HVAC School - For Techs, By Techs

In our first ever ask-me-anything (AMA) podcast, we talk about the trade as a whole and answer random questions about Kalos and myself. Some people ask me if I'd encourage my children to get into HVAC/R. In my opinion, the trade offers plenty of good opportunities and room for growth. So, I will definitely encourage my children to get into the trades, but I will not pressure them into it. I think more of us should encourage our children to consider a career in the trades and understand the benefits of those careers. I'd even say that I'd choose this career path again if I were allowed to restart my life and take a new career path. I'm optimistic about the future of the trade. The pay and opportunities are better than they've ever been before, and we have chances to attract young people to the trade. This trade is one of impact, and impact is becoming increasingly important to young people. One of the main issues we need to address in our trade is unprofessionalism. From bad practices to blatant prejudice, we need to be professional, proud of the work we do, and fair to everyone. We also discuss: Which piece of equipment I identify with Sleep schedules for people who work on many things at once Providing tools and tool stipends HVAC company finances and profit Tech traits across trades The separation between commercial and residential HVAC Unprofessionalism in the trade Taking time to read and do research Time management and discipline Mechanical diagnosticians vs. sales techs What inspired me to get into HVAC Innovation, marketing, and corporate culture among manufacturers Onboarding and training green techs Thanks to everyone who asked questions in this AMA. Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

When we replace equipment, we sometimes wonder if the old unit was undersized. Here are some things to consider before replacing that old A/C with a bigger one. When we do load calculations, we figure out how much heat to remove or add to a home based on the building's design. We need to account for how much heat is entering or leaving a building and heat gains on the inside of a space. Heat gains can come from human body heat or electronics running, and heat losses are quite rare. Those factors are perhaps even more important for correct sizing than mere square footage. In general, I don't recommend putting a bigger unit in. Focus on getting the equipment to work properly before considering an upsize, as the improper cooling could be caused by a mechanical issue and not an undersized unit. If you want to dig deeper and consider upsizing a unit, you have to consider a few things. First of all, you want to look at the sensible and latent loads. Is the unit too small on the sensible or latent side? In either case, you can adjust the blower to try to address these first. If humidity is the issue, you do NOT want to oversize the unit. Is leakage a factor? Check the integrity of the duct system and if you have cracks, can lights, or other sources of leakage. How's our ventilation? Attic ventilation is also a huge factor that will determine how well an A/C unit works. We also discuss: Shade and impact on radiant gains Ductwork, wire, and copper pipe sizing Heat load reduction (lighting, ventilation, etc.) Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

What is the difference between r-value and u-factor? Why should we care about the differences? In this short podcast, we'll explain what those differences between the two are and why you should care. R-value and u-factor are actually pretty close to the same thing; they are inverse coefficients of the same phenomenon. R-value is the resistance to heat energy moving through conductance. R-value is not concerned with radiant gains, such as the sun's UV rays passing through a window; the heat gains occur strictly through conduction, molecule-to-molecule, like heat passing from the wall insulation to the actual wall upon contact. In terms of insulation, a higher r-value is desirable, Inversely, we like to see a lower u-factor. The u-value is the coefficient of heat transfer. So, the r-value's resistance to heat acts directly against the heat transfer of the u-factor. You can convert the u-factor to r-value by dividing the u-factor into 1 (1/u-factor). Similarly, you can get your u-factor from your r-value by dividing the r-value into 1 (1/r-value). We use these values in load calculations and plug them into Manual J programs. We figure out our BTUs per hour in an equation where we multiply the square feet by the u-factor and the delta t. So, our insulation plays into equipment sizing. Some products also have a rated u-factor. You also need to average out the u-factors if you use multiple materials. (Note: sometimes, manufacturer u-factor ratings are not entirely accurate.) Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

