Friday, August 17, 2018

Bristol Compressors Closing

It is sad whenever a company in HVACR cannot make a go of it. Bristol Compressors has announced that they are closing after more than 40 years in business. They developed some innovative products, such as the Inertia Compressors with suction valves built into pistons that separated allowing suction gas to travel through the piston head, or the Twin-Single compressors that had a unique crankshaft which moved both pistons up and down in one direction and only one piston in the other direction.  More details on the closing here 

Wednesday, August 1, 2018

Chemours (Dupont) Buys ICOR International

I just got an email info blast from ICOR in which it states that ICOR is now a wholly owned subsidiary of Chemours. Tht surpised me, so I looked a littel further into it and found an article on :Cooling Post" dated April 8, 2018 which confrms that Chemours bought ICOR. Here is the link to the Cooling Post artcle
Here is the link to the info blast that ICOR sent me.

Basically it is warning against cheap refrigerant from unknown sources. As always, if you stick with legitimate supply houses you are pretty safe. If you get it off the back of someone's truck at midnight in the parking lot behind the bar, well you might not be getting what you think you are getting. Even ordering over the internet is risky if you are are buying it from someone outside of the normal distribution chain. There is now counterfeit refrigerant out there, so just because the jog says Honeywell or Chemours does not mean that it really is from that manufacturer. Some of the counterfeit stuff has hydrocarbons in it and could be quite dangerous in a system that is not designed for explosive refrigerant.

Thursday, July 26, 2018

New Low GWP Non-Flammable R410A Replacement

This will be a short post because I don't know a lot of details yet. Honeywell is developing a new three part zeotropic refrigerant that can replace R410A. It has a relatively low GWP of 733 compared to 2088 for 410A, and most significantly, is non-flammable. Honeywell's trade name for it is Solstice N41, the ASHRAE number is R466A. It reportedly contains the same two chemicals as in R410A (R32 and R125). A third is added - trifluoroiodomethane (CF3I). This third component is currently used a a fire retardant. It also helps reduce the GWP of the mixture. The new refrigerant is not claimed to be a "drop-in" for R410A, but required design modifications are said to be minimal. The refrigerant is currently undergoing ASHRAE testing, but has received a preliminary A1 rating.  I have now told you all I know, and it did not take very long. Here are links to two articles about this new refrigerant.

Thursday, July 12, 2018

Air Conditioning Energy Ratings

BTUh, kWh, EER, CEER, SEER, SACC – when it comes to understanding air conditioner capacity and efficiency there are certainly plenty of arcane acronyms to sort through. The systems set up to allow objective comparison of air conditioners are hindering that very goal because of the many different measurement systems and terminology. Before discussing the different terms I would like to quickly explain what an air conditioner does: it pumps out heat. Much like a sump pump pumps out water from a basement or crawl pace, an air conditioner pumps heat out of your house. You need a sump pump that can pump water out as fast as it leaks in, or your basement will flood. With air conditioning, you need one that can pump heat out of your house faster than it leaks in, or your house will still get hot. The key point is that the air conditioner moves heat. In the United States we measure heat in British Thermal Units, or BTUs. The rate at which in air conditioner is able to pump out heat is given in BTUs per hour, or BTUh. This tells us how many BTUs of heat the unit can remove operating for an hour. The air conditioner’s electrical use is measured in kilowatts hours, or kWh.

EER Energy Efficiency Ratio
The EER is the easiest measure to understand. It is the cooling capacity in BTUh divided by the energy use in kWh. It tells you how many BTU of heat removal (cooling) you get for each kWh of energy. However, there are some things not taken into consideration. First is that it is a steady state test, meaning the unit is up and operating at full efficiency before any measurements are taken. No consideration is given for the energy used at startup, shut down, and while plugged in but not running. Also, all measurements are done at design condition, which is 80°F, 50% rh inside and 95°F outside.
SEER Seasonal Energy Efficiency Ratio
The Department of Energy devised this measurement for rating central air conditioning units in 1978 to address some of the issues not addressed by EER. Namely, cycling losses and operation at more than one temperature. The idea is that SEER is supposed to show the BTUh/kWh over a season, not just at one steady state condition. To simulate seasonal operation, SEER testing includes cycling and operation at  three different test conditions: 80°db/67°wb inside and 95° outside, 80° db/67°wb inside and 82° outside, and 80°db 57°wb inside and 67° outside. A unit’s SEER is generally higher than its EER because the SEER includes operation at milder conditions. Currently, the minimum SEER in the northern half of the US is 13 while the minimum SEER in the southern half of the US is 14.

