Monitoring a Live, 80W, 12VDC Load

  • Thread starter LotusDome
  • Start date
  • Tags
    Load
In summary, the author is looking for a way to monitor the current going through a resistance wire-based heating element circuit. He is considering using a multimeter, a transistor, or a reed relay. All of these suggestions have drawbacks. The author is grateful for the contributions of the other contributors.
  • #1
LotusDome
15
3
Greetings, folks!

I need easy, visual confirmation of the continuity of a resistance wire-based heating element circuit (~80W, 12VDC): it is simply a loop of Nichrome resistance wire (with a fuse!) connected to a 12VDC battery bank.

If the circuit breaks somewhere, I need to know ASAP--that heat is essential! As I am completely off-grid on a solar-panel system, I also need to minimize the additional loading of the circuit. Incorporating a single LED would be ideal: cheap, tiny (size and draw), reliable, and visible in all lighting conditions. (The LEDs I currently use are each 12VDC, in series with a 750-Ohm 1/4W resistor.) I don’t need any other information; I only need to know if current is flowing through the circuit!

My challenge is:

- the LED must be on one side or the other (high or low) of the load. If it were to span the load then it would simply be in parallel with the load and would be illuminated even if the resistance wire of the heating element breaks, and

- I can’t put the LED directly in series with the load! ;-)

A cheap DC multimeter would tell me the current going through it, but it doesn’t light up and I only need to know if any current is going through it! Thus I assume some form of shunt is necessary. I am considering a 100-Watt, 750-Ohm resistor in parallel with the LED (and its resistor) on the low side of the load as the only practical solution.

My assumptions regarding the resistor:
The 100 watts is to allow for the full current passing through the heating element.
The 750 ohms is to force enough current to pass through the LED (and its 750 ohm resistor) so that it illuminates.

Is this a functional solution?

Is it the most practical and reliable solution?

Is there a cheaper solution?

Thoughts?

Please forgive my ignorance and thank you for being such a valuable resource of information!

Thanks!
 
Engineering news on Phys.org
  • #2
Wind about 10 turns of wire (in series with the heater) around a small magnetic compass, and point the coil East-West. If the compass points North-South, the current is off.
Bob S
[added] A 10-turn, 6-amp, 4-cm diameter coil will produce about 6 Gauss (6 x Earth's field).
 
Last edited:
  • #3
:) Hi Bob.

LotusDome:

I wonder if you could afford to lose 0.6 of a Volt?

If so, something like this may be OK:

LED indicator.PNG


There are other ways (opamps and microprocessors) that would allow you to have less of a voltage drop, but this one is pretty simple.
The transistor could be a BC548 or similar low power, high gain device.
 
  • #4
LotusDome,
I think that the other contributors have given some promising and relatively simple :smile: suggestions for an indicator. Perhaps it would also be helpful for you to think a bit more about your original solution. Possibly I have misunderstood your description. but it does not appear to be correct.

In particular, think about why you thought that a 100W 750 ohm resistor would be required.
How much power can be developed in a 750ohm resistor with only 12V supply? How much current could pass through it? Remember I=V/R, P=V2/R

A shunt for monitoring current usually has a low value to mimimise power loss. The voltage across it should be as small as possible. In your case, developing the full LED voltage across a shunt would be very wasteful, so it would be better to use an amplifying switch such as a transistor, which needs less input voltage. Alternatively, an electromagnetic indicator like the compass in a coil would drop very little.
In days gone by, one might have used a commercial analogue ammeter!
 
Last edited:
  • #5
All of my old cars prior to about 1960 had analog ammeters with a low voltage drop. You could possibly find one in an old junkyard.
Bob S
 
  • #6
Digikey sells Allegro current sensors. You can keyword search for In Stock parts.

This product can sense 20A but operates off of 5V, has linear output, and is surface mount:

http://www.allegromicro.com/en/Products/Part_Numbers/0713/0713.pdf

So you'd need to do some work to make it work for you.
 
