This is the first in a series of articles that will explore “The Worth of Water.”
“Water culture” is the set of shared practices, values, and attitudes surrounding the use of water in a community. It’s multi-dimensional, with its many aspects determined on individual, community, and national levels. Water culture encompasses both personal and collective responsibilities, from how much water you use in the shower, to water restrictions on a city level, to the general feeling about water scarcity or surplus in an entire nation—with effects rippling into the rest of the world. Appropriate water culture should result in smart water management that begins with awareness, ends with policy, and is the first step to combatting water scarcity.
How aware are we of the water we use every day? We use it to make our coffee in the morning, wash our clothes and dishes, cook, and shower—but how often we do these things and how much water we use for them depends on how much water we believe is available to us and our communities. Different communities naturally have different levels of awareness. Ghana, where clean water is scarce, has a much different water culture than the United States. But what about differences within our own country? In Elliston, Virginia, we don’t hesitate to water our plants or take a 30-minute shower, but residents of Las Vegas have to be more thoughtful about those activities.
Even though the water culture in the West produces heightened awareness of water scarcity, that doesn’t always lead to changes in policy. Las Vegas, for example, doesn’t have a municipal water reuse system. Moreover, much of the water they do use is evaporating from the many water features on The Strip. Even though the city relies on the dwindling Colorado River for its water, residents still plant grass and water their lawns, and there hasn’t been any large-scale public utility action, such as increasing employee awareness of water use, choosing water-efficient models for fixtures and equipment (such as dry urinals), or widespread leak awareness (the effects of which are discussed here). Unless this water culture changes, how long will it take for the well to run dry?
What is the worth of an inch of water on the East Coast? Is it the same on the West Coast? Should it be? Las Vegas and Phoenix are the least sustainable cities in the world. There, the issue of running out water is not a matter of if, but when. We would assume that residents and municipal governments would react differently in that water culture, since it’s a desert with very few adjacent lakes and rivers. With less water available, shouldn’t they value water more highly? But the Colorado River is running dry as cities in the West hatch plans to draw water from other parts of the region. There is heavy demand on water bodies in the Southwest, but many cities aren’t going the extra mile to take proactive actions restricting water use.
On the surface, it seems like the issue of water sustainability should be cut and dry. But overuse of water resources flows even further into the undercurrents of communities. Deep water culture is revealed in how a city allocates its budget to water stewardship. Industries that require tens of thousands of gallons of water a day to produce a good should not be based in cities where water is already scarce. Likewise, communities should practice good water stewardship. California has been dealing with various levels of drought for more than 100 years—but even this state, a leader in environmentalism and sustainability, is just beginning to experience residential water restrictions. A law set to be implemented later this year will restrict residential usage to 55 gallons per day. The downfall of this law is that although its goal is to create a “culture of permanent water conservation,” water agencies are not required to ensure this new target is kept.
Combatting Water Scarcity
Beginning with awareness and education, water culture should be the lens through which a strong industrial economy evaluates the best areas to generate public goods. The more water a product requires to develop, the closer the industrial plant should be to a large body of water—revealing smart economic development and water policy. Awareness in these issues will affect the votes of citizens, resulting in city and state representatives who will make the choices that will allow the city to buffer the withering effects of water depletion.
Citizens experience a reflection of their own water culture in their daily relationship with water. How long do you leave the water on while your brushing your teeth or shaving? Do you unravel your hose unnecessarily for yard work? Lawmakers and private interest groups influencing water policies demonstrate their own priorities in their private lives by these small tasks. Looking at water policy through a bottom up process that starts with the foundation of our own water culture reveals that we don’t yet consider the current water crisis be as pressing as it is.
One of our company values is to protect people and the environment. We seek to do this through partnering with industrial plants to help them safely reuse water and discharge wastewater, reducing the burden on local water utilities. We take pride in using chemicals and processes that aren’t harmful to the environment or to people. Based in beautiful Southwest Virginia, we understand how sensitive our lands and waterways are to misuse and pollution.
