AC power vs. DC power: Both are necessary in our everyday lives and switching between the two causes a great deal of strife in electronics. Why do we need both?
As some of you may or may not know, there was a long standing battle between the two types of power raging back in the 1880s between two giants. The proponents of this war knew that whoever won would determine the future of the power distribution in the United States and possibly the world. In the first corner was Thomas Edison and his company that would eventually become General Electric; Edison wanted the world to run on DC. In the other corner was Westinghouse Corporation, funded by George Westinghouse and led (intellectually) by Nikola Tesla. Westinghouse represented AC power and would be the eventual winner. You can read more about the battle HERE, but I thought it would be interesting to point out that this battle eventually became a political one. Edison even started fighting dirty, secretly funding the invention and use of the first electric chair powered by AC, in order to give some bad press.
AC of course won out over DC as the power distribution of choice, mainly because of the ability to have large generators in a central location and then transmit the power efficiently over power lines to homes and businesses. DC would have required local generators on every street or even every home, which was not possible nor economically viable at the time.
Hang on a second though…a DC generator on every home…sounds familiar…where have I heard about something like this before? Oh right, solar power. However, even more interesting than the fact that solar power produces DC power output is that any kind of storage will have to be in DC. So THAT means if you have any kind of renewable energy resource on your premises (wind, geothermal, any kind of generator which will have an AC output) and it’s not continually supplying power to your home, you will likely need to store it somewhere (assuming you are not selling power back to the power company, which is the case in some areas still and a must in the remote areas). Further, barring any possibility of storing AC power (a huge inductor?), you will need to store that power in DC. So let’s look at a theoretical wind turbine on a theoretical property:
The wind blows –> wind turbine spins –> motor in turbine creates AC power –> AC converted to DC –> DC stored in a battery –> DC converted back to AC when needed –> AC powers devices in a home –> (possibly) AC converted back to DC for use in consumer devices
That’s a lot of steps! Not only are there a multitude of steps to convert wind into air conditioning (heh, the electrical way…the natural way is opening the window), there are lots of places that you will be losing energy to inefficiencies. These occur in the power generation (motors have friction), the storage in the batteries (heat and losses due to chemical impurities in the wet cells), the AC to DC conversion and the DC to AC conversion (both processes lose energy to heat in the electronics). All told, it’s not hard to see why this is not the preferred method of powering ones’ home.
So now the real question: Can we take out some of these steps?
Other articles on this site will deal with improving efficiencies of each of these steps, but the simplest method for improving overall efficiency would be to remove one or more of those steps. The way I see it, one of these ways would be to convert a power scheme in a house. Let’s look at all the ways a DC power system in a house could be beneficial or detrimental to ones’ living situation:
Concerns about DC wall power
- Many devices have different voltages
- This would be a definite issue. Have you ever had to power a guitar pedal board? Random question perhaps, but if you saw what the power strip looks like, you’d catch my drift. Every one of those little electronic devices is too small for a transformer, so they all have AC-DC converters which can power the device with a different required voltage. Now take this idea and expand it to all the doo-dads in your house. I would be willing to guess that there are at LEAST 5 different required DC voltages for all of the normal devices in a home.
- Converting devices
- Conversions would be required from DC->DC instead of AC->DC. A possible solution would be to set up the wall sockets to have selectable DC output (perhaps the home runs on 100V DC and each socket can convert this down to 24V, 12V, 5V, 3V).
- Selling power back to the power supply company
- One of the most popular notions in renewable energy today is the idea of selling your excess power back to the power company, hopefully at a decent rate. Then when your device is not outputting power, you simply switch to grid power and start buying it from the power company. This is great because it does not require battery systems. And while this exercise excludes that option (for people living in the middle of nowhere or with unaccommodating power companies), it would be nice to sell any excess power back to make a small profit.
- Economies of Scale
- This is possibly one of the biggest problems that an all DC power system would face: No one does it yet! All parts would have to be custom made and you couldn’t just call an electrician to come out and fix your stuff.