  • #7
Thanks, folks, I really appreciate your input!

vk6kro’s schematic looks promising and I expect(ed) that Adjuster’s concerns about my (limited) understanding of resistors are correct. Because of the storm that has rolled through, I cannot yet add any more info. as I must get offline, but I wanted to express my appreciation ASAP.

When I can get time online again, I will investigate and let you know how it goes!

My deep appreciation and Happy Holidays to you all!

Blessings.
 
  • #8
How about using a reed relay with a very low resistance coil? There is plenty enough current to operate a reed switch via a hand wound field coil with a few tens of turns. The switch contacts could operate a signal light and give you an audible buzzer alarm too. Suck it and see! Totally fail safe.
 
  • #9
I've been watching this one for awhile, and I'm surprised that no one suggested a comparator chip, say an LM139, with a low value resistor (i.e. a 6" piece of wire) in series with the load. That would keep the drop minimal, and require little power.

- Mike
 
  • #10
Yes, it's obviously a good and cheap way to do it, for someone familiar with op-amps etc. However, the content of the initial post suggests that the writer may not have this background, and so might need quite a bit of help with it. (LotusDome, please comment if you think I have got this wrong!)

For instance, if you take advantage of the comparator's high sensitivity and use a very small sense resistance, the wiring layout needs to be considered carefully. Voltages dropped in unfortunately arranged wiring can easily upset this sort of thing. The arrangement of the sensing and reference connections to the comparator would have to be carefully described.
 
  • #11
vk6kro said:
There are other ways (opamps and microprocessors) that would allow you to have less of a voltage drop, but this one is pretty simple.
The transistor could be a BC548 or similar low power, high gain device.

Mike_In_Plano said:
I've been watching this one for awhile, and I'm surprised that no one suggested a comparator chip, say an LM139, with a low value resistor (i.e. a 6" piece of wire) in series with the load. That would keep the drop minimal, and require little power.

- Mike

Thanks adjuster. Well said.
Using a comparator with inputs near its supply rails would be full of traps for a beginner.

Another way which I wouldn't suggest would be this one:
Hall probe in toroid.PNG

A small gap is cut in a powdered iron or ferrite toroid and a Hall probe chip is inserted in the gap. A few turns of wire are wound on the the toroid. The magnetic field is concentrated on the chip which can then be used to switch a LED on or off.

I exaggerated the gap size. It should be a tight fit for the Hall chip.
And the toroid would normally be circular.
 
  • #12
Greetings, folks, and thank you all for you kind assistance!

I have much technical training and experience, but no training in electronics, thus my vast ignorance in this regard. Also, due to an extreme accident (I am told I fell about 200 feet, head-first into an ice-wall), I currently have very limited resources. In a week I will have the only chance to visit a Radio Shack for the next few months; thus I most-humbly request some further information regarding resistors.

Specifically:

When a resistor is rated at, say, 5W, does it not mean that the resistor can only allow 0.42A of current (at 12VDC) to pass before it risks failure (as I perhaps incorrectly assumed)?

In the circuit that vk6kro was VERY kind to provide (thank you!), there are two resistors used to divert a controlled amount of electricity to the transistor, used as a switch, that would then allow the flow of electricity through the LED--if there is any current going through the main load. (I do need some form of illumination as I must be able to check the continuity easily at night and it must be small.) Without the specified 0.1-ohm, 5W resistor, there wouldn’t be any resistance to force some electricity to the transistor; it would simply follow the “route of least resistance.” Perhaps I am incorrect here as well!

If so, then a 0.1-ohm, 5W resistor in a 12.5-15.5V circuit (depending on the battery bank being charged by the solar array or not) with an ~80W load should be a small fraction of the necessary capacity (again, as I perhaps incorrectly assumed!).

What I do not understand then, is how the choice of resistors is determined; thus please allow me to ask:

What are the calculations behind the choice of the 1K ohm resistor and the .1 ohm, 5W resistor, given that the circuit will be drawing 80W (or more, given the voltage at the time--thus my belief that I needed a 100W resistor to be safe from overheating)?

