Why is my 555 Timer not blinking?

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    555 timer Timer
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The user is experiencing issues with a 555 timer circuit designed to blink an LED, as the LED remains constantly on and the timer overheats. Key troubleshooting steps include verifying the wiring, ensuring the LED is connected correctly between pin #3 and ground, and checking the current-limiting resistor value. The user is using a 6V power supply with an NE555N timer, which should operate within safe voltage limits, but overheating suggests a possible short circuit or incorrect connections. Recommendations include checking for loose connections, testing the capacitor, and ensuring no shorts exist in the circuit, as prolonged overheating can damage the timer.
  • #51
chroot said:
This worries me. Pin #3 is the output pin, which supplies current to the load. If nothing is connected to it, it should be floating, and will probably not go all the way down to 0V. If you've connected pin #3 to your LED and resistor, it should have a voltage of around 4-5V on it.

If pin #3 is really all the way down at ground (0V), then a huge amount of current is likely flowing out of it. Something's screwed up with that pin. Disconnect everything from it, and make absolutely sure there's no continuity between it and the ground rail.

- Warren

The way I was told to do it was to disconnect the timer, and place wires where the pins would be, and to read those wires compared to a ground with a multimeter.
 
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  • #52
Oh, I see, you removed the timer and those are the voltages on the pins without it present.

Is there any chance that your breadboard is damaged, and there's a short in it that you don't expect? Do you have a multimeter with continuity testing?

At this point, I'd suggest that you dismantle the circuit, and build it again somewhere else on the breadboard. I'd start with just the VCC, RESET, and GND pins, make sure the part doesn't get hot, and then move on to connecting the rest of the circuit.

- Warren
 
  • #53
chroot said:
Oh, I see, you removed the timer and those are the voltages on the pins without it present.

Is there any chance that your breadboard is damaged, and there's a short in it that you don't expect? Do you have a multimeter with continuity testing?

At this point, I'd suggest that you dismantle the circuit, and build it again somewhere else on the breadboard. I'd start with just the VCC, RESET, and GND pins, make sure the part doesn't get hot, and then move on to connecting the rest of the circuit.

- Warren

The word continuity causes my head to make buzzy sounds! :eek:

In other words, what's continuity? (EDIT: Wow, someone explained that to me already in this very thread...the real question: How do I use the multimeter to test continuity?)

This is my multimeter:
http://www.radioshack.com/product/index.jsp?productId=2103170&tab=summary

Also, I just got a hold of a digital camera; going to take as many good shots as possible. I'll be posting them within the next hour or two.
 
  • #54
Ok, I just reconnected everything in a new place, and she is ready for her photo shoot! :smile:
 
  • #55
Twinfun2 said:
In other words, what's continuity? (EDIT: Wow, someone explained that to me already in this very thread...the real question: How do I use the multimeter to test continuity?)

Typically, you turn your multimeter's control dial to the position with a little speaker icon. Next, you touch two different spots with the probes (it doesn't matter which way 'round they are connected). If there is a very low-resistance path between the spots, the meter will beep, letting you know the two spots are electrically the same.

You want to make sure there is no direct connection between pin #3 (output) and any other pin, particularly VCC or GND.

- Warren
 
  • #56
Twinfun2 said:
How do I use the multimeter to test continuity?)

chroot said:
Typically, you turn your multimeter's control dial to the position with a little speaker icon. Next, you touch two different spots with the probes (it doesn't matter which way 'round they are connected). If there is a very low-resistance path between the spots, the meter will beep, letting you know the two spots are electrically the same.

Since the OP's http://rsk.imageg.net/graphics/uc/rsk/Support/ProductManuals/2200223_PM_EN.pdf" does not mention continuity measurement, he can just measure the resistance and look for a (nearly) zero-ohm reading to indicate that two locations are connected, or an infinite-ohm reading to indicate that they are not.
 
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  • #57
As far as I can tell, nobody has posted any schematic of a NE555 LED oscillator. So I built one in 15 minutes (in LTSpice) and turned it on. Here it is...
 

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  • #58
_______________________________________________

The Pictures: (Picture One Indicates Pin 1)

http://img265.imageshack.us/gal.php?g=oneh.jpg

For Reference:
__________

R1:10k
R2:100k
C:10uF

_______________________________________________
 
  • #59
Looks like the LED+resistor are connected between pin 4 and ground, but it should be pin 3 and ground.

