Panel Builder US

February 18, 2020

South Florida Distillers ( is the oldest distillery in the city of Fort Lauderdale, Florida. The company is now branching out into the design business by working with 26° Brewing ( to help them brew world-class craft beers.

Greg Lieberman is the founder and owner of 26° Brewing in Pompano Beach, Florida. He started out as a homebrewer making 10 gallons per batch in a variety of locations such as the garage, the kitchen, a sibling’s backyard and in a barn. Greg’s homebrew career saw about 100 batches in four years, totaling one thousand gallons of beer.

Once he perfected his craft, and with the help of South Florida Distillers, he scaled up the 10-gallon recipes and now produces his beers in a state-of-the-art 30 barrel brewhouse (Figure 1). At 26° Brewing, a sports bar, meeting and retail area, and a fully functioning brewhouse are under the same roof. The brewhouse can produce 30 barrels per batch, with 31 gallons per barrel for a total of 930 gallons per batch, or 7440 pints.

Distillery Gets the Brew Flowing

Before creating South Florida Distillers, I took over the family plastics recycling and manufacturing business, now sold. We recycled commingled large bulk plastics into plastic shipping pallets, primarily for the cruise line industry, using a unique structural foam injection process. It used the recycled plastic and made an 18 pound plastic pallet every two minutes using a single-shot injection molding process.

The machines were all from the 1970s and 1980s, so most were relay controlled using a 25-foot-long control panel full of hardwired relays. Re-building the hydraulics and controls on the recycling machines using AutomationDirect micro modular PLCs was a great learning experience, and it made the equipment more productive and easier to support.

After selling the recycling business, I started South Florida Distillers, a craft rum distillery. I have designed and automated portions of the in-house rum distillery using a wide variety of AutomationDirect control hardware. Based on a demonstration of a 250-gallon distillery fermentation tank using an AutomationDirect PLC and temperature controllers to the owner of 26°Brewing, our company was selected as the designer and integrator of the system for their new craft brewery.

Of course, it helped that the owner of 26°Brewing, Greg Lieberman, was a longtime family friend.  His dad was my pediatrician, and we grew up on the same block back as children. When Greg decided to open the brewery, we discussed in great detail the functionality he wanted yet couldn’t find on the market. That was music to my ears, so I got started on the design.

South Florida Distillers designed and programmed a touch screen fermentation temperature control system for a new brewery installation at 26° Brewing. The controller is responsible for precise temperature stabilization and control of seven tanks initially and is expandable up to 16 tanks.

Crafty Brewing Steps

There are many steps to brewing beer, and this is not a complete list of process steps. During the initial steps, the grains are placed in water in a tank and heated, similar to a pasteurization process, to extract the starch. The grains are then strained out and the liquid is boiled. This converts the starch to sugar and also removes some water, increasing the sugar content of the liquid. After boiling for a time, the liquid is quickly cooled by running it through a plate heat exchanger. This cooling process also provides the opportunity for heat recovery for reuse in upstream processes.

Once the beer is cooled, the tank is drained and pumped to a fermentation tank. Typically, these fermentation tanks need to be cooled due to the heat produced by the metabolic process of converting sugar to alcohol. The fermentation part of the brewing process is where the beer spends most of its time. For example, Pilsner beers ferment about four days, and Lager beers take about two weeks. Controlling temperature during this “cold side” fermentation process is critical to the quality of the finished product.

After fermentation, the beer is transferred to the brite tank where it goes through a final quick cool, and a racking process to remove the beer off the top of the yeast, which settles to the bottom of the brite tank. From there, secondary fermentation may occur, such as adding fruit. Once this is complete, the final product is transferred to the cold liquor tank.

Automation System Details

The automation system consists almost entirely of AutomationDirect components in the following categories: programmable controller, operator interface, circuit protection, enclosure, switch, distribution block, multi-conductor instrumentation cable, DIN-rail and wire duct.

I have always loved working with AutomationDirect’s products. The website is easy to use and they always have what I need. The shipping terms are great, especially since the warehouse is located relatively close to us in the adjacent state of Georgia. Their tech support has never failed me, and their return policy is on point, although we’ve rarely had to use it.

The automation system is based on an AutomationDirect PLC (Figure 2) and touchscreen human machine interface (HMI). The system is being used to control the fermentation process in five stainless steel 30-barrel conical fermenting tanks adjacent to the brew house. These tanks are located in the rear of the facility, with a tap room in the front. The windows behind the bar allow visitors to see the five fermentation tanks, one stainless steel brite tank, and one stainless steel cold liquor tank in the back room.

As of now, the brewery automation system only controls the temperature of these seven glycol-jacketed tanks, but it could be expanded to include pump and motor controls, steam flow control and much more in the way of automating processes which are currently done manually. The automation system was also built to accommodate the future addition of fermenting tanks with minimal hardware changes and a simple software update.

Fermentation Control, The Cold Side

The general purpose of the cold side automation system is processing monitoring, process control, data acquisition and data logging of the fermentation process. Much of the process upstream of fermentation is manually controlled.

Although individual PID temperature controllers could be used at each of the seven tanks, the single AutomationDirect controller solution was a better solution and less expensive. The added value from the PLC comes from the remote viewing and control of the process, and the ease of training new users. The design also required less work on behalf of the electrician, and will be less expensive when it comes time to expand the brewing process.

