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The specific setup: 12v Bilge Pump wired to a 24v solar panel with a resistor (I think).

The situation: I'm a teacher at a school and we have 2 stream tables that have historically been run with a bilge pump connected to a small solar panel. It wasn't operating for a couple years, but we just got it up and running this last week and I was left in charge of it and I have already burned up 2 motors and have no idea whats going on. One theory was because at first I had them wired straight into it, then saw a little rectangular piece that i am assuming is a resistor. Burned up 1 motor before seeing that, then started adding that to the circuit. My other theory, maybe because it's a 12v pump hooked up to a 24v panel. But to my knowledge this was always the way it was, so I would assume it used to work so it should still work. One more detail, a third (brand new) pump seemed to die today, except it runs fine when I hook it up to a car battery. But when I hook it up to the solar panel in full sun producing 23v, nothing.

So...what do I need to change about my setup to make this work? The goal is to keep it as simple as possible. One of the great parts of this is that the students are able to set it all up themselves by getting the solar panels out and just alligator clipping the wires together.
 
The output voltage of a solar panel is extremely variable, from zero to max rated volts, depending obviously on the incident light but also the connected load. The initial setup might have pulled the panel voltage down to around 12V,, but that doesn't guarantee that a different pump, or one working against a different head of water, would do the same. You didn't mention what the voltage was at the motor when running so it's hard to know exactly what occurred.

What is needed is a regulator, to ensure the pump receives a defined voltage. Most practical DC applications of solar power require one. Match the size of the regulator to the maximum wattage output of the panel. You don't technically have to use one intended for solar applications but doing so would give you predictable results. Many are intended for battery charging and are called charge controllers, but the principle is the same. They used to be just shunt regulators that dumped the excess power, but now they are PWM voltage converters that step down whatever voltage the panel is producing to what the user wants.

To know why the pump will not now work from the panel, we need to know what the voltage is at the motor terminals when connected. If the panel has developed a high internal resistance, it might read 23V off-load but the voltage collapses when the pump is connected. Most likely, the panel is now dead.

Small DC bilge pumps are not known for very long service lives. They are designed to run for a few minutes at a time, once an hour, not really all the sunny hours of the day. So I don't know how long I would expect it to last overall even at 12V. The AC motors used in line-powered fountain pumps do not have brushes and do not wear so fast. There are now brushless versions but only from obscure brands so I don't think they are likely to outlast a decent Rule or Jabsco pump. Finally, don't forget that dry-running can destroy a submersible bilge pump in minutes.
 
The output voltage of a solar panel is extremely variable, from zero to max rated volts, depending obviously on the incident light but also the connected load. The initial setup might have pulled the panel voltage down to around 12V,, but that doesn't guarantee that a different pump, or one working against a different head of water, would do the same. You didn't mention what the voltage was at the motor when running so it's hard to know exactly what occurred.

What is needed is a regulator, to ensure the pump receives a defined voltage. Most practical DC applications of solar power require one. Match the size of the regulator to the maximum wattage output of the panel. You don't technically have to use one intended for solar applications but doing so would give you predictable results. Many are intended for battery charging and are called charge controllers, but the principle is the same. They used to be just shunt regulators that dumped the excess power, but now they are PWM voltage converters that step down whatever voltage the panel is producing to what the user wants.

To know why the pump will not now work from the panel, we need to know what the voltage is at the motor terminals when connected. If the panel has developed a high internal resistance, it might read 23V off-load but the voltage collapses when the pump is connected. Most likely, the panel is now dead.

Small DC bilge pumps are not known for very long service lives. They are designed to run for a few minutes at a time, once an hour, not really all the sunny hours of the day. So I don't know how long I would expect it to last overall even at 12V. The AC motors used in line-powered fountain pumps do not have brushes and do not wear so fast. There are now brushless versions but only from obscure brands so I don't think they are likely to outlast a decent Rule or Jabsco pump. Finally, don't forget that dry-running can destroy a submersible bilge pump in minutes.
Thanks for the reply. I played around some more this morning and lets see if any of this helps narrow anything down.