On Sunday, July 15, 2018, the Roanoke Times published an article (and later a follow-up) about discoloration in the James River due to a waste treatment issue at a paper mill in Covington, Virginia. Of course, any change to sensitive river ecosystems is a potential cause for concern, but we also think it’s important to understand the severity of those changes.
Paper mills use millions of gallons of water a day and often discharge their wastewater into local waterways, since water utilities wouldn’t be able to handle such an influx. One way they can mitigate the risks of water discoloration and other related issues is to treat and reuse a majority of their water. By integrating an industrial water reuse system, 85% to 90% of their water could be reused, while treating and discharging only 10% to 15% of their daily intake.
While we don’t work with the paper mill mentioned in the article, we do partner with wood industry plants. (In fact, we recently published an article about one such customer.) The water they use to scrub fine wood particles from gases before they can be released into the atmosphere (to comply with EPA regulations) is exceptionally dirty. Tar and lignin, which caused the discoloration in the James, are unavoidable byproducts when working with wood. And they’re very difficult to clean from water. We spend a great deal of time and effort developing the most effective chemistry and systems to do so safely and within discharge limits.
So, what happens when those discharge limits are exceeded? If it’s a hazardous substance, the results could be catastrophic to people and the environment. Fortunately, that didn’t happen this time. Lignin is a natural substance found in the cells walls of plants. It’s separated from wood during the chemical process of forming wood pulp. While unfortunate, the one-time release of an excessive amount of lignin into the James was not on the scale of a “hazardous spill.” Likewise, the accidental release of biodegradable defoamer (probably a mineral oil-based one) should not be a cause for concern.
It’s important to keep an eye on industry and to advocate for greater water reuse and the rigorous application of discharge limits. Better water management policies are needed to prevent pollution and to preserve our supply of fresh water. Water reuse and treatment technologies like the ones we develop are important in this effort.
ProChem recently completed another project that embodies our mission: to advance our customers’ total water management strategies by providing innovative solutions supported by a comprehensive set of services. This project required the coordination of chemistry, equipment, technology, and customer-centered collaboration—all the disciplines on which ProChem was founded and continues to operate.
Prior to finding ProChem, this wood products manufacturer had been working with their local publicly owned treatment works (POTW) to treat their water. They needed to lighten their heavily pigmented water so that it could be penetrated with a UV light in order to disinfect it before discharging to the POTW.
The company initially hired an engineering firm to find a solution, but because there are so many nuances in waste water treatment that require expertise in multiple disciplines, they were unable to provide one. They would have needed to understand the wastewater, the chemistry, and the unique needs of the customer—a specialized set of services they turned to us to provide.
The plant’s wastewater comes from their wet electrostatic precipitator (WESP) system, which uses water and electricity to scrub fine wood particles from gases before they can be released into the atmosphere according to EPA regulation. Those fine wood particles end up in the wastewater that the ProChem system needed to treat. Our starting point was our CleanWESP water treatment program, designed by ProChem chemists specifically for the wood products industry to protect valuable equipment such as the WESP. Even with this solution in place, this customer had significant problems that would require some creative problem-solving. Fortunately, our team lives by the premise, “The bigger the problem, the bigger the solution.”
While ProChem’s experts were researching the problem, the POTW continued to tighten their restrictions. As a result, the scope of the project pivoted from merely lightening the pigmented water for discharge to treating and reusing 10% of their wastewater inside the plant. This is what we refer to as a “kidney loop”—continuously treating part of the stream, rather than the whole thing, to keep the whole stream cleaner.
ProChem’s custom-tailored solution to treating wastewater for discharge while also implementing water reuse required a carefully orchestrated combination of chemistry, equipment, and technology.