CEER Combined Energy Efficiency Ratio
The DOE devised CEER in 2014 specifically for window air conditioning units. CEER is similar to SEER in that it measures efficiency at two operating conditions: 95° and 83°. It also includes the energy used while the unit is plugged in but not operating. A unit’s EER and CEER normally end up being very close to each other with the CEER being slightly lower.

SACC Seasonally Adjusted Cooling Capacity
The SACC was devised in 2017 to measure the efficiency of portable air conditioners. By portable, they mean the ones on wheels where the whole unit sits in the room and an exhaust duct is placed in the window to carry hot condenser air out. It is similar to the CEER in that it measures capacity at both  95° and 83°. It also includes adjustments for heat gains (cooling losses) from the exhaust duct plus loses due to infiltration caused by having to stick the exhaust duct out the window.

How do you convert between these different methods? You don’t because they each have different testing specifications. There are some formulas offered, but they can’t determine the differences in how different units will respond at the varying testing conditions.  The best you can do is understand each rating and use them to compare units with similar ratings. Just as the EPA mileage estimates don’t really tell you what your mileage will be with that new car you just bought, these ratings will not really tell you the energy use for your new air conditioner for a year. So which rating system do I believe is the most reliable? Honestly, the simplest and oldest one: EER.

Friday, February 2, 2018

Understanding Loads in Series

We don’t often see loads wired in series with each other in HVACR, but you do occasionally run across a circuit which has two loads wired in series. Loads in series spit the voltage based on their individual resistance compared to the overall resistance. So if each load is about the same resistance, they will split the voltage in half. However, if one load has a much higher resistance than the other, the loads with the higher resistance will get the most voltage.

This diagram is a partial diagram of a residential refrigerator-freezer. It shows the defrost control, freezer fan, and defrost heat circuits. During normal operation the freezer fan is in series with the defrost heater, as shown in diagram 1. The heater has a resistance of around 28 ohms while the fan has a resistance of around 280 ohms. But since the fan is an inductive load, its total impedance (effective AC resistance) is much higher – more like 2800 ohms. The current for the circuit is very small 120 volts / 2828 = 0.04 amps. Voltage across each device is calculated by multiplying the current times the resistance. The heater voltage drop is 28 x .04 = 1 volt. The remaining 119 volts are all used by the fan. Essentially, the defrost heater is acting like a wire.

When the defrost control switch moves to the defrost position, the fan shuts off and the defrost heater energizes. The fan shuts off because now the same leg of power is applied to both sides of the fan. With no voltage difference from one side to the other, no current flows through the fan. The heater now has its own source of power ad receives a full 120 volts. The heater will stay energized until the defrost termination thermostat opens, breaking the circuit.

When the defrost control takes the freezer out of defrost (diagram 1) the fan will remain off until the coil is cold enough to close the defrost termination thermostat.

Monday, January 8, 2018

Unlocking the Secret Refrigerant Numbering Code

I have wondered why the new HFO refrigerant numbers look like an internet password. In short, the numbering system describes the chemical makeup of the refrigerant. But that is also true of the much simpler numbers, such as HCFC 22. So why does HFO 1233zd(E) look like a secret code? Mainly because the chemical is a bit more complicated. HFC 22 is a methane based molecule, with only one carbon. All that is needed to describe it is a way to determine how many fluorine, chlorine, and hydrogen atoms surround the single carbon atom. There is really only one way to put the molecule together.