I'm using Rule 12V 360GPH pumps. No idea how reliable these are. I also have 2 solar panels, so I can test between the 2 of them.

Like I said, with no load they produce 23-24v. When I hook up the motor mentioned above, they go down to 1 (tested on both panels). I also have a few brand new motors, so I tested one and it works. Voltage under that load was 6-7.

Is this drop showing that the panels are both dead?

So for now I can just hook up new motors and get everything running again, but if something needs to change to keep me from burning up motors, I want to change it before wasting another motor.
 
It sounds like the pumps are drawing a larger current than the solar panels can produce.
what rating are the panels? If known, if not, what size are they for a rough estimate.
 
So do I understand that the old pump works OK on a car battery but drags the solar panel down to 1V, but the new pump pulls the solar panel to 7V and runs fast enough for your application? Are you testing them under the same conditions?

Try each pump on the battery and measure the current draw, under identical conditions. The head of water the pump is lifting against affects the current, which affects the voltage on the solar panel although not the car battery. The less backpressure on the pump usually the more current it will draw (due to higher flow rate and therefore higher torque). A pump sitting in a bucket of water with no hose connected to the outlet would pull the solar panel voltage down lower than one plumbed in and lifting a column of water, but clearly not down to the point where it doesn't run.

As for what is causing damage, is it possible that the pump under load holds the solar voltage at 7V, but when left unattended, sometimes it's not properly submerged in water so it occasionally runs dry and the loss of pumping load causes the voltage to shoot up. Then it's a double whammy, too high a voltage and running dry at the same time, which rapidly kills the motor.
 
It sounds like the pumps are drawing a larger current than the solar panels can produce.
what rating are the panels? If known, if not, what size are they for a rough estimate.
Ok. Now that I read everything and understand a little more, they are not 24v panels. I was reading the VOC thinking that was the same. The VMPP is 17.5 and they are advertised as 12v panels. Max power is 30watt. Here is a link to the panels
So do I understand that the old pump works OK on a car battery but drags the solar panel down to 1V, but the new pump pulls the solar panel to 7V and runs fast enough for your application? Are you testing them under the same conditions?

Try each pump on the battery and measure the current draw, under identical conditions. The head of water the pump is lifting against affects the current, which affects the voltage on the solar panel although not the car battery. The less backpressure on the pump usually the more current it will draw (due to higher flow rate and therefore higher torque). A pump sitting in a bucket of water with no hose connected to the outlet would pull the solar panel voltage down lower than one plumbed in and lifting a column of water, but clearly not down to the point where it doesn't run.

As for what is causing damage, is it possible that the pump under load holds the solar voltage at 7V, but when left unattended, sometimes it's not properly submerged in water so it occasionally runs dry and the loss of pumping load causes the voltage to shoot up. Then it's a double whammy, too high a voltage and running dry at the same time, which rapidly kills the motor.
Yes you understand correct and that the old pump worked ok on a car battery but pulled the panel down to 1v and did not pump. I only connected it to the car battery for a fraction of a second though because I was just doing a quick dry test and didnt want to run it dry. So I did not test the voltage when this was happening. I'll have to try your test you mentioned a little later and see what it does.

But...the test done that dropped the voltage to 7v was done in a bucket of water without any hose attached (like you mentioned). If I'm understanding correct, it makes sense in this case for the voltage to drop lower (is 6-7 within a "normal" range).

But you mentioned what might be causing damage. I could see this being the case. The hope is students connect them during recess, then disconnect at the end of recess. But they are elementary students, wouldn't be surprising if this gets forgotten and they run for the 2 hours between recesses. They "shouldn't" go dry because water should always be circulating, but its still possible that it happens.
 
Ok. Now that I read everything and understand a little more, they are not 24v panels. I was reading the VOC thinking that was the same. The VMPP is 17.5 and they are advertised as 12v panels. Max power is 30watt. Here is a link to the panels

Yes you understand correct and that the old pump worked ok on a car battery but pulled the panel down to 1v and did not pump. I only connected it to the car battery for a fraction of a second though because I was just doing a quick dry test and didnt want to run it dry. So I did not test the voltage when this was happening. I'll have to try your test you mentioned a little later and see what it does.

