HVAC School - For Techs, By Techs

Dick Wirz, author of Commercial Refrigeration for Air Conditioning Technicians, talks to us about refrigerator and freezer defrost strategies. Check out Dick's book HERE. In commercial refrigeration, we deal with much lower evaporator temperatures than residential HVAC. Although an evaporator temperature of 40°F may be commonplace in residential HVAC, you can expect evaporator temperatures from 25-30°F in refrigeration. Even though having ice on the coil is a negative thing in residential HVAC, it is perfectly normal in refrigeration. The purpose of defrosting is to bring the evaporator temperature above freezing to melt off the frost. We can defrost a coil in a few different ways, including a mere off-cycle defrost in medium-temperature refrigeration. When the system shuts off, the evaporator coil can start defrosting. However, if too much heat is introduced to the system, more frost can accumulate on the evaporator coil. As such, a planned defrost may be in order. These defrosts occur on a timer and turn the system off overnight. Alternatively, these defrosts may use electricity or hot gas to remove ice from the coil more rapidly, especially in low-temperature applications. Electric and hot gas defrost are common defrost types. The hot gas method generally reverses refrigerant as a heat pump does; hot discharge gas runs through the evaporator coil and melts the ice off the coil. However, hot gas is an expensive method and can negatively impact system longevity if used improperly. The electric method is cheaper than the hot gas method; this method relies on electric heat outside the coil to melt the frost from the outside. Dick also talks about: Warm air infiltration Coil-sensing thermostat controls Defrost failsafe Defrost termination "Snowing" in the box and fan delays Drain pan heaters and drain complications Paragon timers Demand defrost setups/clocks   Check out RefTech HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this episode, Bill and Bryan recap the 2018 AHR conference with what they learned and what you can expect to see in the HVAC/R trade in the next year. There were 2100 exhibitors who gave demonstrations and discussed products. AHR shows the real scope of the HVAC/R industry, and it is an excellent opportunity to learn more about the trade and do some networking. At the AHR conference, there were some demonstrations that may indicate a paradigm shift in the industry's best practices. For example, the AccuTools booth projected the rate of evacuation through three hoses of different diameters, including the mythical 1" hose. The visual representation of those evacuation rates showed the trend towards faster evacuations with larger hoses. More tool manufacturers may jump on the trend to make larger hoses that assist technicians and lead to better evacuations. The technology on display at AHR also testified to the fact that many more tools are integrating with our cell phones, including the CPS IAQ monitor. AHR also had a treasure trove of new technologies, including BluVac's Bluetooth-connected combustion analyzer. BluVac's branding is very science and engineering-focused, and they also fine-tune their technology to support techs in the field. Overall, AHR was a fantastic forum for people to spread information about products. In turn, Bill and Bryan had some of their product research validated and built upon. Bill and Bryan also discuss: Attaching micron gauges at the pump Professional branding Industry education Surge suppressors and melting issues The time Bill called Bryan out Engagement with HVAC educational materials Testo precision manometers and additional heads Filling the HVAC/R skills gap Increasing your value as an individual technician in this industry Building performance in the HVAC industry Internet of things (IoT) The commercial HVAC market   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In today's podcast episode, Bryan talks to west-coast commercial tech Jim Loring about pneumatic controls and variable air volume (VAV) systems. People sometimes confuse pneumatics and hydraulics. Hydraulics use liquid to provide pressure; conversely, pneumatics use air to provide pressure. Pneumatic controls use a bit more energy than other controls, but they are less costly all around. Nowadays, direct digital controls (DDCs) provide greater energy savings than pneumatics. However, pneumatic controls were a precursor to the DDC technologies we use on actuators today, and they are still a prevalent technology. The air compressor is a critical component of pneumatic controls. That is because pneumatic controls require clean, dry air. Air compressors have an auto-drain and auto-dryer to help purify the air for peak performance. However, while air compressors are basic, their maintenance practices are often overlooked. Variable air volume (VAV) units vary airflow throughout the building via zones. Each zone has a damper and a thermostat. The thermostats control the dampers, which control airflow to the zone and move via actuators. In a pneumatic control system, the air pressure release or gain at the thermostat moves the dampers. Thermostats also have to bleed off some of that air via direct or reverse-acting controls. Bypasses help regulate static pressure when dampers close. Thermostats can help modulate the dampers; they don't merely open and close. The modulation occurs within a certain pressure range on a VAV system. (For example, 8 PSI would close the damper while 13 PSI would leave the damper wide open.) In addition to damper modulation, velocity controllers help control the air velocity based on signals from the thermostat. Jim also covers: Common air compressor problems Pressure-reducing valves (PRV) Restrictor tees Direct-acting vs. reverse-acting controls Heating and cooling in VAV systems Damper position   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Jeremy Smith goes over floating suction and floating head refrigeration strategies. He also talks a bit more about low-ambient equipment operation. Floating suction controls developed when we started using low-pressure controls on rack refrigeration. As the electronics advanced, we developed controls that could control temperature, which impacts pressure as well. Nowadays, controls can cross data and be much more effective at controlling pressure and temperature. Suction