottom and top of the container. Precise pressure measurement is used to determine the height of the liquid in the tank. One of the most advantageous aspects of DP transmitters is that they can be used in pressurized containers.

Other examples of level transmitter technologies which are not hydrostatic devices include magnetostrictive, capacitance, ultrasonic, laser, and radar.

In magnetostrictive level transmitters the measuring device, a float, has a magnet that creates a magnetic field around a wire enclosed in a tube. Electrical pulses sent down the wire by the transmitter head produce a torsional wave related to the position of the float, which moves with changes in liquid surface level. The transit time of the torsion wave back to the sensing head is measured and the depth of the liquid, as indicated by the float position, can be determined.

Capacitance transmitters are best applied to liquids that have high dielectric constants. Essentially, changes in the capacitance of the sensor / tank / liquid assembly will vary proportionately with the liquid level. The change in capacitance is measured and converted to an appropriate electrical signal.

Ultrasonic level transmitters emit ultrasonic energy from the top of the vessel toward the liquid. The emissions are reflected by the liquid surface and them time required for the signal to return to the source is used to determine the distance to the liquid surface.

Laser level transmitters operate similarly to an ultrasonic level transmitter. However, instead of using ultrasound signals, they use pulses of light.

Radar level transmitters involve microwaves emitting downward from the top of the container to the liquid’s surface. The measured time for receipt of a return sign reflecting off the liquid surface enables calculation of the distance from the sensor to the liquid surface.

The precise measurement of transmit time for a wave or pulse of energy is employed in several of the technologies, the measurement of pressure in others. Each technology has a set of attributes making it an advantageous selection for a particular range of applications.

Analynk Wireless provides connectivity solutions enabling the wireless transmission of measurement data across the room, across the property, across the globe. Share your process measurement and control connectivity challenges with the experts at Analynk for a solution that is simple to implement and cost effective.

Wireless Communications Deliver Real Time Process Data From Remote Operating Sites

communications satellite orbiting the earth
No distance is too near or far for industrial wireless
communications
Oil is where you find it, with many prospecting and production sites located where the communication options taken for granted in developed areas do not exist. Oil is big and serious business, with tremendous sums of money at risk on the prospect of reaping even greater returns. Every business operation, though, is of great importance to the stakeholders. Countless operations in little known industries and endeavors are located beyond the boundaries of modern communications infrastructure. 
If you want a data connection, bring your own.
Remote operating sites, whether for oil extraction or other purposes, will often be automated. Some decision making system or individual is responsible for the safe and effective operation of the remote site, or has a use or need for real time data being gathered at the remote site. Radio transmission is a viable, maybe the best, option for delivering real time data from a remote site to a central office.
  • Transmission options for 900 MHz, 2.4 GHz, cellular, and satellite systems are readily available.
  • Equipment operates on low voltage, low power. Suitable for solar or other remote site power source.
  • No special instrumentation needed. Radio transmitting and receiving equipment interfaces directly with analog signals from common industrial process transmitters.
  • No "across the land" cabling needed.
  • Equipment can be configured to resist extreme environmental conditions.
Analynk manufactures transmission and receiving equipment that builds the bridge between remote sites and the home office. From elemental componentry to integrated, ready to run systems, Analynk specializes in wireless communications for industrial process control. Contact us with your wireless challenges. Whether an expansive multipoint, or a single point application, the specialists at Analynk can combine standard or customized products into a practical solution for every application.

One Transmitter, One Receiver, Multiple Process Signals

Multiple input output module connects to single receiver or transmitter
A16000 Multiple I/O Module
Analynk
Radio frequency (RF) communications can enable the establishment or cost effective, quick, process signal connections across very small or very large distances. A misconception arises, from time to time, that it is necessary to have a dedicated transmitter and receiver for each process signal. Analynk has a solution that provides for delivery of up to sixteen process signals over a single transmission path.

Wireless transmission of process control signals is steadily increasing in prevalence throughout commercial, institutional and industrial settings. The ease of implementation, with no long cable runs to plan, layout, install, protect, and maintain, allows wireless installations to fulfill application niches that may have been considered impractical in the past.

Analynk provides hardware that easily allows the transmission and reception of up to 16 I/O points using a single transmitter and receiver. The A16000 Expansion Module can be configured with up to four internal cards that accommodate various types of input and output signals. The process is similar to setting up the I/O on a PLC. Connect the process signals to the A16000, and the A16000 to one of Analynk's transmitter or receiver devices. Setup is straight forward and allows the installation to be operable in minimal time.

Share your wireless communications and signal transmission challenges with the experts at Analynk and get recommendations on how to best implement workable solutions.


Automation and Grain Processing

grain storage silos
Grain processing benefits from automation and industrial wireless
The grain industry serves as an example of industrial process control, where standards are maintained at a constant rate for product delivery. Automation in grain processing provides both safety and efficiency by supporting the product delivery process. Historically, the grain production process has been hazardous, with industry workers subject to harsh conditions and potential risks associated with the grain, such as flammable grain dust. The transition from manual labor to automation has become the industry’s essential shift, with automation now a staple in harvesting, milling, and handling grain. The developers of automation components seek to mitigate production ineffectiveness and inventory miscalculations. Solids level transmitters, responsible for continuously monitoring the amount of grain in potentially hazardous environments, are a reliable replacement for employees at a silo’s peak.