Since pin 4 is tied to Vs, the LED would stay on continuously.

EDIT: that would not have caused the chip to overheat however.
 
  • #60
Redbelly98 said:
Looks like the LED+resistor are connected between pin 4 and ground, but it should be pin 3 and ground.

Since pin 4 is tied to Vs, the LED would stay on continuously.

Just fixed.

(I didn't make that mistake before, so nothing wrong there. :blushing:)

Anything else?
 
  • #61
Take another picture.

- Warren
 
  • #63
Looks good to me... Keep in mind that the horizontal stripes of holes at the top and bottom of the board do not always connect all the way across the board. Make sure that all of your VCC connections, and all of your GND connections, are continuous with your multimeter.

- Warren
 
  • #64
chroot said:
Looks good to me... Keep in mind that the horizontal stripes of holes at the top and bottom of the board do not always connect all the way across the board. Make sure that all of your VCC connections, and all of your GND connections, are continuous with your multimeter.

- Warren

Ok, I will do that, and then insert my new timer afterward.

Wish me luck guys! :biggrin:
 
  • #65
Still no dice guys...light stays on, and the timer is actually STILL getting hot. Could it simply be the breadboard? If so, I might make an attempt at soldering the circuit together instead.

Output of Pin is in this order:

Resistor, LED, Ground

Is there any connections missing? According to the schematic supplied by Bob S, there should be some extra connections that are not included in my circuit.
 
  • #66
At this point I'm at a loss. Have you gone through all the nets in the design, measuring their resistance to all other nets? It is entirely possible that your breadboard is damaged. If it is, it'll show up in those continuity tests.

- Warren
 
  • #67
Could "Rechargeable Batteries" be the culprit?

I'm just looking through every detail now...
 
  • #68
No, rechargeable batteries should not be an issue. Again, there's something going where a lot of current is flowing through your device. You should try:

1) Measuring the resistance between each net and all the others.
2) Using your multimeter to measure currents through the VCC and output pins.

The second test needs to be done with the part installed, of course, but you should be able to get a reading of the current in just a second or two.

- Warren
 
  • #70
I compared each and every node on the breadboard circuit with the ones on the schematic in the OP and they all match. I'd suspect the board at this point.
 
  • #71
What does the writing on the 555 chip actually say? Could you read it please?
 
  • #72
One last silly question: Is that electrolytic cap connected with (-) lead to ground?
 
  • #73
Still no dice guys...light stays on, and the timer is actually STILL getting hot. Could it simply be the breadboard? If so, I might make an attempt at soldering the circuit together instead.

Just reading back through the posts, I saw this one (above).
If you can get away from the breadboard approach, it would be good. You don't need printed circuit boards. I find breadboards generate more problems than anything else, usually because of poor connections.
This is a simple and extremely reliable ciircuit and it shouldn't be causing so much grief.

You turn the chip so its legs are facing upwards. (this construction method is called "dead bug construction" for this reason).
Any legs that are to be grounded are bent downwards and soldered to the PC board. Also any capacitors etc that need to be grounded are soldered in.
Power leads etc are attached to tag strips and not directly to the IC. (I use header pins cut to shape as tag strips).
This way, you can lay out a circuit as it is in a diagram and quickly see if something is wrong. It is very safe and the IC is in no danger of being pulled apart. And you can easily change a component value if you want to.


What does the writing on the 555 chip actually say? Could you read it please?

.
 
  • #74
vk6kro said:
What does the writing on the 555 chip actually say? Could you read it please?

LM393? :smile:
 
  • #75
LM393...Where did you get that?
 
  • #76
It's a joke. The 393 is also a common 8-pin PDIP part.
 
  • #77
What does the writing on the 555 chip actually say? Could you read it please?

http://www.radioshack.com/product/index.jsp?productId=2062596

Would you guys consider Radio Shack to be a distributor of quality merchandise of this sort?

One last silly question: Is that electrolytic cap connected with (-) lead to ground?

Yes.

This is a simple and extremely reliable circuit and it shouldn't be causing so much grief.

:cry:

At this point, all I there really is to blame is the breadboard, I completely agree.

During the past 3 or 4 days I have been posting here, has anyone been able to replicate my exact circuit?
 