When dealing with wood wastewater, there’s only one proven chemical treatment that works. A coagulant turns dissolved contaminants into solid particles, while the polymer holds those together to make bigger particles, which typically sink to the bottom. But in cases such as this, the wood particles float. The chemistry team at ProChem had to find a combination of polyamene, pH, coagulant, and polymer that had good separation to allow the solids to float in as compact a layer as possible and also produce water as clear as possible. At the plant, the particles on the top get skimmed off and go to the belt press, where the water in the sludge is removed and the sludge is disposed of.
The system that ProChem designed includes pretreatment, sand filtration, reverse osmosis membrane filtration, and UV lights. The system is based around a specialized chemical treatment program coupled with I-PRO™ and B-PRO™ membrane technologies. Designed to treat up to 60,000 gallons per day at 200 gallons per minute (gpm), the current system handles 125 gpm of reuse water and is integrated with existing clarifiers, dissolved air flotation (DAF), and a belt press.
ProChem fabricators constructed three Conex containers at our facility in Elliston, Virginia, and outfitted them with amenities for 24-hour, year-round operation—lights, heaters, fans, and ventilation.
One container houses three 62-ft3 sand filters operating in parallel with one in service at a time. The sand filters are equipped with automatic switching and backwashing of exhausted columns using permeate water.
Our membrane technology for this project included both I-PRO and B-PRO Conex containers. Both containers consist of an automatic prefilter switching to reduce down time, additional chemistry to prevent scaling and biological growth, and an automatic phase change based on conductivity—keeping discharge within operating parameters. The I-PRO container consists of 10 membrane housings, each with six membranes, while the B-PRO container has eight membrane housings with four membranes in each.
As always, we incorporated the most up-to-date technology that was appropriate for the customer’s particular needs:
The initial walkthrough at the customer’s plant revealed tight spaces that would require precise piping work to create the most efficient and sustainable system. For a clean piping sequence, our Project Superintendent made sure there were no “jumping pipes,” meaning no pipes overlap. Overlapping diagonal pipes make the system less serviceable. For example, simply fixing a valve could require cutting pipes. Because of our close attention to detail, that wouldn’t be necessary for this project.
This system is automated and continuously transmits data to ProChem’s AutoRun™ software. To accomplish this, our Controls & Instrumentation Engineer used the P&ID to determine how many PLC (programmable logic controller) inputs and outputs would be needed. The PLC is at the center of the control system, continuously monitoring the state of input devices and making decisions based upon a custom program to control the state of output devices as much as 100 times a second.
Our Controls & Instrumentation Engineer writes custom programs using algorithms to monitor flow, dose chemicals, adjust pH, control agitator speed, and much more. Any signal that can be measured can also be manipulated.
ProChem upgraded the customer’s wastewater treatment system to provide operators the means to enhance their process for meeting the plant’s water quality needs. As part of the upgrades, ProChem modernized the control system utilizing a Remote I/O solution. This technology reduced wiring costs while improving operational readiness and reliability.
The Remote I/O system provides a reliable method to transfer monitoring and control signals to and from the PLC-based control system. In this configuration, two Remote I/O stations are situated along the Ethernet network in different areas of the system. Each station contains five to 10 I/O modules. For monitoring applications, the system collects signals from analog transmitters or discrete devices. It concentrates the signals and, when polled by the network master, sends them over the Ethernet network directly to the main PLC control panel. For control, process commands from the host are transmitted over the network and converted to analog or discrete form to control valves, pumps, motors, and other types of proportional and on/off control elements.
This wood products manufacturer has a large and complex treatment system with multiple moving parts. The challenge for us was to make all those parts work together in balance. It was the most complicated control system our engineers have ever designed.
As always, we maintain an ongoing relationship with this customer and continue supporting them both remotely and on-site. In fact, one of our Environmental Technicians is responsible for the day-to-day optimization of the system.
ProChem’s team took a customer who was discouraged and gave them the solution they needed to protect their costly (about $1 million/year) WESP equipment by treating and reusing their wastewater. The remaining wastewater is discharged to the POTW, guaranteed to maintain compliance.
Looking for a solution to your industrial water problems? Contact our experts today!