Thanks to developments in technology, the implementation of sustainable automation does not need to come at the expense of company profit. A sole driver needs to control automation operations when dealing with grain handling, meaning that the number of employees put at risk via that stage in the process is substantially reduced. In order to keep track of inventory, automated management tracks not only the levels of grain inside silos but also where materials are located throughout the production facility. Grain sensors allow for the constant communication of how much grain is being moved through grain elevators and terminals. Instrumentation measures level, weight, and flow of solid grain while maintaining process protection.

Grain terminals allow for grain to be unloaded into hoppers, and then conveyors transfer those hoppers to the elevators. Cleaning drying, and blending machinery all employ automation, reducing the risks presented to employees. Truck and rail load-outs need to be close to target levels, because overloading or under-loading transport results in product loss. Preventing the loss of time and physical resources is a key element of automation. Radar transmitters cut through dust in silos to deliver reliable information back to the process operators. Ultrasonic instrumentation matches with point level technology to indicate when grain levels are high or low.

The handling and blending of raw materials can be monitored by solid flowmeters, with high accuracy still applicable in more compact spaces. A similar solid flowmeter ensures the accuracy of the flow rate and weight of solids measured in bulk, and can also be used in tandem with flow and weigh feeders to keep each individual load of grain consistently accurate. The applications of automation throughout the grain production process have evolved into a reliable means of reducing employee risk while ensuring accuracy and increasing throughput.

Grain operations cover large areas. A reliable, flexible, and cost saving way to establish the needed process control connections throughout the facility is via industrial wireless. Connections between measurement instruments and control units can be created across very long distances without the need to install conduit and cabling. Connections can be created quickly and reliably, with flexibility to increase throughput as more stations or sensors are needed. Equipment is suitable for general or hazardous locations. Contact an industrial wireless communications expert for help in developing connections on your project.





Diaphragm Seals Protect Industrial Pressure Gauges and Transmitters

industrial pressure gauge with diaphragm seal installed
Industrial pressure gauge with diaphragm seal installed
Courtesy Wika
Pressure measurement is a common element of industrial operations and control systems. Fluid processing can often involve media that is potentially harmful to pressure sensing devices. The media may be corrosive to the sensor material, or other media properties may impact the performance or usable life of the instrument. In process control environments, diaphragm seals play a role in protecting items like pressure sensors from damage by process fluids. The diaphragm seal is a flexible membrane that seals across the connecting path to a sensor and isolates the sensor from the process media. System pressure crosses the barrier without inhibition, enabling accurate measurement, but the process fluid does not. Typical materials composing diaphragm seals are elastomers, with a wide variety of specific materials available to accommodate almost every application.

In the operating principle of the diaphragm seal, the sealed chamber created between the diaphragm and the instrument is filled with an appropriate fluid, allowing for the transfer of pressure from the process media to the protected sensor. The seals are attached to the process by threaded, open flange, sanitary, or other connections. Diaphragm seals are sometimes referred to as chemical seals or gauge guards. Stainless steel, Hastelloy, Monel, Inconel, and titanium are used in high pressure environments, and some materials are known to work better when paired with certain chemicals.

Sanitary processes, such as food, beverage, and pharmaceuticals, use diaphragm seals to prevent the accumulation of process fluid in pressure ports, a possible source of contamination. If such a buildup were to occur, such as milk invading and lodging in a port on a pressure gauge, the resulting contamination compromises the quality and purity of successive batches. Extremely pure process fluids, like ultra-pure water, could be contaminated by the metal surface of a process sensor. Some pneumatic systems rely on the elimination of even the smallest pressure fluctuations, and diaphragm seals prevent those by ensuring the separation of the process materials from the sensors.

Diaphragm seals are not without some application concerns, and devices are now built to address and counter many potential issues related to the use of diaphragm seals with process monitoring instruments and equipment. Products seek to eliminate any and all dead space, allow for continuous process flow, and are self-cleaning thanks to continuous flow design. Some high pressure seals come equipped with anti-clogging features, accomplished by the elimination of internal cavities while protecting gauges. Multi-purpose seals reduce temperature influence and improve instrument performance while pinpointing and diffusing areas of high stress. These pre-emptive measures result in longer instrument life-cycles and improved performance while ensuring protection from corrosion.

There are numerous options and available diaphragm seal variants. Share your application specifics with a product specialist, combining your own process knowledge and experience with their product application expertise to develop an effective solution. Analynk Wireless manufactures industrial wireless communications equipment and process transmitters.

Tachometer Transmitter for Industrial Process Measurement and Control

industrial motor pump assembly
Tachometer transmitters deliver rotational speed signals
Analynk Wireless, in addition to producing their line of products for establishing wireless connections among industrial process measurement and control devices, manufactures an extensive array of wired products. The wired products are useful in establishing similar connections between sensors and the devices or instruments that will utilize their output signals. The transmitters are available with a wide array of input and output combinations, as well as several enclosure options. Enclosures can be customized to meet specific installation challenges.

The tachometer transmitter will convert the pulse signal from a tachometer into a linear signal representing rotational speed. There are many applications where a frequency output from a tachometer or other sensor needs conversion to a 4-20 mA or other common signal for use by a monitoring instrument. Analynk provides transmitters to easily convert almost any sensor signal to a linear voltage or current output. A data sheet is included below that provides more detail about one of the many transmitters available from Analynk.

Share your connectivity challenges with the process signal transmission experts at Analynk. Effective solutions come through consultation and cooperation.