But...the test done that dropped the voltage to 7v was done in a bucket of water without any hose attached (like you mentioned). If I'm understanding correct, it makes sense in this case for the voltage to drop lower (is 6-7 within a "normal" range).

But you mentioned what might be causing damage. I could see this being the case. The hope is students connect them during recess, then disconnect at the end of recess. But they are elementary students, wouldn't be surprising if this gets forgotten and they run for the 2 hours between recesses. They "shouldn't" go dry because water should always be circulating, but its still possible that it happens.
Why not just use the panel/s to charge the battery via a charge controller, which would be the normal way to do things.
 
Why not just use the panel/s to charge the battery via a charge controller, which would be the normal way to do things.
Couple reasons. First, we don't currently have batteries, so saving the money (although you could argue I might end up spending more if I keep burning up motors). But also trying to keep it super simple. Our campus is a shared space, so we have to put the solar panels (and if we had batteries, those too) away every day. And it's all led by 4th graders. So getting a battery out every day and hooking it up just adds complication. But we also use this set up to reinforce our teachings on solar energy so that they can actually see solar working. Stand in front of the panel and it stops working, move away and it works again.
 
So do I understand that the old pump works OK on a car battery but drags the solar panel down to 1V, but the new pump pulls the solar panel to 7V and runs fast enough for your application? Are you testing them under the same conditions?

Try each pump on the battery and measure the current draw, under identical conditions. The head of water the pump is lifting against affects the current, which affects the voltage on the solar panel although not the car battery. The less backpressure on the pump usually the more current it will draw (due to higher flow rate and therefore higher torque). A pump sitting in a bucket of water with no hose connected to the outlet would pull the solar panel voltage down lower than one plumbed in and lifting a column of water, but clearly not down to the point where it doesn't run.

As for what is causing damage, is it possible that the pump under load holds the solar voltage at 7V, but when left unattended, sometimes it's not properly submerged in water so it occasionally runs dry and the loss of pumping load causes the voltage to shoot up. Then it's a double whammy, too high a voltage and running dry at the same time, which rapidly kills the motor.
Ok. Did the test on the car battery. 12.6 no load. When I touch the pump a momentary jump to 12.7, then sits back at 12.6. Both pumps exactly the same except the "old" pump is noticeably louder.
 
Couple reasons. First, we don't currently have batteries, so saving the money (although you could argue I might end up spending more if I keep burning up motors). But also trying to keep it super simple. Our campus is a shared space, so we have to put the solar panels (and if we had batteries, those too) away every day. And it's all led by 4th graders. So getting a battery out every day and hooking it up just adds complication. But we also use this set up to reinforce our teachings on solar energy so that they can actually see solar working. Stand in front of the panel and it stops working, move away and it works again.
Without a voltage/current regulator, the setup will never work correctly with max sun on the panels the voltage is going to be around 17v driving a 12v motor which is then going to draw a lot of current.
When there is less sun, the motor may not even start at all

If there isn't enough current, then you could try two panels via a regulator to drive the pump.
 
Ok. Did the test on the car battery. 12.6 no load. When I touch the pump a momentary jump to 12.7

Ah, it was the current that we were looking for, not the voltage. That won't change significantly on a car battery due to its low internal resistance. But the current will tell whether the old motor is damaged and therefore explain why it doesn't now work on the panel. If it takes more current under the same conditions, there are probably shorted turns on the armature or the commutator is damaged. That would tend to confirm that it has been overrun.
 
Ah, it was the current that we were looking for, not the voltage. That won't change significantly on a car battery due to its low internal resistance. But the current will tell whether the old motor is damaged and therefore explain why it doesn't now work on the panel. If it takes more current under the same conditions, there are probably shorted turns on the armature or the commutator is damaged. That would tend to confirm that it has been overrun.
Ah, that makes sense. Unfortunately my multimeter is fused at 200MA. So I can't really test current until I can get to the store.