The PLC includes two multipoint AC output modules to control the 19 solenoid-actuated water valves. Seven RTD sensors are connected to PLC input modules to measure tank temperatures using clean-in-place RTD probes. Each of the five fermentation tanks has three cooling zones, with cooling solution flow controlled by one valve per zone, for a total of three valves per fermentation tank. The brite and cold liquor tanks each have two cooling zones and valves.

The temperature of each fermentation tank is controlled by a PID control algorithm running in the PLC. For each tank, a PID loop uses the tank RTD sensor as the process variable input, and controls three ball valves via the PID controller output. These valves control the flow of a glycol/water solution at each tank jacket. A ramp/soak pattern can be programmed to last for days or weeks based on the beer being fermented.

Temperature control for the brite and cold liquor tanks is similar, except there are only two cooling zones and valves per tank.

HMI and Remote Access

The HMI has a custom-designed user interface which mimics the flow of product through the brewery (Figure 3). The controller and HMI are networked together through an Ethernet switch, as is a wireless access point. This access point provides network connections for both local and remote access to the C-more touchscreen via iPad, iPhone and Android apps running on smartphone or table mobile devices.

This system adds tremendous functionality and makes interaction with the automation system more user-friendly and easier to setup than with multiple temperature controllers. The automation system provides data logging locally at the PLC, and remotely through the Ethernet switch.

A free app allows mobile devices to remotely access the HMI. Once remote access is enabled at the HMI and the app is installed on the mobile device, duplicate screens from the HMI can be viewed and controlled remotely from the mobile device.

All of the process data is emailed to a selected group of users at periodic intervals or upon an alarm condition. Email addresses and recipients can be added or deleted at the HMI. High and low temperatures alarms, deviation alarms, and other conditions can each trigger an email. Text messages can also be sent to smartphones with the HMI.

Installation and Results

All wiring to and from the electrical cabinet including power wires, RTD temperature sensors and cooling valve control wires were installed by a licensed electrician. The system startup was executed by me and Greg Lieberman. The initial startup involved training the PID algorithms for the three different sized fermentation tanks.

Each fermentation tank has three valves controlling the flow of glycol to the cooling bands. Training the PID loop for each tank required opening and closing the valves to see how quickly the temperature of the water in the tank changed.

Beer took a bit of retraining due to the exothermic reaction of fermentation, which is of course not present with water. Overall it took 6 to 12 hours per tank to train the PID cooling loop, mainly because 1000 gallons of beer are slow to heat or cool.

The system performs as expected and the client was able to sleep better knowing that each batch of beer has a watchdog to notify him and other operations personnel of any mishaps. There is always room for additional automation throughout the brewery. There are additional designs for motor controllers and valve routing systems ready to be built, just waiting for the right time.

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Editor's Pick: Featured Product News


Extremely space-saving and flexible

The C60xx series of scalable ultra-compact Industrial PCs combines maximum computing power in what is currently the most compact format with a wide range of options for installation in the control cabinet. It is ideally suited for control, visualization and communication, for example into the cloud.

The latest Intel processors − in three different performance classes, from the Intel Atom with one core to the Intel Core i7 with eight cores – offer maximum scalability and power density with an optimal price-performance ratio.

Performance classes and application areas

The C601x series offers Intel Atom computing power for a wide range of automation and visualization tasks. Due to their impressive computing power in relation to their size, the PCs are mainly suited for use in Industrie 4.0 applications, for example as an IoT gateway.

The C603x series unites high-performance Intel Core-i processors with extremely compact housing dimensions. The processors from the 65 W class have only been used in the much larger ATX-based Industrial PCs up to now. The devices thus represent a new dimension in terms of power density. They are suitable above all for particularly complex automation and visualization tasks, but also for a wide range of other applications in the field of image processing, the handling of large volumes of data and in the IoT environment.

The C602x series is the link between the C601x and the C603x, and the fanless integration of Intel Core-i-U processors of the 15 W class opens up new application areas and options.

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TE Connectivity has recently upgraded its rugged, high-speed Mezalok mezzanine connector family to support the growing demand for higher data rates and improved processing power in military electronics. The upgraded connectors have increased data rate support up to 32+ Gb/s. The Mezalok connector family has been designed specifically for mezzanine cards in rugged applications and is standardized as the interconnect for XMC 2.0 (VITA 61). Rapidly evolving technologies in signal intelligence, radar, communications and surveillance are driving the need for more powerful embedded computing solutions. 

Mezzanine cards are often used to provide additional functionality and processing capability within a small form factor. TE designed the Mezalok connector family to support these applications. Typical applications include application-specific high-speed input/output (I/O) protocols, graphics, memory and digital-signal processing.

“New designs in rugged embedded computing require higher speeds and high pin counts in order to pack more functionality into smaller plug-in modules,” said Jason Dorwart, product manager for TE’s Aerospace, Defense and Marine division. “TE recognizes this trend and is continuing to build on this platform to help solve customer needs, offering new options in stack height, pin density and higher speeds, giving the system designer a broader solution set to work with when needing a fast, rugged and reliable mezzanine connector for extreme environments.” 

TE’s highly reliable Mezalok mezzanine connectors more than double the speed and durability of competing technology, making it one of the most viable options for today’s military and commercial aerospace applications.

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For their next meeting with an OEM or system integrator, can panel builders simply grab their smartphone and project the digital prototype of a control cabinet onto the desk of the managing director? Or right into the customer’s production facility? This admittedly sounds fantastical – but is already a reality. The new augmented reality (AR) add-on for the EPLAN eVIEW Free cloud software, in combination with the free Vuforia app from PTC, enables the free projection of completely assembled control cabinet into virtual space.

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