So, I learned something interesting about the technology underpinning refrigerators once. In my case, it was an old HVAC AC unit.
We had it checked once, and the tech said the until was really old, but seemed fine. It turns out the old units lasted forever, because they were made with heavy duty materials - thick steel, etc. The downside was that the efficiencies were really low. He said it was a trade-off: you get higher efficiencies by using thinner metal with better thermal conductivity, but you sacrifice durability. Basically, itβs a trade-off between durability and efficiency. Whatever built-in obsolescence you get is on top of an essential limitation in physics: it takes more energy to transfer heat between thick metal and thin, and thin just doesnβt last as long.
Iβm not a materials scientist, so Iβm probably paraphrasing him wrong and misinterpreting it, but since his advice was to not replace it until it died, which could be another decade, unless I had an urgent desire to get a higher efficiency unit, I figured he wasnβt BSing me and took him at his word.
I absolutely believe in planned obsolescence, but I also believe that there are some fundamental laws of physics contributing to lifespan of appliances. If you want high efficiency (in some types of appliances, such as refrigerators), youβre generally going to be working with more flimsy materials which are more prone to breaking down.
I suspect that the higher efficiency donβt make up for the irreparability and subsequent waste of replacing appliances more often, but Energy Star contributed to requiring some of that, so not all of the blame can be laid on manufacturers.
I dunno if that is true of refrigerators. Newer fridges have more electronic components, vs just a compressor and some simple mechanics on older fridges. The cooling tech on fridges hasnβt changed much, but the extra amenities sure have.
Yea, for appliance components like compressors, thinner materials has practically no impact on performance (but probably saves a little money on manufacturing, and probably reduces life span).
For the condenser and evaporator, it could make a difference, but those have been largely optimized probably since the 60βs - theyβre not complex things. Even there, a thinner wall on the tubing isnβt really going to make a major improvement, since itβs fin density that really matters.
Itβs controls that break 98%+ of the time. A refrigeration circuit is pretty simple, so long as you donβt poke a hole in the system, generally it will continue to work.
Of all the systems Iβve worked on, Iβve rarely replaced even a compressor (it does happen). Condensers and evaporators practically never wear out - almost all that Iβve replaced have failed from being hit by something, or being cleaned with an unfriendly chemical (some newer ones are really fragile, and even conventional ones donβt like dog urine on them constantly). A family friend has been an HVAC guy since I was little (he taught me), and this squares with his experience.
Controls are #1, seals are second (especially on automotive systems, since they get shaken around constantly and deal with much greater temp swings).
βNewβ stuff (starting in the 80βs) has shit electronic controls - theyβre manufactured as cheaply as possible (unlike say electronic controls for a car engine or safety systems, which have to meet regulatory requirements). Old school controls are so simple thereβs little to go wrong.
The βnewβ DC/inverter compressors are probably the biggest improvement in recent years, since they can run at varying loads instead of just off/on - this should make them noticeably more energy efficient.
The pieces of refrigerators that have failed me in the last 15 years have been the plastic parts. A small improvement in plastic quality or engineering seems like it could double the life of the refrigerator. And of course a small plastic replacement part costs $50 or more.
In the case of refrigerators, there doesnβt need to be any trade-off between efficiency and heavy duty. The main thing determining efficiency is primarily where the heat exchanger is positioned (top mounted is the most efficient, but uncommon), and the thickness and quality (R value) of the insulation.
If you add extra insulation to an old heavy duty fridge, it increases its efficiency by 50% or more (depending on the thickness of insulation).
The extra insulation, as a side effect of better efficiency through better temperature retention, will also extend the lifespan of the compressor, which will need to run half as much as normal.
The main reason this isnβt done from the factory is cost, and to reduce the physical dimensions of the fridge.