But after testing and doing my limited thinking it got me wondering about the solar panels. First, they are only 30W. Looking at the motors, they are 12V 2.1A. So it needs 25.2 watts at max flow. It also supposed to be fused at 4A. Does this means it could draw 48W at times?

Also, I'm not sure how old these panels are. So maybe they just aren't producing as much.

Is there a way to test the panels to see how much they are still producing?

And would this be why the voltage drops to 7 when under the load of the pump?

Lastly, could running the pumps at the lower voltage damage them?
 
Ah, that makes sense. Unfortunately my multimeter is fused at 200MA. So I can't really test current until I can get to the store.

But after testing and doing my limited thinking it got me wondering about the solar panels. First, they are only 30W. Looking at the motors, they are 12V 2.1A. So it needs 25.2 watts at max flow. It also supposed to be fused at 4A. Does this means it could draw 48W at times?

Also, I'm not sure how old these panels are. So maybe they just aren't producing as much.

Is there a way to test the panels to see how much they are still producing?

And would this be why the voltage drops to 7 when under the load of the pump?

Lastly, could running the pumps at the lower voltage damage them?
If the motors aren't run at the rated voltage, give or take a few volts, then they are liable to get damaged.
Like Lucien said, you need to be able to measure the voltage and current to determine what's going on.
 
Marine and automotive electrical systems using a 12V battery operate at up to 14.2 - 14.4V when the engine is running, as this is the voltage required to charge the battery, Components such as motors are made to withstand this voltage. Conversely, when the engine is stopped and the battery partially discharged, giving say 11.5V, devices must still be able to operate even allowing for some voltage drop in the wiring. So most will still function, although not perhaps at nameplate performance, at 10-10.5V.

Lastly, could running the pumps at the lower voltage damage them?

Because the mechanical power absorbed by a centrifugal pump varies dramatically with speed, as the voltage (and hence speed) is reduced, the load on the motor reduces so much that the motor can continue to rotate down to quite a low voltage at which point the pump will deliver hardly any head or flow. The motor will not be harmed by this, so long as it keeps rotating.

There is a slight possibility of damage if the voltage is just low enough that the motor stalls. Then, the current (albeit much reduced) will flow through one spot on the commutator and one coil, and if the brush contact isn't ideal at that exact spot, might erode the commutator segment by arcing. Unlikely, because the current will be low, but outside the intended operation conditions of any normal small brush motor.

Note that the above is not true of all types of motor and load. There are situations in which reduced voltage can lead to overheating even while the motor is still doing its job.

Looking at the motors, they are 12V 2.1A. So it needs 25.2 watts at max flow. It also supposed to be fused at 4A. Does this means it could draw 48W at times?

Momentarily when starting from a standstill, if connected to a source of constant voltage and negligible resistance. A stationary motor generates no back-EMF, so the starting current will be the supply voltage divided by the winding resistance, usually many times higher than rated current. A large industrial DC motor cannot simply be switched on to the supply, it must be started through a resistance. A tiny motor like this has enough resistance of its own to be switched directly on to full voltage, but it will take a surge of current hence the need to provide a larger fuse. In fact the starting current is probably more than 4A but very brief. The manufacturer has probably proven through extensive testing that the specified 4A fuse represents a good compromise, being small enough to blow and prevent the motor catching fire if mechanically jammed, but large enough to avoid nuisance failures through repeated thermal cycling each time the pump starts.

With the solar panel, the maximum current will be limited so the motor will never achieve that sudden peak power consumption. Again thanks to the minimal power extracted by a centrifugal pump at low speed, it will still start on the panel's limited output, but just take a second longer to spin up. The same is not true of say an elevator motor, that must start from standstill with a deadweight torque that it must overcome before it can begin to accelerate, so it cannot ramp up from zero current.