In vk6kro’s schematic, I assume that the “1K” represents a 1K-ohm resistor; I am using 750 ohm, .25 watt resistors for single red LEDs. Would .25W then be a proper value for this resistor as well?)

Blessings to you all for your patience and efforts!
 
  • #13
If you look at the current flowing, 80 watts at 12 volts means that 6.66 amps is flowing.

(12 volts * 6.66 amps = 80 watts)

So, 6.66 amps through 0.1 ohms is 0.666 volts.
(V = I * R... so ...V = 6.66 * 0.1 = 0.666 V).

It takes 0.6 volts to turn on a silicon transistor so there is 0.066 volts across the 1 K resistor.
So, there will be a base current of about 66 uA.

With a high gain transistor with a gain of about 200 this will give a collector current of about 13 mA.
This will be enough to light the LED, and you can change the 1 K for something smaller if you want it brighter. (Yes, 1 K = 1000 ohms). Maybe 470 ohms would be a better choice.

Having a LED on when it is working is also a check that the power supply has not failed. If the LED only came on when the circuit failed, you wouldn't know if the power had gone off.

EDIT: The power dissipated in the 0.1 ohm resistor is as follows:
Power = Voltage * Current = 0.6666 volts * 6.666 amps = 4.44 watts so a 5 watt resistor would be OK, but it will get hot. 10 watts would be OK too, if that was available.

The 1 K can be anything but 0.25 watts would be fine. It is dissipating 44 uWatts.

.
 
Last edited:
  • #14
Guys. We have Eight Amps to dtetct here. Why are people insisting on solutions that will detect milliAmps?
A simple 40 ampere turn reed switch will operate reliably with, say, 20 turns of wire, wound into a solenoid, with a ball point pen body as a former and held together with Araldite. The switch can be put in parallel with an LED and the two can be put in series with a 1kohm resistor. As long as there is current, the LED will be off. When continuity fails, the switch will open and the LED will light. That solution is almost FREE!
It's at least worth a try- old technology is good for some things and easy to understand.
 
  • #15
sophiecentaur said:
A simple 40 ampere turn reed switch will operate reliably with, say, 20 turns of wire, wound into a solenoid, with a ball point pen body as a former and held together with Araldite. The switch can be put in parallel with an LED and the two can be put in series with a 1kohm resistor. As long as there is current, the LED will be off. When continuity fails, the switch will open and the LED will light. That solution is almost FREE! .
Good ... except when the 12 V battery is discharged, the LED will also be off. The LED has to be ON when the current is flowing. Then the LED is OFF whenever EITHER the load is disconnected OR the battery is dead.

I just placed a single wire carrying 3 amps on top of a compass needle oriented N-S, and the compass needle rotated 45 degrees. So a couple of turns around the compass will work adequately, unless a remote readout is needed.
Bob S
 
  • #16
Ok. Have the switch in series with the LED,then. No current, no light.
 
  • #17
Lol.
Good thing there are no psychologists replying - you'd hear about how to regress your amperage through hypnosis or something.

Why not...
wrap one of the power leads around a toilet paper derder?
Then, turn on the power, set a cake pan under the derder and dump a handfull of paperclips into your electromagnetic coil?
If power goes off, the clips will clatter like madness into the cake pan below.
If you want a visual alert, put a paperclip on the bottom of a red straw. The straw will fall out of the coil if power cuts off.

MacGyver's kid sister was consulted for these suggestions.
 
  • #18
For the transistor based alarm, would it be worth adding a very weak pull-up resistor from the transistor base to +12V, (say about 47kohms if the suggested 1k base feed is used). The idea is to increase the base voltage slightly, although not enough to turn the transistor on with the element failed.

I'm concerned that the voltage might not be enough to guarantee the transistor on if it is exposed to cold weather, or perhaps if the battery voltage is low. Alternatively, raise the 0.1 ohms a bit, but that would waste power.