pressure is the greatest contributor to a system's compression ratio. The higher the compression ratio, the less efficient a system is; a high compression ratio can be costly for grocery business owners or managers. Therefore, floating suction controls set the temperature exactly to what it should be based on the system's load, not lower than what the suction temperature should be. Floating head controls attempt to minimize the compression ratio from the high side of the system. The floating head attempts to maintain head pressure by matching condenser fans closely with ambient temperatures. Ambient temperature controls the floating head control's set points. These floating head controls can set the condensing temperature as low as 68 degrees (F). The main factor that prevents the temperature from getting any lower is the expansion valve. It is possible that EEV usage could enable even lower temperatures, but they have been quite problematic so far. Jeremy recommends taking advantage of natural subcooling to get the most out of your floating head strategy. These controls have to decrease capacity before they hit their targets. As such, these floating head and suction controls can be erratic and "swing" from extremes upon startup. Jeremy also covers: Energy and monetary savings Pressure differentials caused by floating head controls Expansion valves in refrigeration Superheat "floating" "Drain" leg or regulator   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Bryan talks with Jesse and Nathan about setting up dehumidification for residential equipment in general. They also discuss some of the required and recommended settings on an Ecobee thermostat. On typical single-stage residential equipment, dehumidification works based on CFM per ton. We control humidity by dropping the CFM across the indoor coil and extending runtime. However, as you cool the air, you reduce its ability to hold moisture. So, you increase relative humidity through cooling. When we have achieved the desired humidity but not the desired temperature, the thermostat reduces the fan speed. Thermostats should vary the fan speed based on the call for cooling and the humidity in the air. Some systems have a dehumidification terminal; when there is a call on that terminal, the fan speed gets maxed out. Some older thermostats would display relative humidity but did not have a dehumidification terminal; these systems would merely overcool instead of removing the humidity. These systems would be very prone to freezing. Nowadays, freezing still occurs on occasion, but our newer thermostats can control their CFM per ton much better to prevent freezing. Ecobee thermostats work to integrate many different accessories. So, Ecobee thermostats try to solve every problem on a system, even on systems with supplementary humidifiers or dehumidifiers. These thermostats don't have a dehumidification terminal, but they have ACC- and ACC+ terminals for accessories, including dehumidifiers. Many technicians become confused when they think that the fan is a core element of dehumidification. Instead, the ACC terminals should be set as single-transformer, and you can choose the dehumidification option (which should NOT have the fan on). When wiring the Ecobee for dehumidification, connect the DH terminal to ACC+, remove the jumpers, set up the single-power source, do NOT dehumidify with a fan, and set "Dehumidifier Active" to "Open."   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this episode, we cover the skills and traits needed to be the best residential service techs you can be. We follow up on the last episode's tips for getting a raise and discuss how to become more valuable as an employee. All good service techs clearly have to be able to repair and maintain systems well. Commercial and residential techs need to demonstrate mechanical aptitude. However, soft skills are what separate the good residential service techs from the excellent techs. Observational skills are imperative. Residential techs need to take a wide-narrow-wide approach to diagnosis. They must also utilize their senses to observe the ENTIRE piece of equipment. Observant techs are quite good at catching potential issues before they spiral out of control. Resourceful techs make the most of the books, manuals, and other resources they have. If they don't have a resource, they find it. Since residential service techs deal with customers, it pays for them to be pleasant with people. These people are still honest with customers, but they're positive and empathetic. The best techs are organized and keep their tools in order for maximum efficiency. Efficient techs increase their value as employees with every task. They become quicker as they become more confident with tasks. Great techs are also conscientious. They are aware of their surroundings and considerate of the customer's property and feelings. Excellent techs are also self-aware about their knowledge. They understand that they don't know everything, and they know what they have to study or search for. Finally, the best techs are all neat, clean, and communicative. Residential service techs are our industry's ambassadors, and it is important that they communicate well AND project a good image of the industry and company to the customer.   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

As we ring in the new year, this episode focuses on how people in the HVAC/R trade can get a raise, promotion, or bonus without facing rejection or sounding selfish. Before you think about asking for a raise or promotion, evaluate your company. Is your company pragmatic? Does the company refuse to address conflict or let tempers run high? Do your leaders care about making decisions logically and promote people who will truly help the business? A pragmatic company makes logical decisions and respects the employees who keep the business alive. Many people want to ask for a raise when they find out that someone earns more than them or feel as though they haven't had a review in a while. People in these situations feel as though they are OWED additional pay. Here's Bryan's advice: DON'T ask for a raise, promotion, or bonus unless you have a written salary agreement that hasn't come to fruition. When you ask a leader for a raise, you make your leaders put their guard up. In general, it's not a good idea to make someone else put their guard up when communicating with them. If you want to talk to a leader about a plan to earn more money in the future, try to explain your vision of the future for the company; solve a company problem, or contribute to a leader's solution. Avoid self-assessments; talk about a plan or vision where YOU play an integral part in improving the company. Tie YOUR pay to the company's success, whether your solution addresses revenue, callbacks, or training within the organization. Overall, you have to show that you're willing to accomplish a task to earn more pay. A pragmatic business will see the value in your ideas and will be more willing to give you a raise, promotion, or bonus after you execute your plan.   