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Another Interesting Circuit from Burt's Design Pad

NE555 Low Voltage Battery Disconnect

Circuit

 Note: There have been some changes since this document was first published. Please notethe latest update before constructing the circuit.

R ecently in a repeaters owner's discussion group (repeater@repeater.net) reference was

made to a "low voltage disconnect circuit" that appeared in QST Nov 93. I made the rashcomment that the aforementioned circuit was overly complex and that one could achievethe same ends with a single NE555 IC and a dozen passive components. I wasimmediately challenged to show this simplified circuit. The following is the result. It doeshave a few more than a dozen passive parts but still makes a much simpler circuit than theQST article. I hope that it is useful to some folks.

Long Live KISS Design

• Basic Design

• Detailed Design

• Options

o Remote Reset Option

o Reset Option Parts List

o Alternate NPN Relay Drivers

o Reducing Relay Holding Current

o High Side Solid State Switches

o High Side Switch Parts List

• Relay Selection

• Construction

• Calibration

•

Parts List• PC Board Patterns

Basic Design

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Basic Low Voltage Detector Circuit

The ubiquitous NE555 "Timer" IC is a very versatile chip. It contains two voltagecomparators with an internal reference, an R-S FlipFlop and a "totem-pole" type outputcircuit capable of sourcing or sinking up to 200 ma. All of these subcircuits are used to

advantage in this battery disconnect circuit.

Basically a 555 works as follows:

• When the voltage on pin 2 is less than 1/3 of the IC's supply voltage (Vcc), the RSFF is set and the output (pin 3) goes high (almost up to Vcc).

• When the voltage on pin 6 is more than 2/3rds of the supply voltage, the RS FF isreset and the output pin goes low (grounded to the negative supply line).

A pot is connected across the battery to be monitored with the wiper to pin 2 and adjusted

so that the voltage on pin 2 equals 1/3 Vcc when the battery is at the desired low voltagedisconnect point. When the battery voltage goes below this setpoint, the output voltage on pin 3 will go high.

Another pot is connected across the battery with its wiper to pin 6. It is adjusted so thatthe voltage on pin 6 is equal to 2/3rds of Vcc when the battery voltage is at the desired"turn-on" setpoint. When the battery exceeds this setpoint, the output pin will go low.

All that is left to enable the disconnect circuit is a relay driver that will turn on the relaywhen the 555 output is low and release it when the output is high.

 

Detailed Circuit

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Low Voltage Disconnect Circuit Schematic

The detailed circuit has some refinements on the basic that make for easier adjustmentand more stable operation.

U1 (NE555) needs a regulated supply voltage to supply the internal voltage divider references that control the input voltage comparators connected to pins 2 and 6. VR1, a7.5v 1W zener diode along with R9 dropping resistor is simple and cheap. R9 resistanceis chosen so that the zener voltage will be maintained down to about 10v input supply or 

 below. C3 filters the regulated voltage. Should the supply voltage be reversed, the zener diode will clamp the voltage at -0.7v.

The monitored battery voltage input is fed to two voltage dividers, R1, R2 and R3 for theOFF adjustment and R4, R5 and R6 for the ON adjustment. The fixed resistors are chosenso that the pots cover the expected adjustment range (2-3 volts for R2 and 4-6 volts for R5) and make the adjustment easier.

R7 and C1 provide some time delay for the ON adjustment when the monitored voltageabruptly changes. Similarly R8 and C2 provide a time delay for the OFF setpoint for abrupt changes in the monitored voltage. These components have little effect on gradualchanges in the monitored voltage but the time delay from abrupt changes depends on theamount of change and how far below the OFF setpoint the lower voltage is. The OFF timedelay is about 5 times the ON delay. Since any leakage current in capacitors C1 and C2will upset the setpoints, they are chosen for minimum leakage.

C1 and C2 capacitors in the time delay circuit also serve another purpose. Conventionallythese capacitors would be connected to ground but by connecting them between the inputand VCC (U1 regulated supply voltage) the time delay effect is the same and there is anadded bonus. When the circuit is powered up, pins 2 and 6 will be forced high

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momentarily by the charging of C1 and C2 capacitors. This guarantees that the circuit will power up in the "ON" position which is essential for proper operation. If the capacitorswere connected to ground, it would power up in the OFF position which would be veryundesirable.