HFO refrigerants are decidedly more complicated. They are built around a propene molecule. Propene has three carbon atoms surrounded by hydrogen atoms. Propene is similar to propane, except propane has all single bonds between its atoms while propene has a double bond between two of the carbons atoms.

You can think of each carbon atom as having four Velcro hooks. Molecules like propane only use 1 hook for each bond. This allows each carbon to bond to the most possible other atoms. Molecules constructed this way are referred to as saturated.  Two of the carbon atoms in a propene molecule use two Velcro straps to bond to each other, which reduces the number of other atoms the carbon molecules can bond with. Molecules built this way are referred to as unsaturated.

To unlock the secret code which describes fluorinated hydrocarbon refrigerants, just add 90 to the number, leaving off the leetrs for now. For example, 1233 + 90 = 1323. Working backwards from the right, the first number describes the number of fluorine atoms. In this case it is 3. The second number from the right describes the number of hydrogen atoms. In this case 2. The third number from the right describes the number of carbon atoms. In this case 3. The fourth number from the right lists the number of double bonds in the molecule. In this case 1. Notice the number of chlorine atoms was not addressed. The number of chlorine atoms is found by subtracting the fluorine and hydrogen atoms from the number of bonds. A propene molecule has 6 bonds. 6- 3 -2 = 1. There is one chlorine atom.

So what are the letters at the end of 1233zd(E)? The short answer is that all the letters following the number describe the particular molecular arrangement. We know that 1233zd(E) contains 3 carbons, 3 fluorines, 1 chlorine, and 2 hydrogens. However, even if you know exactly which atoms there are, you must also describe where they are attached because there are now many places to put them.

Each different arrangement of the same atoms produces different properties, so it is important to specify which arrangement the refrigerant is using. These different arrangements are called isomers. The two lower case letters after the number describe the specific arrangement (isomer). But note that this refrigerant number has yet another upper case letter after the two lower case letters. Some isomers have the same arrangement, but differ in spatial orientation. The upper case letter identifies which spatial orientation.

This is about as deep as I feel I should go in a blog post (maybe even a bit too deep). If you want more detail, it is all explained in the ASHRAE Standard 34-2016.

Thursday, December 28, 2017

Glove Cut Resistance Ratings

Did you know that gloves have ratings? When looking for a glove to protect your hands from cuts and scrapes you should get a pair that matches the required duty. There are actually two different glove ratings for cut resistance: ANSI/ISEA 105 and EN 388. In the United States we use ANSI/ISEA 105 which had a significant update in 2016.  There are nine levels, A1 – A9, with A9 being the most cut resistant. The gloves are tested by placing a fixed amount of pressure on a blade while moving it across the glove for a distance of 20 millimeters (roughly ¾ of an inch). The tool used is called a tomodynamometer which moves a razor blade slowly across the material being tested at a specified pressure for a specific length. The glove cut resistance levels are established based on the amount of pressure required to cut through the material. The Table below shows the nine levels in the ANSI system. You can see that the minimum recommended cut level for HVAC work is A4.

ANSI/ISEA 105 2016 Glove Cut Rating
Pressure Required to Cut Through
Recommended Use
200-499 grams
General Purpose Material Handling
500-999 grams
Packaging, paper handling
1000 – 1499 grams
Handling construction materials
1500 – 2199 grams
HVAC, duct work
2200 – 2999 grams
HVAC, metal fabrication, metal stamping
3000 – 3999 grams
HVAC, metal fabrication, metal stamping
4000-4999 grams
HVAC, metal fabrication, glass manufacturing
5000 – 5999 grams
HVAC, metal fabrication, glass manufacturing
6000 or more grams
HVAC, metal fabrication, metal recycling

There is no requirement for glove manufacturers in the United States to test and label their gloves, so many gloves are sold without the cut rating. However, better manufacturers test and label their gloves. Look for gloves that have an ANSI/ISEA rating of at least A4 to protect your hands. To learn more, check out this page from Superior Glove Company.

Glove Rating Systems Explained