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this podcast episode, we discuss power distribution and some practical tips about three-phase, single-phase, and split-phase power. The power company generates three-phase power; a power pole transformer typically has three current-carrying conductors. Each phase of power runs at 60 Hz and generates a sine wave. That sine wave peaks and valleys in a wavy formation. Power is generated in a rotating magnetic field, so it is helpful to think of a sine wave as a variation of a circle. Transformers take high voltage and bring it down to 120V split-phase via a winding on the left, a winding on the right, and a neutral tap. The split sine waves are exactly 180 degrees out of phase; they are direct opposites, and they will intersect and both be "off" at the same time. The center is neutral. This 120V split-phase power results in 240V total; therefore, we can use them in 240V applications. Split single-phase motors require a capacitor. Three-phase power uses all three legs of power, and the sine waves are 120 degrees out of phase with each other. In three-phase power, only one wave will be "off" at any point in time. Three-phase power is a more efficient means of running motors; split single-phase power is relatively inefficient and requires a capacitor. However, reverse-phasing is a possibility and may run motors backward, causing damage. The most common type of three-phase transformer uses the wye configuration and works for 208V applications. Bryan also discusses: Wye vs. delta configuration Delta configuration high leg Start assistance and capacitors Residential vs. commercial applications Capacitor failure 277V and 480V applications Replacing single-phase with three-phase power or vice versa Three-phase condensers with single-phase air handlers   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Learn about large-scale desiccant dehumidification from the expert, Tom Peterson. Tom works with CDI (Climate By Design International). Dehumidification has several different methods and applications. Cooling is the most basic of those methods, but it has its limitations. For example, dehumidification by cooling may leave moisture on the coil and lead to freezing. Desiccant dehumidification can remove water from the air without the possibility of freezing the unit. Desiccants are crystalline structures with pores, and they remove moisture via adsorption. Water has a pressure that pushes other water molecules into those pores. Partial pressures also help force the pressures from high to low. Moisture will only come out of the desiccant upon heating the air around it. Heat excites the water molecule that has been trapped in the desiccant pore, so that molecule breaks the bond between itself and the desiccant (desorption). Commercial/industrial dehumidifiers make use of desiccants. Desiccants fit into rotors or wheels, and air passes through the desiccant rotor. The goal is to dehumidify and only dehumidify. So, no heat transfer occurs as air passes through those desiccant rotors.  About 3/4 of the rotor works to adsorb moisture, and about 1/4 of the rotor works to desorb moisture. We measure moisture in a unit of weight called grains per pound of dry air (simplified to "grains"). Grains refer to moisture rather than a humidity percentage, but grains and humidity are indeed linked. Even though we attempt to reduce grains per dry air, we cannot have negative grains of moisture; it is an impossibility. Tom also discusses: Sensible vs. latent heat Grain depression Dew point   Learn more about desiccants at the CDI website at cdihvac.com and their YouTube channel HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Carter tells us why compression ratio is important, what it means, why it changes so much on heat pump systems, and the effect it has on system operation. We also talk a bit more about heat pumps and their unique challenges beyond compression ratio. Compression ratio is a comparison of discharge pressure to suction pressure. A ratio of 3:1 indicates that the discharge pressure is three times higher than the suction pressure. The higher the pressure difference, the less gas you move and the less efficient your system is. The compressor has a fixed volume, but the gas's actual mass varies based on density and pressure. So, lower suction pressure results in less gas being moved. Dirty filters, coils, and other means of clogging the system can drastically increase the compression ratio. Heat pumps are especially sensitive to compression ratio changes because they move varying amounts of refrigerant depending on the operating mode. As such, charging heat pumps can be a challenge. Some heat pump manufacturers use a charge compensator to help make charging a slightly less difficult task. Heat pumps may also have coils with smaller surface areas, which can drive up the compression ratio. Heat pumps have highly variable evaporator temperatures, and refrigeration systems have highly variable condensing temperatures. Both of these highly variable conditions may indicate systems with susceptibility to high compression ratios. In the case of refrigeration systems, the metering devices are critical components for reducing keeping the compression ratios at bay. If you cannot find manufacturer literature or are working on an old heat pump, Carter recommends using airflow and temperature difference to determine how much heating the system is accomplishing. Carter and Bryan also discuss: Rheem and Ruud heat pumps Centrifugal blowers Plenum placement New inverter-driven compressors   If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.