Finally a suggestion for LotusDome, if mobility problems or any other reason mean you can't easily get to a dealer, can't you get components by mail/internet order? Actually, I've just had a thought: ice-wall accident...storm rolling in - are you at a very remote location?
 
Last edited:
  • #19
Thanks for the response, BenchTop! You are the only other person I know, besides the person who told me, what a derder is! ;-)

Thank you, Adjuster, for your intuitiveness. I am a monk, living alone in the vast, UT wilderness after the accident; my production company is “dormant.” (The details of the interim R & D work I am doing, and thus why I need these indicator lights, is described on the Status Updates page of www.LotusDome.com ) Temperature here is a big concern, thus this thread (see below).

The pull-up resistor sounds like a wise choice, given the conditions, Adjuster. Where would it go in the schematic? FYI, Digi-Key may be necessary as Radio Shack doesn’t seem to have any resistor in the 0.1-ohm, 10W range; I just wanted to spare the shipping and retrieval costs as I am a long way from a dirt road.

Given vk6kro’s kind (and patient!) advice:

> If you look at the current flowing, 80 watts at 12 volts means that 6.66 amps is flowing.

I learned it long ago as the West Virginia law, W = V*A. Although I haven’t yet mentioned it, as it is running off a battery bank fed by solar panels, the voltage can get up to 15.5V when charging. This is why I asked for the equations, to not impose any more than I already am.

> So, 6.66 amps through 0.1 ohms is 0.666 volts.

This is what has me so baffled. Why would there suddenly only be 0.666 volts in a 12V circuit? Did it get “absorbed” by the ~80W load and thus there is no “pressure” on the low side?

In closing as the temperature plummets, a brief elucidation of the conditions here:

It does get “a bit chilly” here so I appreciate your concern regarding exposure, Adjuster; it has rarely gone above freezing during the day this past month and gets down to well below zero degreesF at night. One of the indicator lights--the one being discussed--will be to tell me if the composting toilet is freezing up solid . . . again. (I have just built and installed two aluminum, resistance wire heating plates inside the drum to compensate, thus this thread) Another indicator light is to tell me if the cat’s 48W 12V electric blanket is functional--they get the electric blanket not me; it’s a compromise they both grudgingly accept. ;-) FYI, it can get over 100 degreesF during the summer.

Blessings to you all for your kindness and patience (and God bless satellite modems!). I am deeply appreciative, and humbled, by your help.

Richard Fairbanks
 
  • #20
I am a monk, living alone in the vast, UT wilderness after the accident;

WHAT ACCIDENT?

> So, 6.66 amps through 0.1 ohms is 0.666 volts.

This is what has me so baffled. Why would there suddenly only be 0.666 volts in a 12V circuit? Did it get “absorbed” by the ~80W load and thus there is no “pressure” on the low side?

If you like, you can imagine your 80 watt 12 volt load as a 1.8 ohm resistor made up of 18 resistors all in series with 0.1 ohms marked on each one.

Each one has 6.66 amps flowing in it and 0.666 volts across it.

Can you see that all these 0.1 ohm resistors would equally share the supply of 12 volts and all their 0.6666 volts would add up to 12 volts?

Adding another 0.1 ohm resistor reduces the overall current slightly because you now have 19 0.1 ohm resistors in series and 6.3 amps flowing, so each resistor in the series string would have 6.3 amps flowing in it and 0.63 volts across it, including the recently added external 0.1 ohm resistor.

All these precise calculations change when the battery voltage rises to 15 volts, though.However, I do like the reed switch idea. I'm not comfortable with using 5 watts just to turn a LED on.
Since it was Sophiecentaur's idea, maybe he could draw up a detailed picture of how to do it.
It is an easy and efficient way of doing it.
 
Last edited:
  • #21
from vk6kro:

> WHAT ACCIDENT?

Thanks for asking; it’s detailed (what I have been told—I have no memory of it) on the Status Updates page of www.LotusDome.com .

<snip>

> All these precise calculations change when the battery voltage rises to 15 volts, though.