U1 pin 5 is connected to one of the internal reference voltage divider taps and C4 filtersthis point to reduce effects of noise on the power supply. Test point TP1 provides areference voltage for calibration purposes that can be compared to TP2 (adjust ON Adj sothat TP2=TP1) and TP3 (adjust OFF Adj so that TP3=0.5 x TP1).

U1 output pin 3 will have a low voltage when the circuit is "ON" and a high (near VCC)when it has tripped off. Q1 inverts this action so that the "ON" state is high. Q1 and R11also level shifts the high voltage state to the 10-14 volt supply level rather than theregulated VCC. This reduces the current required from the regulated supply.

CR1 is a protection diode to prevent excessive current flow through the MosFET relay

driver if the battery voltage should be reversed.

Q2 is the relay driver. An N-channel power MosFET is the best for this purpose since itrequires no current to turn on (only voltage) and can switch considerable power at modestcost. There are alternative relay drivers using NPN single and darlington pair transistorsshown below as options. It is also possible to use P-Channel MosFETs as direct "highside switches" in place of the relays. However relays will have the lowest voltage drop(virtually zero) whereas MosFETs have an inherent series resistance R DS that willcombine with the current to give a very significant voltage drop. For more details, see theHigh Side options below.

CR2 protects the circuitry from the reverse spikes that relays generate when they turn off.The relay K1 must be chosen with several factors in mind. You want minimum coilcurrent to conserve power but the relay contacts must be able to handle more than themaximum current that your equipment will draw from the batteries. See "Relay Selection" 

 below. A simple modification to the relay can substantially reduce the current required tohold the relay closed.

A high resolution GIF image of the schematic can be viewed but it may not show or printtoo well on most browsers. I would recommend that you save it as a file and load it into a

 bitmap viewer such as PaintShop and print it out from there.

 

Relay Selection

The relay used with this circuit must be chosen with care. On one hand, it must be able tohandle the "worse case" current drain expected from the battery. On the other hand, thecoil of a large relay generally draws a lot of current and during power outages when the

 battery is the only source available, the relay can drain the battery all by itself. Evenmodest relay current can be significant. For example, a relay with a 100 ohm coil willdraw 120 ma at 12 volts. Over the space of 24 hours, this will result in a loss of 3 Amp

Hour.

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A relay that I have found useful for high current is the Potter & Brumfield VF7 series(12v unit p/n = VF7-11F11) with a 70 Amp contact rating and a coil resistance of 72ohms.

See also the optional relay current reduction circuit below as another way to control relay

coil losses.

Don W6OA, Joe K1IKE, Hank N1LTV and possibly others, suggested that a solid statedevice such as a P-Channel Power MosFET could be used as a relay replacement. Thatoption is discussed below.

 

Options

There are several options that can be used with the LV Disconnect circuit.

  ********* 

Remote Set/Reset Control

Optional Remote Set/Reset Control Circuit for LV Disconnect

This optional set/reset circuit allows the circuit to be tripped or reset remotely bygrounding one of two input pins. This could be useful, for example, on a remote repeater site where there is an alternate control method such as a phone line or a low power control

receiver with its own battery. A control signal could reset the disconnect long enough toget a telemetry readout or trip the disconnect even when the battery is still useful in order 

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to save power. I am sure that many more uses for this option can be dreamed up byresourceful users.

 

********* 

NPN Bipolar Relay Drivers

Here are two alternate relay driver circuits using bipolar transistors instead of the power MosFET. I have not checked them out in practice but they should work with the resistor 

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values shown. The 2N2222A should be limited to 350 ma drive current and the darlingtonto 1 amp maximum.

:

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Reducing Relay Holding Current

The choice of a suitable relay is difficult. The current needed by the relay can seriouslydischarge the battery if not chosen with care. Most relays, once they pull in, will hold inwith typically 10-25% of their nominal rated voltage. This little circuit will apply fullvoltage to the relay for long enough to pull it in and then the current will drop to a value

 just sufficient to hold it in under worse case conditions. The resistor value may have to beexperimented with for optimum operation. This should reduce the relay current by 2/3rdsor more. The disadvantage is that the relay will not pickup again if it is mechanically

opened (such as from a severe mechanical shock or vibration) with the power on. In order to pickup again, the power to it must be cycled. Mechanical dropout would be quite rare(except with human intervention) so this circuit is quite reliable.

