I've had HVAC techs tell me not to use those thick filters unless your system is designed for it. They make the fan work harder to pull less air. This reduces how much air it can move.
A good system like an AprilAire [1] will have a 4" thick filter vs the standard 1" thick filters. This allows much more filter area than a standard filter allowing proper airflow even with a finer more restrictive filter medium.
You can't just swap filters, the 4" thick one usually go in right before HVAC air handler intake rather than at returns. I have had an AprilAire installed for over 10 years in my HVAC when it was replaced last time, recommended by HVAC installer, its has worked very well and I do have my blower fan cycle constantly regardless of need for heat/cool to turn over and filter air.
You can have them do a test and adjust the system depending on the filter that's installed to make sure it's moving enough air (though that is mainly important when heating to prevent the heating element from overheating).
It is also important in the cooling cycle for two reasons.
1. If there is not enough air moving over the air-conditioner coils there is the possibility that they will ice over. This has a cascading effect where there is less transfer through the coils and more ice builds up until the whole thing is a block of ice. This most often happens though when people buy condensers that are too big for their system (the thinking being the bigger the better the more cooling, but it is a balance within some tolerance) but can also be done on the other side by reducing airflow too much.
2. Less airflow can also mean too much condensation in the air which can end up sitting in the ductwork and causing it to rust out. This happened to my parents when they installed extra filters in their HVAC system. I guess this is similar cause as #1, just different potential effects.
I have been told a different take. The amount of airflow over the coils is important as the compressor system also expects a certain thermal exchange (think air conditioning) and thus a certain pressure on the return.
Less air over the coils can inhibit the cooling properties, this was conveyed to me as high "head" compression pressure that can lead to premature compressor failure in the outdoor AC part, the expensive part. This is more important as the higher the SEER level, generally newer the system, the more sensitive they are to this issue. HVAC tech sold me with high head pressure expect failure of compressor in a few years.
Also you are running as efficient since the AC has to work longer burning electricity.
I've always heard this, but I don't know that that's true. The thing that dies first on an HVAC system isn't the motor, it lasts a long damn time, it's the capacitor, or contactor or some other fault not really related to the motor work load.
Plus, your "motor" isn't an engine, it's not variable speed, it only has one "hardness" that it works at. It might push less air with the thicker filter, but it's not going to ramp up and consume more wattage or anything like that.
It's usually a misunderstanding of how furnaces "work" - the blower motor does its thing and doesn't really "spin up or spin down" depending on the load - it just moves more or less air.
The problem is (especially with older furnaces; modern ones have safety features to prevent this) that if you have too much back-pressure you don't get enough airflow over the heat exchanger (or air conditioner coils) and it can crack - allowing dangerous exhaust gasses into the airflow (or freezing the coils for the AC which isn't as bad).
Once the heat exchanger is gone the furnace is basically trash and has to be replaced (you can replace the heat exchanger but it's rarely worth it).
> The problem is (especially with older furnaces; modern ones have safety features to prevent this) that if you have too much back-pressure
An everyday way in which people induce this scenario is by shutting the heating vents in particular rooms because they get too hot. Even on the newer furnaces, this results in the automatic controls shutting off the burner when the pressure and temperature gets too high, and then the fan starts pushing around cold air.
A secondary negative effect of this is that it pressurizes the ducts causes them to leak more, resulting in reduced efficiency, and also quicker failure.
A well designed system which has been configured to deliver the correct amount of heat to each room doesn't experience the same issues. Unfortunately, most older homes and even newer production built homes have poorly designed HVAC systems.
Heat pumps don't experience as many of these issues because they just don't get air as hot, and instead rely on higher throughput of lower temperature air to heat spaces, but that makes them far more reliant on good duct system design.
>Plus, your "motor" isn't an engine, it's not variable speed, it only has one "hardness" that it works at.
This is incorrect - electric motors draw more current when under load. I would suggest researching this or playing with some toy electric motors run from a battery through a current meter.
> This is incorrect - electric motors draw more current when under load.
Which is a true statement but incomplete and therefore misleading. A fan motor is under the highest load when it is doing the most work. That is, moving the MOST air. If you restrict airflow (e.g. with a dirty filter), the motor is under less load and draws LESS current. A lot of people get this wrong because it's counter-intuitive on the surface of it.
You can test this very easily with a box fan and a kill-a-watt. Turn the fan on High in the center of the room and read the power. Now move it against the wall. You will hear the fan get louder because it is spinning faster, because it's doing LESS work. The meter will also show less power being drawn.
It is true that a dirty filter restricts airflow through the whole HVAC system. This extends the system's "on" cycle, which reduces the whole system's efficiency. But the popular claim that a dirty filter will burn out the motor is bunk.
I have a degree in electrical engineering, thank you for telling me to do my research, I spent four years doing that.
Sure, some motors have characteristics that can be tweaked to run at different work loads either with PWM, or allowing them to pull more amps to drive higher loads. Hell, you can even overvolt them and make them actually work harder.
That's not how HVACs work though. Have you ever opened one up and did a repair? The circuitry is dead simple, there's no current limiting setup or PWM to control how much the motor is pulling or spinning, there's no CFM measuring device to give the motor more volts or a higher amp limit.
The motor is simply pushing air. Air isn't something like a solid load where a motor might lift something or move a lever or gear, it's fluid. The motor is going to run at max and be done.
Ya, and restricting airflow reduces load. It may not be intuitive, but you can plug a vacuum cleaner into a meter and put your hand over the tube to restrict airflow. The load on the fan will go down because less air means less friction. In other words, it's easier to run a fan inside a vacuum. The louder sound you get when you put your hand over a vacuum cleaner tube is the motor speeding up because it has less load.
> I have a degree in electrical engineering, thank you for telling me to do my research, I spent four years doing that.
Apologies for the tone!
> Have you ever opened one up and did a repair?
Well funny you should ask, but yes! Two times. One time, a power relay on the control module shorted and blew a hole in the circuit board. Had to replace the control module there. Another time, the start capacitor needed to be replaced on the giant 2KW squirrel cage motor. I removed the blower, disassembled it, lubricated moving parts, and of course tested it out on a stand. That much blowing power is quite impressive when right next to your face.
That's true, but it's not so simple anymore. Furnace blowers are all electrically commutated brushless DC motors now, and will ramp to keep a constant torque.
It’s a trade off though, because good filters will keep dust out of the HVAC systems innards, which according to the techs I’ve talked to makes a difference in longevity.
You can't just swap filters, the 4" thick one usually go in right before HVAC air handler intake rather than at returns. I have had an AprilAire installed for over 10 years in my HVAC when it was replaced last time, recommended by HVAC installer, its has worked very well and I do have my blower fan cycle constantly regardless of need for heat/cool to turn over and filter air.
1. https://www.aprilaire.com/whole-house-products/air-purifiers...