- This also means that you would have a tough time buying consumer goods. Nearly every device has an AC plug, because that’s what everybody has! Not to mention all of the internal components for AC conversion and occasional power filtering (some devices need very clean DC power). Let’s just say you couldn’t go buy a TV and plug it in…
- Government regulation would also limit any kind of large scale implementation of DC power sockets. It is almost guaranteed that it would require government certifications on many levels to allow manufacturing large enough quantities to bring the cost down for Mr. John Q Everyman.
- Conversion to AC for certain devices
- Motors are the first kind that come to mind. This is basically how Nikola Tesla got started onto AC, proving that it is much more efficient when using AC than DC AND that these motors do not rely on voltage level (DC motors’ speed can be controlled by the voltage applied). This would mean you would either have to convert your DC back to AC to run the vacuum cleaner or you would have to make sure that your DC could supply constant DC and the whopping currents that those kinds of devices use.
- Step up/down transforming
- You know those big garbage can looking things that are attached to power line poles? Those are changing the ridiculously high voltages in the power lines (done for transmission efficiency) down to something that we can use in our houses. Further, these are VERY high efficiency devices. For power in general, you really can’t beat AC-AC conversion; the system proposed here would have to use transistors (note: not transformers) which will have some amount of heat loss associated with them. So even though we wouldn’t be using the AC power from the power company, we would be losing a critical tool in the electrician/electrical engineers’ arsenal, the transformer.
- Leakage currents and phantom power consumption
- No transistor is perfect, they all let just a little bit of current through. The more components in a system or the higher voltage you run at, the more leakage you will tend to have (Ever wonder why electronic devices run out of batteries eventually, even if you don’t use them for a long time?). This would apply to any DC system too and when you don’t have the lights on or anything running, there’s still a chance that the power devices are leaking. This will cut into overall efficiency.
Benfits of using DC instead of AC:
- Higher efficiencies off of battery power
- This point was discussed above, but is THE main point of the article and for going to all this trouble. The less you need to convert between AC and DC, the less energy will go to waste. And if you do need an AC power source, the inverter could be much smaller, in order to handle smaller loads or in order to sell power back to the power company (once the battery is fully charged)
- LED Lighting
- Currently any LED fixture installed in homes requires an AC-DC converter. Using a DC wiring system throughout a home would allow easy installation of LED fixtures and elements (the LEDs themselves)
- No 60 Hz hum
- I’m sure most of you know what this sounds like from a faulty light switch, an older device with poor power supplies or even by sticking a fork in the wall. The native frequency of power coming out of the wall is 60Hz in the US, but varies by region. Either way, this is something that I’ve had to deal with at my job and that all electronics designs have to deal with. With an all DC system there would be other issues such as power filtering and voltage stability… no hum though!
- Shrinking power supplies
- As devices continue to get smaller, the power supplies are reaching a lower limit. 1.8V is currently the lower end of DC supplies for microchips. This allows for less power consumption, as is governed by the formula P = V² * f * C (where P = power, V = voltage, F = frequency and C = capacitance). Have you ever noticed how they stopped increasing the frequency of microchips past a certain point (~3.5 GHz)? Yeah, it was because they started getting so hot you could fry eggs on the processors. Plus mobile processors became much more prevalent. As more and more devices go towards these lower voltages, there will be less need for conversion (or alternately, more need for AC-DC converters if wall power remains as AC).
So the final question comes back to that posed by the giants of the 19th century: AC or DC power? Well, really the answer will be both, as history has shown. Perhaps over time we’ll see a shift back towards DC power as devices continue to shrink and manufacturers don’t want to include bulky transformers or as people hopefully begin producing their own power at home; but one thing that is for certain is this battle will continue raging for a long time and hopefully we’ll help renewable energy find it’s place.
I welcome any and all comments on this idea and if you know of something being developed similarly, please let me know!
“If I have been able to see further than others, it is because I have stood on the shoulders of giants.” ~Sir Isaac Newton
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December 29th, 2008 at 6:58 pm
As the “green living” evolution changes our ways of thinking, I just had a few questions/proposals/comments and am looking for some input.
If one were to reduce the living space, for one, wouldn’t this make a difference in power drain?