Please forgive me for not detailing the solar power set-up earlier; I thought I could just resolve it at this end after the calculations were known. My sincere apologies!

> However, I do like the reed switch idea. . . . It is an easy and efficient way of doing it.

from sophiecentaur:

> The switch can be put in parallel with an LED and the two can be put in series with a 1kohm resistor. As long as there is current, the LED will be off.

and

> Ok. Have the switch in series with the LED,then. No current, no light.

----

After all this, if the switch is in series with the LED, why the switch? Why can’t the LED just be in series with a 1K ohm or 750 ohm, 1/4 watt resistor, in series on the low side of the load? Then there would be no switching necessary at all: If the load loses continuity, the LED gets no current and thus doesn’t light up.

I thought (as per the original post, most-likely in error!) that the LED would not be able to handle being in series with the ~8 amps going through the circuit and would immediately fry and open the circuit—exactly what I need to avoid.

Please excuse my brevity, I must go into town for propane before I run out.

Blessings and thank you again for you kind efforts!
 
  • #22
Yes, the reed relay sounds like a good idea simple idea, and it neatly sidesteps the difficulties that seem to be attached to some other suggestions. However, given your accident, will you be able to wind coils yourself, or can someone help you with that?

This has been an interesting discussion. It shows that there is more than one way of skinning... No doubt there are more possible ways, such as using temperature alarms to detect cooling, but we have to call a halt somewhere.

The discussion has also reminded me of how often difficulty seems to be encountered in understanding voltage drops and potential division. There has been quite a lot of discussion of such topics on the web, e.g. on voltage dividers, or on choosing LED dropping resistors.

I would very much like to help clear up some of the confusion, but don't really know how - can anyone advise me? My guess is that for many the stumbling block is a failure to grasp that current is equal throughout a series circuit. Of course, this is way off the original topic. We really need a new thread - something like "Potential Division: Half a Bridge Too Far"?
 
  • #23

After all this, if the switch is in series with the LED, why the switch? Why can’t the LED just be in series with a 1K ohm or 750 ohm, 1/4 watt resistor, in series on the low side of the load? Then there would be no switching necessary at all: If the load loses continuity, the LED gets no current and thus doesn’t light up.

I thought (as per the original post, most-likely in error!) that the LED would not be able to handle being in series with the ~8 amps going through the circuit and would immediately fry and open the circuit—exactly what I need to avoid.


Your heater has a resistance of about 1.8 ohms. If you put 750 ohms in series with that. the LED will light up, but the current through the 1.8 ohms will be so low that there will be no heating. Your cat will shiver and your toilet will freeze.

At present, the current is 6.66 amps. With the 750 ohms in series, the current will be (12 / 751.8) or 0.015 Amps.

A reed switch looks like this:
258px-Reed_switch_%28aka%29.jpg


although usually about half that size.

You would connect it like this:

reed switch.PNG


The strange looking switch is the reed switch which is enclosed in a sealed glass tube.
It is activated by current flowing in the coil wrapped around it.

I wrapped 100 turns of wire onto a reed switch and it took 0.8A to close the switch. This is 80 ampere-turns. So if you had 6 amps you would need about 80 / 6 turns or 13 turns to operate the switch. Polarity didn't matter so you could connect the coil either way.
 
  • #24
LotusDome,

I really don't know if this will do any good, but I feel that I have to give it a try:

If we have some resistances in connected in series, the total resistance of the circuit is equal to the sum of all the resistances. RTOTAL = R1 + R2 +...etc

The current passing through the series circuit is determined by dividing the voltage applied between its two ends by its total resistance as described above. I = VTOTAL/RTOTAL = VTOTAL/(R1 + R2 +...)

Please note that the SAME current passes through each resistance in a series string. The voltage developed across any resistance within the string can therefore be found by multiplying the current by the value of that particular resistance.

These are established principles which let us make the kinds of calculations that other posters have described.
 
  • #25
Blessings and Happy New Year!