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  • #78
Twinfun2:

I repeat: measure the resistance between all of the nodes in the circuit, with the 555 installed, but without power. There are only a handful of nodes, so this should only take a few minutes. With this information, we can hopefully positively identify your problem as a bad breadboard.

- Warren
 
  • #79
I found a very old 555CN chip and made up your circuit.
AND I got the same result as you did, but without any heating. The LED was on all the time. I checked with an oscilloscope and there was no other oscillation going on.

It will not oscillate with a 100 K resistor unless the supply is less than 4.5 volts.

To oscillate at 6 volts the 100 K resistor has to be about 10 K but no more.

So, you might like to try that. Use just 3 alkaline AA cells to get 4.5 volts or get a 10 K resistor.

A data sheet I found gives 100 K as the upper limit on this resistor.

I'm sure I have used 555s that were a lot less fussy than this one. Guess it depends on the maker. Mine was obviously ***P quality.

If the Radio Shack is convenient, you could try one of these:
http://www.radioshack.com/product/index.jsp?productId=2062595
It is the CMOS version of the 555 and should let you use any resistor you like.

I was also going to suggest you pick up a cheap digital multimeter, but not from there. Overpriced and poor features.
This is the sort of meter I was thinking of:
http://www.altronics.com.au/index.asp?area=item&id=Q1053A
that is about US$7.50

but Australia is a long way from Philadelphia.
 
  • #80
There's really nothing wrong with his meter. Nothing you're going to do at the board level is going to require more than 1% precision, so just a couple of significant figures is plenty. You can easily read a few sig figs off an analog meter. The only advantage of digital meters is that you can read them a little more quickly. They may appear to have greater precision, but their least significant figures are mostly noise anyway.

- Warren
 
  • #81
The non zero voltage readings in the following chart should have all been 5 volts. Because of the low resistance of the analog meter, much lower readings were obtained.
This was the test where the chip was removed from the socket.
1: 0v
2: 2v
3: 0v
4: 5v
5: 0v
6: 2v
7: 4.5v
8: 5v
 
  • #82
vk6kro:

The readings that were obtained have nothing to do with his meter.

The voltages on pins 2 and 6, etc. should not be 5V, and it's ridiculous of you to assert that they should have been. C1 had not been properly discharged, so it had some residual voltage on it -- nothing is driving that node.

There's nothing wrong with an analog meter -- certainly, nothing that's going to make his small 555 circuit fail to work. You're leading him down a frankly idiotic path.

I am a little concerned, though, about the voltages on pins 4 and 8 (RESET and VCC) being 5V, rather than 6V. If you're using 4 AA batteries and the voltage is sagging all the way down to 5V, you must be pulling a lot of current through them... what's the voltage of the battery pack when it's not connected to the circuit? What's the voltage when it is connected to the circuit? Are they substantially different?

- Warren
 
  • #83
The readings were taken under power from 4 AA rechargeable cells.
This means that the capacitor was fully charged and that the voltage should have been about 4.8 volts (4 times 1.2 is 4.8 volts).

So, since there was no current flowing in the resistor chain (after a 1 second charging time), the supply voltage should have been across the capacitor.
So there should have been 5 volts there.

The only thing wrong with his analog meter is that it is a low impedance device trying to measure high impedances. Better digital meters have a 10 Megohm resistance even on the low voltage ranges, but even cheap ones have 1 megohm input resistance. The error in this case was up to 60%, quite enough to lead him to the wrong conclusions.

I actually prefer an analog meter, but I wouldn't use one in this case.
 
  • #84
chroot said:
... what's the voltage of the battery pack when it's not connected to the circuit? What's the voltage when it is connected to the circuit? Are they substantially different?

Good idea to check these. Either the analog meter is somewhat off, or the unloaded battery voltages are that low, or the batteries are being drained when connected and that is pulling their voltage down.

I'll just add, try measuring the connected-battery-voltage both with and without the chip in the circuit. EDIT: but don't leave the chip in AND battery connected very long, due to the overheating chip issue.
 
  • #85
vk6kro said:
So there should have been 5 volts there.

Well, I looked through the analog meter's manual, and am very surprised to see that its input resistance, when set to the 25V scale, is only 20kohm. As you said, that's definitely low enough to cause problems here. Please accept my apologies -- I just never expected any meter to be that poor.

It does achieve 2Mohm resistance, but only on the 1000V scale...