LED lighting is great, I had thought of automobile-type bulbs, in small efficient areas throughout the home, but LED is ALOT more efficient. Thank you!
If one were to use the 12v automotive type plugs throughout the home, for items such as laptops, small dc fans strategically placed for cooling, and other portable type devices used in a more permanent setting, how bad would the power drain be? Also, how bad would dc inverters, like the type that are used in automobiles for powering laptops, drain the system?
Finally, larger appliances such as clothes washers and refrigerators, are there DC options available for these that would be efficient?
Thinking of building an approximately 600-800 sq. ft. vacation home that would be strictly DC powered and these are some questions I have…
Really enjoyed your post…
J.C.T.- Louisiana
March 18th, 2009 at 7:21 pm
Does anyone else have any experience with this?
May 30th, 2009 at 11:22 am
You mention the need to convert to AC for appliances, such as vacuum cleaners. Vacuum cleaners are one appliance that have always used AC/DC motors, so they could run directly on 120VDC, except the on/off switch would have to change. In fact, all switches in the house would have to be rated for DC, which is not trivial.
For low voltage devices, I fail to see why conversion from a high voltage DC source is more efficient than from an AC source.
JCT suggests wiring a house with 12V outlets. There is a reason that homes are wired with 120/240V. At 12V, the wires would have to be 10 times the diameter – using 100 times as much copper! Realize that a 1500W hair dryer or toaster would draw 125A ! Even 0000 gauge wire (almost 1/2″ diam) would be too lossy. Or are you suggesting a dual wiring system, with both 12V & 120V circuits?
June 8th, 2009 at 3:28 pm
We will never get away from 120V a.c. or 240V a.c. mains electricity depending whether you live in the US or the UK respectvely. ower levels of appliances are just too high….
a) 3kWatt immersion heaters
b) 2kWatt vertical kettles
c) 2kWatt hair driers
The list goes on.
I would however suggest 12Volts or 24Volts for ordinary house lighting. How many cars are there on the roads that use 12Volts, so no shortage of bulbs or storage batteries. How many trucks or aircraft are there that have a 24Volt system. No shotage of lighting equipment.
Storing any form of enery is potentially dangerous, hence Potential Energy.
Hot water storage for domestic housing from Solar Panels is not exactly dangerous. 39 cubic kilometres of water behind the Three Gorges Dam is dangerous, potentially.
June 18th, 2009 at 6:44 am
I am going through the misery of finding someone to help me design a 95% dc powered motorhome. None of the solar companies are interested in discussing these possibilities with me… they want to sell gen sets and inverters. The cost of an inverted system is outrageous. I want to use dc in everything – true, it drives up the initial cost, but when you are finished with a quality dc appliance, you still have something to sell. The only people that I can get advise from are the 12vdc alternator people, and their knowledge is usually not too broad. The others are those that prefer to live like hermits. As this nice website does not seem to prohibit emails, I would like to know somewhere I could go to find some advise/consultation on how to set up such a system – even if it costs to get that advise: tkmartin1070@gmail.com
June 26th, 2009 at 6:08 pm
Hey, this is a great post, I like your blog. I’m writing from the CPES at Virginia Tech, I came upon this post while doing some research for this program called the Sustainable Building Initiative. I shared the website with this comment, it’s exactly what you’ve written about, we’re designing and developing a showcase home running with DC. The grid will still be the main power source, with solar and wind sources helping to charge home battery storage and an EV battery, if plugged in. The concept is to have two DC buses, a 380V for large appliances (fridge, washer, dryer, etc) and a 48V bus for appliances. Lighting will most likely be a mix of fluorescent and LED, but I’m trying to see if we could use entirely nanocrystal LED. Anyways, just figured I’d comment since you wanted to know of anything similar being developed. If you want to get back to me, send me an email at ishkabum@vt.edu
August 19th, 2009 at 2:14 am
Nice one. I have been thinking along the same lines myself. Is it ok to reference your post in my work?
September 7th, 2009 at 12:29 am
I find solar/direct current powered aircons use less than half the power of grid(alternating) current aircons for the same cooling capacity. Why ?