To fully understand the behaviour, one needs to see the pump's torque/speed curves for various heads, and the solar panel's output curves, and crank them through some relatively complex mathematics. You would do that for a large solar-powered irrigation scheme but it's a bit far-fetched for a 360GPH bilge pump.
 
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Marine and automotive electrical systems using a 12V battery operate at up to 14.2 - 14.4V when the engine is running, as this is the voltage required to charge the battery, Components such as motors are made to withstand this voltage. Conversely, when the engine is stopped and the battery partially discharged, giving say 11.5V, devices must still be able to operate even allowing for some voltage drop in the wiring. So most will still function, although not perhaps at nameplate performance, at 10-10.5V.



Because the mechanical power absorbed by a centrifugal pump varies dramatically with speed, as the voltage (and hence speed) is reduced, the load on the motor reduces so much that the motor can continue to rotate down to quite a low voltage at which point the pump will deliver hardly any head or flow. The motor will not be harmed by this, so long as it keeps rotating.

There is a slight possibility of damage if the voltage is just low enough that the motor stalls. Then, the current (albeit much reduced) will flow through one spot on the commutator and one coil, and if the brush contact isn't ideal at that exact spot, might erode the commutator segment by arcing. Unlikely, because the current will be low, but outside the intended operation conditions of any normal small brush motor.

Note that the above is not true of all types of motor and load. There are situations in which reduced voltage can lead to overheating even while the motor is still doing its job.



Momentarily when starting from a standstill, if connected to a source of constant voltage and negligible resistance. A stationary motor generates no back-EMF, so the starting current will be the supply voltage divided by the winding resistance, usually many times higher than rated current. A large industrial DC motor cannot simply be switched on to the supply, it must be started through a resistance. A tiny motor like this has enough resistance of its own to be switched directly on to full voltage, but it will take a surge of current hence the need to provide a larger fuse. In fact the starting current is probably more than 4A but very brief. The manufacturer has probably proven through extensive testing that the specified 4A fuse represents a good compromise, being small enough to blow and prevent the motor catching fire if mechanically jammed, but large enough to avoid nuisance failures through repeated thermal cycling each time the pump starts.

With the solar panel, the maximum current will be limited so the motor will never achieve that sudden peak power consumption. Again thanks to the minimal power extracted by a centrifugal pump at low speed, it will still start on the panel's limited output, but just take a second longer to spin up. The same is not true of say an elevator motor, that must start from standstill with a deadweight torque that it must overcome before it can begin to accelerate, so it cannot ramp up from zero current.

To fully understand the behaviour, one needs to see the pump's torque/speed curves for various heads, and the solar panel's output curves, and crank them through some relatively complex mathematics. You would do that for a large solar-powered irrigation scheme but it's a bit far-fetched for a 360GPH bilge pump.
Thanks so much for the detailed response. This whole process has now turned into both getting everything up and running in a way that lasts, but also an opportunity to learn something new. So I appreciate it.

To sum up, seems like you are saying that the lower voltage is unlikely a problem. And would not be the cause of burning up 3 pumps in a week.

And I could also do some very in depth tests, but these seem silly for a $30 motor. Would this also be to figure out why it's pulling the voltage down to 7 volts? Or does that seem normal? That is a question that I'm still trying to figure out.

The other issue that hadn't been mention and I didn't think a lot about is sand getting in the motor and jamming it up. I'm assuming this could also kill the motor. Or...is the effect of this fire and not burning the motor up?

So my plan is to make a plan so the pump stays under water but away from the sand to hopefully keep from killing motors.

BUT...its also made me curious about if these solar panels have run their course and I need to get new ones. How can I test the panel and how well it is operating?
 
Thanks so much for the detailed response. This whole process has now turned into both getting everything up and running in a way that lasts, but also an opportunity to learn something new. So I appreciate it.

To sum up, seems like you are saying that the lower voltage is unlikely a problem. And would not be the cause of burning up 3 pumps in a week.

And I could also do some very in depth tests, but these seem silly for a $30 motor. Would this also be to figure out why it's pulling the voltage down to 7 volts? Or does that seem normal? That is a question that I'm still trying to figure out.

