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1. ## electric heater

This heater I have is rated at 1800 watts. Before i plug it In I would like to know if the older wireing system here will be able to handle it (positive and negative wires only in any one outlet). What is the best way to figure for that ? Every outlet in this place is a GFCI (Bdrms.,living room,kitchen and 1 in bathroom) or will this type of outlet trip if to much or not enough juice Is detected at outlet ? Thank you

2. ## It sounds like it would be close

Without knowing more about the wireing in the home it is difficult to answer.

However, somthing that might help is

Voltage X amps = Watts

So, Amps = Watts / Voltage

1800 watts/120 volts =15 amps. Normal household circuits will be 15 amps.

You would be pulling 100% of the circuits rated capacity if it is a 15 amp breaker with just the heater alone.

Next you can look at the gauge of the wire. If it is 14 gauge then 15 amp is the max amp allowed.

12 Gauge could carry a 20 amp circuit.

I know this does not exactly answer your question but might help

3. Originally Posted by DIY
This heater I have is rated at 1800 watts.
If you have a voltmeter, measure how far the voltage drops when you turn on the heater and post back. A 3vac drop is about normal; that is, from 120vac to 117vac, for example.

4. ## power

The wire size, circuit breaker, and additional load on the circuit will determine whether you can safely use the heater in that outlet.

5. Just curious...

What is the brand / model of the heater and what type of plug does it have on it? (Regular outlet plug?)

Has the plug been changed from the manufacturer's supplied plug?

6. Originally Posted by DIY
This heater I have is rated at 1800 watts. Before i plug it In I would like to know if the older wireing system here will be able to handle it Thank you
No .

7. Originally Posted by Thatguy
If you have a voltmeter, measure how far the voltage drops when you turn on the heater and post back. A 3vac drop is about normal; that is, from 120vac to 117vac, for example.
How does this help the OP to answer their question?

8. Basically, that heater will draw close to a full 15A, and if your input voltage drops below 120 (and your normal may be lower than that), it will try to draw more than 15A, so it is very likely it will trip the breaker or blow the fuse fairly quickly. A constant load like that should have some excess capacityon the supply side. I'd be somewhat surprised if it didn't have a 20A plug on it. This has one of the blades turned 90-degrees so it will only fit into a 20A receptacle.

9. Originally Posted by Jim Port
How does this help the OP to answer their question?
It checks connection integrity. Hello again, Mr. Port.

10. This heater will need to be multiplied by 125% or figured at 2250 watts.
The minimum circuit capacity will need to be 18.75 amps.

Most 20 amp circuits in a normal house will trip after a couple hours with a heater this large plugged in.

On any circuit watch for failure of the receptacle that is being used. In most houses all the receptacles are rated for 15 amps and this heater will be drawing the heat of a 18.75 amp load.

11. Originally Posted by jwelectric
This heater will need to be multiplied by 125% or figured at 2250 watts.
The minimum circuit capacity will need to be 18.75 amps.

Most 20 amp circuits in a normal house will trip after a couple hours with a heater this large plugged in.

On any circuit watch for failure of the receptacle that is being used. In most houses all the receptacles are rated for 15 amps and this heater will be drawing the heat of a 18.75 amp load.
I thought the 125% rule was for calculating sizes for dedicated load circuits like hot water heater.

Why would a 1800 watt plug in heater be pulling 2250 watt load?

Also, why would a 20 amp circuit trip from a 18.75 amp load after couple hours? Heat buildup in the panel?

12. Originally Posted by arfeller
I thought the 125% rule was for calculating sizes for dedicated load circuits like hot water heater.

Why would a 1800 watt plug in heater be pulling 2250 watt load?

Also, why would a 20 amp circuit trip from a 18.75 amp load after couple hours? Heat buildup in the panel?
Any resistive load should be figured at 125% weather it is the branch circuit, overcurrent or even a plug and cord appliance.

If a 20 amp circuit has anything else in use with an 1800 watt heater you can count on the circuit opening each and every time, especially after an hour or so.

Any 15 amp receptacle weather used on a multi-outlet 20 circuit or not will fail when more than a 12 amp load is being used for an extended amount of time. This is where a lot of electricians make the statement of not using the stab lock on the back of a 15 amp device comes from.
The tension on the blades of the male plug will start to fail due to the heat of the receptacle.

A small test can be done with this type of portable heater that helps anyone to understand what is happening inside the receptacle. Simply plug in a small electric heater and let it run for about an hour. Unplug the heater and hold the male plug in a closed hand to capture the heat of the male plug inside the closed hand.
If is feels hot then the tension of the receptacle is being lost and at some point in time the prongs of the male plug gets spread apart in order to keep from falling out of the receptacle. At this point the receptacle is failing and needs to be replaced.

I have personally seen where the conductors, yes even the ones wrapped around the screw have started to discolor and melt from the use of portable electric heaters. I have seen many portable electric heaters where the male plug was deformed from the heat produced at that connection point.

Really want to see a problem with portable heaters. Use an extension cord so the heater can be placed closer and then the problems really begin especially from those little brown cords that cost \$1.19 at the local Family Dollar Store.

When the receptacle starts to fail and arcing starts between the blades of the male plug and the tension of the inside of the receptacle we now have an added resistance that is in parallel with the load.

Also in a parallel circuit the total resistance will always be less than the lowest resistor thereby causing more of a load on the overcurrent than the heater itself is pulling.

Should there be a resistance of 25 ohms at the receptacle in parallel with the heater then the 20 amp overcurrent device is maxed out.

13. 125% rule applies, no question about that.

Sounds like the OP needs to hire someone who knows what they are doing. Simply not enough information given to give an answer. At minimum a dedicated 20a circuit would be needed for using this heater. If it plugs in, I would suggest a single receptacle and not a duplex.

14. Originally Posted by jar546
125% rule applies, no question about that.

Sounds like the OP needs to hire someone who knows what they are doing. Simply not enough information given to give an answer. At minimum a dedicated 20a circuit would be needed for using this heater. If it plugs in, I would suggest a single receptacle and not a duplex.

Very sound advice as a single receptacle on a 20 amp circuit would require a 20 receptacle.

210.21
(B) Receptacles.
(1) Single Receptacle on an Individual Branch Circuit. A single receptacle installed on an individual branch circuit shall have an ampere rating not less than that of the branch circuit.

15. Originally Posted by Thatguy
It checks connection integrity. Hello again, Mr. Port.
The question was dealing with circuit capacity, not connection integrity.

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