This episode is very exciting to me because we get to have Dr. Allison Bailes on the show. Today, he shares his knowledge about friction rate and duct design. Allison got his start teaching college-level physics before getting into the building design industry. If you have a forced-air system that blows heated or cooled air through a duct system, that blower creates a pressure difference. Some of the pressure is used up on the filter, registers, and dampers, so you will see pressure drops. Anything left over is the available static pressure, which pushes air through the ducts. When you do a duct design, you must account for pressure drops and your blower's static pressure rating. When designing a duct system, you want to minimize friction as much as possible. Counterintuitively, you want a high friction rate. Friction rate refers to the availability of static pressure compared to friction provided by the effective length, not the total amount of friction. Fittings significantly impact your total effective length. By extension, fittings can have a major impact on friction. In flex duct designs, the turns add additional resistance. Oversizing often happens due to poor load calculation. While you increase capacity with an oversized system, there are plenty of drawbacks. The capacity will rarely match the load, you may spend too much on the equipment, have ineffective dehumidification, and you will deal with short cycles, which lead to comfort problems. Allison and Bryan also discuss: Home energy ratings Equivalent length and total effective length Flex duct design Seasonal runtime Surface area challenges Unconditioned spaces Filtration To find out more about everything Dr. Bailes has to say about building performance and duct design, visit his site at: https://www.energyvanguard.com/blog Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Rusty Walker with Hill-Phoenix comes on and talks about CO2 triple and critical points. He also covers some best practices for refrigeration techs working with CO2. The triple point is the temperature and pressure at which a substance can exist in all three phases of matter. CO2 has a very high triple point, and CO2 refrigeration equipment can reach its triple point during operation, unlike most other refrigerants. Solid CO2 is dry ice, and it sublimates by becoming a gas and bypassing the liquid CO2 phase under low-pressure conditions. Therefore, the relatively high pressure applied in a CO2 refrigeration system keeps the refrigerant in a liquid state. We want to avoid reaching the triple point because solids can cause restrictions. The critical point is the point at which a substance becomes a supercritical fluid and loses its pressure-temperature relationship due to densities equalizing. CO2 has a low critical point, only 87 degrees Fahrenheit. So, CO2 refrigeration systems will have supercritical or transcritical CO2 in their systems. You cannot calculate superheat under these circumstances, and you cannot condense supercritical fluid. So, you need to send the supercritical fluid through a gas cooler to reduce the temperature before it can change state. Critical and triple points are important to keep in mind when working on a CO2 system. You want to control pressure to steer clear of the triple point and understand the necessity of gas cooling when dealing with supercritical fluid. Remember: all of the basic laws of thermodynamics still apply. Rusty and Bryan also discuss: CO2 leak detection Bars and pressure conversions Supercritical fluid as a solvent Avoiding triple point on a service call Recommended equipment and practices for working on CO2 systems Vacuum Booster system piping and brazing Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this short podcast episode, we cover what you need to consider before you solder or braze any type of joint in HVAC/R work. We want to give special thanks to Solderweld; you can learn more about their products at solderweld.us. When you braze or solder anything, you need to know your base metal. The base metal's temperature and composition will determine which type of flux you will use. For example, if you are working with steel, you can't use fluxing agents with phosphorus. Instead, you will need to use high silver rods and a separate flux. Copper rods with phosphorus don't require a separate flux. The main difference between brazing and soldering is the temperature. When you work with temperatures above 840 degrees Fahrenheit, you're brazing. Anything below 840 degrees counts as soldering. In both cases, you use an alloy that differs from the base metals. Copper is highly conductive and is one of the most common metals we use for brazing and soldering. So, it is pretty easy to draw the alloy into a copper-to-copper joint because the copper heats easily and evenly. Steel is nowhere near as conductive as copper, so it can be challenging to work with because the heat localizes. So, on copper-to-steel joints, you need to understand the different behaviors of the metals. It's also a good idea to know the melting point of your base metals to prevent overheating. As we heat base metals, they change color. When those metals get to a cherry red, that's a great range for brazing; don't let the temperature rise or fall much below that. We also discuss: Soft solder Metal expansion and contraction Copper-to-aluminum brazing challenges and practices Flux usage and best practices Alloy-Sol and bonding Preventing leaks Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