This is very exciting; thank you all! I am deeply grateful for the patience and effort you have all put into this!

from Adjuster:

> Please note that the SAME current passes through each resistance in a series string.

This is what I did not know; I didn’t know what remained constant, the voltage or the current. THANK YOU! I can stop be (quite) so much of a pest!

from vk6kro (in reference to the reed switch):

> You would connect it like this:

Thank you! In the middle of the night, I figured that such had to be the case, blessings to sophiecentaur for the initial suggestion and to you for the schematic! It sounds like a great solution.

Thus, please allow me to describe what I understand to be the procedure to make the switch, based on the schematic:

The coil can be constructed with any single-conductor wire of similar gauge (16g.) and resistance (virtually none) as the 16g. zip cord I am currently using to feed the load(s).

I assume vk6kro’s reed switch is only concerned with a minimum of 80 ampere-turns needed to close the NO (normally open) switch. Is it correct that higher amperage through the coil should have no effect as the switch will already be closed? If so, I could make a collection of identical switches that will work with a variety of loads, as long as the loads are drawing greater than a minimum amperage.

For example: To allow for the maximum range of possible voltages coming from the solar-charged battery bank, I could plan on a range of 3-9 amps running through any given coil (for the cat blanket or composting drum switches). To make a coil for an 80AT reed switch, running off a minimum 3A load, I would then wrap the switch with a minimum of 27 turns of wire. (To allow the switch some “grace,” I could make it with 30 turns.)

Two sets of questions regarding the wire and switch:

1: Kind of Wire:

What is the criteria for the wire for the coil? Is insulated wire acceptable? Do I need to use “magnet wire” or can I just use 18AWG “hookup wire”?

2: Kind of Switches:

If I go to http://www.digikey.com/" and search for:
Reed Switch
SPST-NO (Normally Open)
500mA Switching Current (DC) (Max)

An item returned is: http://search.digikey.com/scripts/DkSearch/dksus.dll?Detail&name=ORD2212-2030-ND" :
Type: Glass Body
Circuit: SPST-NO
Must Operate: 20 ~ 30AT
Must Release: -
Switching Current (DC) (Max): 200mA
Switching Voltage (DC) (Max): 100V
Switching Power (Max): 10W

With a switching current of 1.5A, however, an item is: http://search.digikey.com/scripts/DkSearch/dksus.dll?Detail&name=HE546-ND" :
Type: Glass Body
Circuit: SPST-NO
Must Operate: 27 ~ 33AT
Must Release: -
Switching Current (DC) (Max): 1.5A
Switching Voltage (DC) (Max): 200V
Switching Power (Max): 50W

Are these acceptable switches? Is there any reason not to get the more powerful switch? Is the 20 ~ 30AT (or 27 ~ 33AT) windings a necessary range to be adhered (I.e., it can’t handle a higher magnetic field and a lower value will not be strong enough to close the switch) to or is it an approximated minimum value?

Thank you!
 
Last edited by a moderator:
  • #26
I assume vk6kro’s reed switch is only concerned with a minimum of 80 ampere-turns needed to close the NO (normally open) switch. Is it correct that higher amperage through the coil should have no effect as the switch will already be closed? If so, I could make a collection of identical switches that will work with a variety of loads, as long as the loads are drawing greater than a minimum amperage.

Because of the limited space, plastic insulated wire would not be suitable unless you only needed a few turns. These switches are very small, but I managed to wind 100 turns of 0.0125 inch diameter enamel coated wire onto mine. I wound it right onto the glass.

I don't think extra ampere turns will matter, but extra wire means you will get some unnecessary voltage drop.

Either of those switches sounds OK.

Glad you understood the ampere-turns concept. It is useful in this case.

These switches can also be operated by bringing a strong magnet near them. So, you could have a buzzer sound if your cat went outside through a catflap door, for instance.
 