 

********* 

Solid State High Side Switches

 Note: A "High Side Switch" is a switch that interrupts power on the positive side of the power supply. Compare this with an NPN transistor or N-Channel MosFET that wouldcontrol the power on the negative lead by grounding the negative lead of the equipment(the relay driver in the above circuit is such an example). That would be a low sideswitch. Most 12 volt equipment that we encounter is already negative grounded and a"high side switch" is necessary to switch its power on or off. This distinction applies onlyto solid state switches where the current can only flow in one direction. Relays do nothave this limitation.

Several people including Don W6OA, Joe K1IKE, and Hank N1LTV have suggested thata solid state relay could replace the mechanical relay. This possibility has some notableadvantages such as very low actuation current (zero in the case of MosFETs). However 

all solid state devices have voltage drop either 0.3-0.4 volt in the case of fully saturated bipolar transistors or I x R DS in the case of MosFETs. Since many units designed for 12

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volt operation cease working or work in an undesired manner (radios that lose frequencycontrol or generate spurious emissions) when the voltage drops too low (say below 11volts), the problem of voltage drop in the relay must be very carefully considered. For example, if we consider that the radio should not have less than 11.0 volts applied to itduring transmit, the drop in the transistors and wiring could easily exceed 0.5 volt. The

 battery then should not be allowed to drop below 11.5 volts. But at 11.5v terminal voltageon a lead acid battery, a considerable capacity (30% or more) still remains in the batterythat will be wasted.

Personally I consider that 0.2 volts should be the maximum drop in any "relay" circuit.0.1 volt drop would be better. That rules out bipolar transistors. Besides bipolar transistors would need a continuous base current that would be much more than the coilcurrent in an equivalently rated relay. What is left? Power MosFETs such as those made

 by International Rectifier (IR HexFETs) and Motorola (TMOS FETs). The keyspecification that you must look for is the Drain-to-Source Resistance R DS. This value canvary widely depending on manufacturer, current and voltage rating, and type (N or P-

Channel) of MosFET. For example, the R DS of an N- Channel 2 amp device might be 2-4ohms whereas a 40 amp device may be as low as .028 ohms. Generally a P-Channeldevice will have at least twice the resistance of an N-Channel device of the same ratings.Unfortunately from the voltage drop angle, a P-Channel device is necessary for a highside switch.

In order to keep the voltage drop low when using P-Channel MosFETs as a high sideswitch, we have to choose a high current device but only pass low current through it. Anumber of identical devices connected in parallel would handle higher current. MosFETsare inherently stable when connected in parallel so this configuration should have nosurprises. An IRF9540 is rated at 18A and has a R DS of 0.2 ohm so we could not passmore than 1 amp each in order to keep below 0.2v drop. For 10A, we would need 10devices in parallel. Not too practical.

Again hams to the rescue. Hank, N1LTV, pointed out that International Rectifier has a P-Channel device with a very low R DS. The IRF4905 is rated at 50v 64A continuous maxwith a R DS of 0.02 ohm. I had not noticed it in my catalogue and databooks. It is packagedin a TO-220 package and should cost about $6US in small quantities. Since each devicewould handle 5-10A and still have a drop below 0.2v, 10 units in parallel would handle50- 100Amp at a cost of $60 for the devices. Not cheap, but practical if your aim is toswitch high current without wasting continuous current in relay coils. That is the key, a

relay coil draws current continuously, many amp hours a day. This solid state switchwould have no current draw continuously and would only lose power as heat (I 2 x R DS)when current is drawn. As you would be drawing only a very small current in eachdevice, the heat sinking requirements would be trivial (0.5W for 5A draw or 2W for 10Afor each device).

A suggested high side relay circuit using the IRF4905 P-Channel MosFET is shown below. I have not yet checked it out, so if anyone wants to try it, you are on your own.One unknown is the effect on the MosFETs if the supply voltage should be reversed or if the equipment side of the FETs is at a higher voltage than the battery. I will probablyorder up a quantity of the IRF4905 parts and try them out on a simple circuit board if time

 permits. Stay tuned for info - but don't hold your breath - blue does not become you :-)

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P-Channel MosFET High Side Switch Circuit

 

Construction

This circuit is simple enough that it can be constructed on a perf board. However a printedcircuit board is more convenient and neater. A PCB design is shown below.