The other issue that hadn't been mention and I didn't think a lot about is sand getting in the motor and jamming it up. I'm assuming this could also kill the motor. Or...is the effect of this fire and not burning the motor up?

So my plan is to make a plan so the pump stays under water but away from the sand to hopefully keep from killing motors.

BUT...its also made me curious about if these solar panels have run their course and I need to get new ones. How can I test the panel and how well it is operating?
Jamming or stalling the motor will cause damage.

Ideally you need a variable power supply, variable load along with current and volt meter to give you the current /voltage curve of the panel and the motor.

The problem you have is the solar panels vary in output by quite a large margin depending on the amount of light.
Driving a motor directly from a solar panel isn't ideal.

There are lots of solar pumps for sale.


Alternatively, you could always drive something else other than a motor directly.
 
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Jamming or stalling the motor will cause damage.

Ideally you need a variable power supply, variable load along with current and volt meter to give you the current /voltage curve of the panel and the motor.

The problem you have is the solar panels vary in output by quite a large margin depending on the amount of light.
Driving a motor directly from a solar panel isn't ideal.

There are lots of solar pumps for sale.

Alternatively, you could always drive something else other than a motor directly.
I hadn't considered a pump like these that are marketed for fountains, but do the same thing. Definitely something to consider. Brings up the question, what makes these different than the setup I am running? Is it just that these have a voltage regulator?

We just got a regulator, so I'm wondering if this will make our setup the same as these solar fountain pumps? If so, don't want to invest in a whole new setup.
 
I hadn't considered a pump like these that are marketed for fountains, but do the same thing. Definitely something to consider. Brings up the question, what makes these different than the setup I am running? Is it just that these have a voltage regulator?

We just got a regulator, so I'm wondering if this will make our setup the same as these solar fountain pumps? If so, don't want to invest in a whole new setup.

The problem you have is the matching of the motor to the solar panel, the panel has to produce above 12v (assuming it's a 12v regulator) to be able to even run the motor.

I doubt that there is any regulation as such in those fountain ones, but the solar panels would be matched with the motors and would have some sort of current limiting.
 
The problem you have is the matching of the motor to the solar panel, the panel has to produce above 12v (assuming it's a 12v regulator) to be able to even run the motor.

I doubt that there is any regulation as such in those fountain ones, but the solar panels would be matched with the motors and would have some sort of current limiting.
I'm not fully understanding. The panel is a 12v panel, and has enough wattage to run this pump. Is there something else to also look at for matching them? Or is the panel just dying? If so, is there more to look at than voltage and wattage when purchasing a new one?
 
A '12V panel' indicates that is suitable for charging the battery of a 12V system; not that it will typically output 12V by itself. In a conventional DC power system, the voltage is defined by the battery and everything has to revolve around charging it at the correct rate, not overcharging etc. This requires all sorts of control and regulation mechanisms in alternators, chargers and solar controllers, but ultimately it is the battery that defines the voltage. When the panel is used without either battery or regulator, it will produce all sorts of voltages, from 23 or whatever open-circuit in bright sun, down to near zero when overloaded relative to whatever power is available at that level of illumination.

The pump would normally be used in a system with a voltage defined by a 12V battery, hence is compatible any voltage within the battery's working range say 10-14V. Behaviour and survival outside that range is not specified or guaranteed. It is not expected to work with supplies of high internal resistance, such as a panel without the benefit of a battery to 'buffer' it, because the voltage will vary widely with changes in load.

A suitably matched panel and pump might nevertheless behave in a reasonable manner, with the voltage never going so high as to cause damage. That might be what is inside cheaper ready-made solar fountains, where the manufacturer has chosen specific motors and solar cells to work correctly together. OTOH, basic PWM regulators are cheap enough to build into most products. They will probably have tried ten different panels and ten different motors and matched them to get the best bang for buck and most reliable operation. Otherwise, there is no telling what might happen to the voltage, absent the battery and regulator.
 

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