- Warren
 
  • #86
~10-20k is a typical low-scale input impedance for basic analog meters--even the venerated Simpson 260 only had a 20k input-Z. Better ones incorporate a FET to raise the effective impedance to the low tens of MOhms.
 
  • #87
Yeah, I made the (apparently really bad) assumption that all modern meters use the same kind of sensing circuitry (FET input stage, for example), and that the only difference is the display... and I was wrong!

- Warren
 
  • #88
chroot said:
Twinfun2:

I repeat: measure the resistance between all of the nodes in the circuit, with the 555 installed, but without power. There are only a handful of nodes, so this should only take a few minutes. With this information, we can hopefully positively identify your problem as a bad breadboard.

- Warren

Roger, I will do this when I get the chance, but I am away from home again (Been a busy few weeks).

Sorry for such a late update.
 
  • #89
chroot said:
Well, I looked through the analog meter's manual, and am very surprised to see that its input resistance, when set to the 25V scale, is only 20kohm.

Wow.

Weird, I looked through the manual and could not find that info. Are you looking at something other than:
http://rsk.imageg.net/graphics/uc/rsk/Support/ProductManuals/2200223_PM_EN.pdf
?
 
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  • #90
Very last page, bottom of right column: "Specifications."

- Warren
 
  • #91
Looked there, and saw:

Ranges...Resistance: 2k, 20k, 2M (Center Scale 20 ohm)

Sensitivity...DC Voltage: 20,000 Ohm/Volt​

Don't see anything else that relates to meter impedance. But I also admit I don't understand the remarks "Center Scale 20 ohm", or what the Sensitivity spec means. Do one of those somehow indicate 20k impedance on the 25V scale?

(Unless you're saying that the list of ranges for resistance measurement relate to meter impedance somehow?)
 
  • #92
Yeah, it's pretty confusing, and I'm not sure I understand it. The highest possible resistance is 2M, though, and that clearly must be in the largest scale, 1000V. The smaller scales must have lower resistances, so... it can't be any more than 20k on whatever scale he's using.

- Warren
 
  • #93
Hmmm, I thought those numbers (2k, 20k, 2M) were just the max scale readings for doing resistance measurements. Not convinced they have anything to do with meter impedance.
 
  • #94
Multiply the sensitivity in Ohms/volt by the full scale value of the range in question to get the impedance for that range in Ohms. For example: if the meter has a 1-volt range, the impedance will be 20 k; for a 5-volt range, the impedance will be 100 k.
 
  • #95
Does it heat up if you only connect + and ground?
 
  • #96
You can calculate the resistance of the meter if you assume the readings are accurate and the capacitor is not faulty.
It comes out as 73.529 K
So, 73.529 / (73.529 + 110 ) times 5 volts = 2 volts.

Given that this meter is 20000 ohms per volt and it was probably on the 5 volt scale, it should have had a resistance of 100 K as Negitron pointed out.
This may mean that the capacitor is leaky or that the meter is inaccurate enough to give this discrepancy.

Twinfun: have a look back about a page to item 79 in this thread.
 
  • #97
ShadowPho1 said:
Does it heat up if you only connect + and ground?

That question was asked way back in the thread. Yes it does.

I most likely will wind up skipping 555 timer chip, because this is causing me way too much grief. I'm trying to learn about basic electronics for all main pieces of hardware before I start learning how to use my Picaxe starter kit (just to be safe), which really won't require a 555 timer any time soon. Is there any other IC's that would come in handy that do things that the Picaxe can't already do?

Again, thanks for all the help.

P.S. I'll still try and get those extra ratings when I get back home.
 
  • #98
The thing is--and I do understand this has been a source of frustration for you--there's something fundamentally wrong here. This is not a difficult circuit and troubleshooting should not be this complicated. I'm not intending to pick on you here nor make fun of you (lord knows I've had my hsare of head-pounding frustration only to realize the solution was blindingly obvious) but until you can get this really basic circuit working, you probably don't want to get too far into anything more complex. Perhaps you should take a step back, however, and put this on the back burner for a day or two and then tackle it again with a fresh head. You can do this! Just take your time.
 
  • #99
If the chips get hot with just the supply voltage on them, then the chips are probably faulty. You can't fix faulty chips.

Good news about the Picaxe kit. Amazing chips and a great programming language. Which one did you get?
 
  • #100
Here we are at 100 posts for the NE555. That's over 12 posts per pin on an 8-pin DIP. Wow.
 
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