The components are mostly non-critical and informed substitutions should not be a problem. So far, the only components that I have found to be critical are C1 and C2.These capacitors must have low leakage to avoid affecting the calibration set- points. Ihave found that tantalum capacitors will be generally suitable but most of the aluminumelectrolytic capacitors that I have tried were too leaky. All the tantalum capacitors I tested

were better than the best aluminum electrolytic. Sealed axial lead tantalums were the best but dipped (teardrop style) tantalums were also quite good.

There is a simple test you can use to determine if the capacitors you will be using aresuitable. Using a high impedance voltmeter (like 11 Meg input impedance typical of VTVMs and digital voltmeters), you connect the capacitor in series with the voltmeter and a 12 volt battery (capacitor + to battery +). Momentarily short the leads of thevoltmeter together (this charges the cap quickly) and then allow the reading to stabilize (itmay take several minutes). If the reading is less than 0.5v, the capacitor will be excellentfor the job. If the voltage is above 1.0v, there is too much leakage for this circuitapplication. You can do a final check if the capacitors you are using are suitable during

the calibration stage.

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Although terminal blocks are specified for the input and output connections, you can alsouse solder posts like Vector T-28 (you would have to redrill the holes to 1/16 in dia) or simply wires soldered into the terminal holes. The board is drilled for terminal blocks thatare 0.2in (5.08 mm) spacing but 5.00 mm terminals will also fit with no problems. Therelay connections (TB2) are also drilled for 3/8 in spaced terminal blocks if you have

them.

Since the voltage comparator circuit inputs are high impedance, any leakage from these pins on the IC will cause problems with the calibration set-points. The effect of leakycapacitors C1 and C2 on this problem is discussed above and is verified duringcalibration. This factor is especially important if the circuit is to be used in anuncontrolled environment where moisture could condense on the board during use. Toavoid these problems, the board should be thoroughly cleaned after assembly and testingand then coated on both sides with a thick coating of acrylic lacquer or other suitableinsulating material. For PC board cleaning hints, see my document on the subject.

 

Calibration

Calibration of this Low Voltage Disconnect circuit is quite simple. You will need avariable power supply that covers both set-point voltages, an accurate high impedancevoltmeter preferably digital and a small screwdriver.

• Hook up a relay to the relay terminals TB2.• Connect TB1 pin 4 to the positive terminal of the power supply.

• Connect TB1 pin 3 to the positive terminal of the power supply with another wire.• Connect TB1 pin 1 to the negative terminal of the power supply.• Turn on the power supply and adjust its voltage to the desired "Turn-On" voltage.

This could be 12.0v or higher depending on how you intend to use the circuit.• Using the voltmeter, measure the voltage at TP1. It should be approximately 5v.• Adjust the trimpot R5 (ON Adj) so that the voltage at TP2 is exactly the same as

at TP1.• Readjust the power supply to the desired "Turn-Off" voltage. This is usually 10.5

volt for lead acid batteries although you may wish to set it to another voltage for your application. Pause a couple of moments for the circuit to stabilize.

• Again measure the voltage at TP1 and calculate one half of its value.• Adjust the trimpot R2 (OFF Adj) so that the voltage at TP3 is exactly one half of 

the voltage at TP1.

The following checks that the electrolytic capacitors C1 and C2 have a suitably lowleakage current so that the set points are not affected.

• Measure and note the voltage at TP2.• Quickly measure and note the voltage at U1 pin 6. Quick readings are necessary

as the voltage will be loaded by the impedance of the voltmeter and will dropgradually.

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• If the two readings are essentially the same (within 0.01v), C1 has a suitably lowleakage. If pin 6 is higher than TP2, then C1 may have to be changed to a lower leakage capacitor.

• Repeat the test for C2 by comparing TP3 with U1 pin 2.

Finally verify the operation as follows:

• Turn on the power supply. The relay should immediately pull-in even if thevoltage is below the Turn-Off set-point.