Eric Mele is back on the podcast. This time, we cover hot gas as a reheat dehumidification strategy with all of the broad strokes you should be aware of. One common dehumidification strategy is the hot gas bypass; this strategy allows you to operate under low load. Hot gas reheat is when you add discharge heat back to the conditioned space. When you use reheat for dehumidification, you cool for the purpose of dehumidification and then add sensible heat to remove moisture on the coil. So, you don't overcool the space to an uncomfortable level. Hot gas reheat uses waste heat from the equipment to remove moisture. Using waste heat is not a very efficient process, but it is better than using electricity or fuel to provide a heat source. Common systems that use this reheat system are 100% outside air units and humidity-control applications. Systems that use hot gas reheat can divert refrigerant to a reheat coil or use a dedicated reheat circuit. No matter which strategy the equipment uses, the reheat always happens AFTER the evaporator coil. Common issues with these reheat systems deal with the modulating valves. These valves can get stuck or end up in a different position than their controls say. You must confirm that the valves are in position. When working with these valves, you may work with DC controls, so that's something to keep in mind if you primarily work with AC circuits/controls. DC-signal sensors can also malfunction, so you have to check your outputs and can usually find a sensor-related problem quite easily. We also discuss: Overcooling to dehumidify Fresh air requirements and equipment Solenoids Expansion line Technician vs. manufacturer training Confirming valve position Stepper motors Tools for circuits Checking the refrigerant charge Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this short podcast episode, Bryan covers three things you can do to level up and make you a much better tech tomorrow. Everyone will notice your improvement. Also, no matter what level you're on, you can become even better by remembering the following three tips: 1. Use a full-system diagnostic process. Every application should have a full-system diagnostic process, whether you're working on a residential ductless mini-split, a commercial chiller, or a walk-in refrigerator. Instead of focusing just on the primary problem, you'll be much more effective if you assess the entire system. You can also adopt a wide-narrow-wide approach to diagnosis where you start by examining the entire system (for example, look for oil and check the filter). Then, you focus on the main problem at hand and fix it. Before you leave a job, test the equipment and check it over once again to make sure that everything is working as it should. 2. Communicate better. In the commercial sphere, it's a good idea to write up equipment reports that customers can use to help them make informed choices about their equipment. For residential customers, communication is about courtesy. Send a text to let them know you're en route or send a follow-up email. When it comes to dispatch and leadership within your organization, communicate useful and helpful information for them. Report common things that you see in the field so that they can improve at their jobs. 3. Have a closing conversation with every customer. Before you leave a site, check in with your customer to make sure that there's nothing you or your company can do better. When you have these conversations, you show that you care and give the customers an opportunity to provide feedback. Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

In this episode, Jim Bergmann does a deep dive into combustion analysis. He covers everything you need to know to keep a furnace running safely and efficiently. When you go into a home, one of the first things you should do is perform an ambient CO test to check how much carbon monoxide is in the home. Combustion analyzers can typically measure CO, or you could use a dedicated CO meter. When it comes to checking for spillage, you'll want to make sure you check anything that is connected to an atmospheric draft appliance; these appliances, including water heaters, can create a pathway for CO. First, you want to make sure everything is working properly before the combustion analysis. Set the fuel pressure according to the manufacturer's specs. Then, you go outside and clock the meter. When you do that, you merely verify that you have the correct gas input to the appliance; figure out how long it takes the one-foot dial to do a single revolution. After you verify the fuel and air, you want to see if you have an adequate amount of draft. Then, you set your temperature rise and verify that your CAZ zone is within the allowable limits. When we do a combustion analysis, we measure the efficiency of the combustion process, not the overall furnace efficiency (AFUE). Combustion analyzers also help us account for stack losses. When doing the test, you must measure undiluted flue gas and take readings on fuel pressure, excess air, and stack temperature. Jim and Bryan also discuss: Fuel pressure and fuel orifice sizing Fuel heat content Excess air and condensing Carbon monoxide thresholds Stand-by losses Contaminants Temperature rise ranges Net vs. gross stack temperature Combustion efficiency Duct leakage Positive vs. negative pressure exhaust Cracked heat exchangers What to do when CO levels are high AccuTools Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.

This short podcast episode is about a simplified way to explain the basic refrigerant circuit to new techs. By explaining a component as an absorber, rejector, increaser, or dropper, you may help lock in the basic idea of absorbing and rejecting heat. The goal of refrigeration is to remove heat from a place. Whether that place is a grocery case or a house, we're moving heat. The overall function is pretty straightforward, but the components can get a little bit complicated. At Kalos, we've found that HVAC/R apprentices tend to grasp the refrigerant circuit better when they can refer to the components by their functions. We move heat with a combination of heat absorption and rejection and pressure rises and drops. For example, the compressor is the "pressure increaser," and the metering device is the "pressure dropper." Likewise, the evaporator is the "heat absorber," and the condenser is the "heat rejector." When we understand that higher energy goes to lower energy, we can understand that the cold refrigerant inside the evaporator acts as a heat absorber. The evaporator coil is lower than the indoor temperature; it can do its job as a heat absorber even in relatively cool spaces. In air conditioning, we try to maximize efficiency by creating the proper temperature inside the evaporator (heat absorber). In many places, that temperature is about 35 degrees (F) below the indoor dry-bulb temperature. Explaining the component in this way encourages technicians to check the space of the temperature and relate it to the evaporator temperature. The condenser is a heat rejector; it performs the opposite function of the evaporator. So, the outdoor temperature must be lower than the condenser (heat rejector) temperature. Then and only then can the condenser reject its heat to a cooler location. Learn more about Refrigeration Technologies HERE. If you have an iPhone, subscribe to the podcast HERE, and if you have an Android phone, subscribe HERE.