  • #27
The diameter of the turns does not matter - the coil doesn't need to 'hug' the switch. The activating Magnetic field is defined in terms of Amps times Turns which doesn't mention diameter. This simplified terminology applies to any solenoid as long as it is significantly longer than its diameter. More turns (of thicker wire) will obviously fit easier onto a larger former. There is no harm in providing much more field than specified: these switches will work with very powerful little permanent magnets up very close - and then release.
I'm glad you like the solution, LotusDome - it's so lo-tech and easy to build. Fault finding will also be easy! I think you may need to be careful when soldering to the leads on the reed switch and keep away from the glass, avoiding 'roasting' them. If it reluctant to take solder, first time, then gently clean the leads with fine glass paper to give a clean surface.
 
  • #28
If there are too many turns of wire on the reed switch, it will pull in at a too low a current, say 30A-T, when there are 10 turns carrying 6 amps = 60 A-T at a fully charged battery = 12 volts, so if it drops out (opens) at 15 A-T, that would correspond to maybe 3 volts left on the 12 volt battery. Maybe it should pull in at 10 volts and drop out at 5 volts. Minimum hysteresis is important. It would be nice if it dropped out at ~8 or 9 volts.
Bob S
 
  • #29
There is no end to the possible sophistication. I thought the original problem was just to detect a break in continuity. If more detail is required then a set of reed switches and appropriate coils with red green and orange LEDs could show the supply volts gradually dieing. Or a voltmeter?
 
  • #30
The reduced brightness of the LED should indicate that the battery voltage is down.
 
  • #31
Thank you all so much!

Wow. I feel like a mortal who was allowed to eavesdrop on a debate between the Gods!

I got the reed switches and the 18g. magnet wire in! (The 18 gauge wire will minimize any additional resistance in the circuit and the 1.5A switch will be able to do a lot more than just light a LED!)

I wrapped 14˝ of the the wire around a 7/64˝ drill bit shank (after breaking the first switch wrapping the wire around it—wow, they are fragile!) for 18 turns and it works great! 18 is about all the turns that can fit on the switch, but I figured it really didn’t have to fit entirely on the switch if it wasn’t in contact with it. So . . .

I made two more with 22 turns each and am using them inside the Sun-Mar Excel NE composting toilet to monitor each of the two heating plates separately (WOW!), with the switch sitting inside the coil, which is wrapped with a strip of a rubber jar-opening pad, and all slid inside in a 1/2˝ copper tube to protect them. The ends of the copper tube are sealed with hot-melt glue (a reliably unreliable material which allows it to be disassembled if ever necessary ;-) ).

They work great! Thank you! And the red LEDs are great for night lights! (“It’s a floor wax. No, it’s a desert topping.” ;-) )

Now I want to take a dual trip point temperature sensor with a NTC thermistor, set such that it will switch the heating plates on when the compost inside the composting drum gets down to 20 degreeC point and it will switch the heating plates off when the compost inside the composting drum gets up to 40 degreeC.

But that’s another topic for another time—I still need to do more research. ;-)

Thank you all SO MUCH for your help!

Blessings to you all!
 

FAQ: Monitoring a Live, 80W, 12VDC Load

What is a live load?

A live load refers to the amount of power being drawn by a device or system that is actively in use. In this case, the live load is 80 watts at 12 volts DC.

Why is it important to monitor a live load?

Monitoring a live load allows for the measurement and analysis of power usage, which can help identify any potential issues or inefficiencies in the system. It also allows for proper maintenance and troubleshooting.

How is a live load monitored?

A live load can be monitored using a variety of tools such as multimeters, power analyzers, or data loggers. These devices measure the voltage, current, and power consumption of the load.

What factors can affect the live load?

The live load can be affected by changes in the power supply, fluctuations in the electrical grid, and the efficiency of the device or system being powered. Temperature, humidity, and other environmental factors can also impact the live load.

How can the data from monitoring a live load be used?

The data collected from monitoring a live load can be used to optimize power usage, identify potential issues or malfunctions, and make informed decisions about maintenance and upgrades. It can also help with energy management and cost-saving measures.

Back
Top