• Adjust the power supply to the Turn-Off voltage plus 0.1 v (eg 10.6v). Pauseseveral minutes for the circuit to stabilize.

• Adjust the power supply to 0.1v below the Turn-Off set-point. The relay shoulddrop out after a short delay.

• Raise the power supply voltage to the Turn-On set-point less 0.1v (ie 12.0-0.1=11.9v). Pause a couple of minutes for the circuit to stabilize.

• Raise the power supply voltage to the Turn-On set-point plus 0.1v (ie 12.1v). The

relay should pull in after a short delay.

That completes calibration and circuit verification .

 

Parts List

PC-420 Basic Parts List

Designator Description

C1,2 Capacitor, tantalum electrolytic, low leakage, 22uF, 16-25v

C3 Capacitor, electrolytic, 22uF, 16-25v

C4 Capacitor, ceramic, 0.1 uF, 50v

CR1,2 Diode, silicon, 1 amp, 400 PIV, 1N4004 or equiv.

K1 Relay, 12vDC coil, contacts suitable for application

Q1 Transistor, silicon, NPN, 2N3904 or equiv.

Q2 Transistor, power MosFET, n-channel, 4A, 100v, IRF510 or equiv.

R1 Resistor, carbon film, 33 kilohm, 1/4 watt

R2 Potentiometer, trimpot, 3/8 in square, 10 kilohm

R3 Resistor, carbon film, 8.2 kilohm, 1/4 wattR4 Resistor, carbon film, 22 kilohm, 1/4 watt

R5 Potentiometer, trimpot, 3/8 in square, 10 kilohm

R6 Resistor, carbon film, 15 kilohm, 1/4 watt

R7 Resistor, carbon film, 100 kilohm, 1/4 watt

R8 Resistor, carbon film, 470 kilohm, 1/4 watt

R9 Resistor, carbon film, 270 ohm, 1/2 watt

R10,11,12 Resistor, carbon film, 10 kilohm, 1/4 watt

TB1 Terminal block, 5 screw terminals, 0.20 (5.00 or 5.08 mm) spacing

TB2 Terminal block, 2 screw terminals, 0.20 (5.00 or 5.08 mm) spacing

U1 Integrated circuit, timer, NE555VR1 Diode, zener, 7.5 volt, 1 watt, 1N4737A or equiv.

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PCB Printed circuit board, Lantronics PC-420A or equiv.

 

Remote Reset Option Parts List

Designator Description

CR21,22,23 Diode, silicon, switching, 1N4148 or equiv.

Q21 Transistor, silicon, NPN, 2N3904 or equiv.

R21 Resistor, carbon film, 100 kilohm, 1/4 watt

R22,23,24,25 Resistor, carbon film, 10 kilohm, 1/4 watt

 

High Side Switch Option Parts List

Designator Description

Q31,32,33,34Transistor, power MosFET, p-channel, 55v, 64A, IRF4905 or equiv.

R13 Resistor, carbon film, 10 kilohm, 1/4 watt

R31,32,33,34 Resistor, carbon film, 10 kilohm, 1/4 wattVR21,22

Suppressor, surge, metal oxide varistor,12vdc, Harris V18ZA1 or Seimens S05K11

 

PC Boards

I have laid out and double checked a printed circuit board for this NE555 based LowVoltage Disconnect. Here is the pattern (PC-420A) for reference purposes. Itaccommodates all the options except the high side switch option which would have to be

mounted on a separate heatsink board. I hope that it shows properly on most browsers. Note that this pattern was modified from the original one (PC-420) published toincorporate necessary circuit changes.

PC-420A Copper Side - Direct View

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PC-420A Component Side - Parts Layout View

A high resolution (300 dpi) pcb pattern gif image can be downloaded and printed outfrom a bitmap viewer such as PaintShop. If using this pattern to make your own boards,you must make sure that the pattern is scaled to size properly. Use the size marker toconfirm the proper scale

Due to a general lack of sufficient demand for the circuit boards, they are no longer available. A short production run was made 4 years ago but I am no longer in the circuit

 board business, so they are no longer available from me. You are welcome to use the PCBlayouts above to make your own boards if you have the facilities and skill.

You might also be interested in a 12v Battery AmpHour Meter  application for thisdisconnect circuit.