Sterling Power Products PDAR, PDARRC User Manual

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WWW.STERLING-POWER.COM	PDAR
WWW.STERLING-POWER-USA.COM	PDARRC

STERLING POWER PRODUCTS ADVANCED ALTERNATOR REGULATOR PRO-DIGITAL

Advanced charging technology Installations Instructions & manual English and German.

2 x temp sensors

www.sterling-power.com www.sterling-power-usa.com

control box

Sterling Power Products

Advanced 4 step DIGITAL alt regulator

GREEN: High charge rate on

YELLOW: Timer activated

GREEN: Float mode

ORANGE: Low voltage warning

RED ONLY: High battery V trip

FLASHING: High battery temp

BAT TYPE: Green=gel/sealed Yellow= open lead acid Red= AGM

RED: Battery negative trip

GREEN: High alt temp disengage

YELLOW:12 v system setup

GREEN: 24 v system setup

BATTERY TYPE PROGRAM SELECTOR SWITCH, INSIDE LID 4 BATTERY TYPE POSITIONS

ON ON ON ON

1 2	1 2	1 2	1 2
GEL USA Spec	GEL	Non Sealed	Sealed acid
LED Green	Exide Spec.	Lead acid	and AGM
Flash. 10x	LED Green	or Traction	LED Red or
Then off		LED Yellow	Green & Yellow

Pro Reg D

block		temp
connection		Alternator
		Battery



Optional		temp
		Ign S/W


		D+

ALL L.E.D.S

FLASHING HIGH

ALTERNATOR

VOLTAGE TRIP

Wire configuration read instructions

Yellow: ignition feed White: field wire Brown: alt D+ Black: x 2 to neg. Red: to domestic bat Black/white: bat neg

RoHScompliant

Remote Control Socket

IUoU+

Remote control optional extra

HOCHLEISTUNGSREGLER

PRO-DIGITAL

Installationsund

Bedienungsanleitung

RoHS

compliant

INSTALLATON MIT TRENNDIODE ODER RELAIS: INSTALLATON WITH SPLIT

	fan	CHARGE DIODE OR RELAY:
	fan	Temperature-Sensor
		Temperature-Sensor

TERLING POWER PRODUCTS

	UNIVERSAL ADVANCED DIGITAL+			EXTRA
	S 4 STEP ALTERNATOR REGULATOR
				CONNECTIONS
	GREEN: HIGH CHARGE RATE ON			BLOCK

YELLOW: TIMER ACTIVATED

GREEN: FLOAT MODE

ORANGE: LOW VOLTAGE WARNING

RED ONLY : HIGH BATTERY V TRIP FLASHING RED: HIGH BATTERY TEMP

ALT

TEMP

BATTERY

TEMP

D+

SWITCH

BATTERY TYPE: GREEN: GEL/SEALED YELLOW: OPEN LEAD ACID RED: A.G.I.

BATTERY NEG TRIP FAULT

GREEN:HIGH ALT TEMP DISENGAGE

YELLOW:12 V SYSTEM SETUP

ALL L.E.D.S

FLASHING

HIGH

ALTERNATOR

VOLTAGE

TRIP

GREEN: 24 V SYSTEM SETUP

k	POS(+)	POS(+)	f	l
b	POS(+)	POS(+)	h	Temperaturesensor
		c
a		e

d	g

BATTERY TYPE	ON	ON	ON	REMOTE	i
BATTERY TYPE				CONTROL
PROGRAM SELECTOR				CONTROL
SWITCH, INSIDE LID				SOCKET
3 BATTERY TYPE	1 2	1 2	1 2			j
POSITIONS	GEL	LEAD	A.G.M
CE	SEALED	OPEN	L.E.D.
	L.E.D. L.E.D. ( RED )
	( GREEN ) ( YELLOW )
HELP LINE FOR STERLING POWER PRODUCTS TEL U.K 01905 26166
a = yellow to ignition (or D+/L/61)					a = gelb an Zündung+ oder (D+/R/L/DL)	Fig 4
b = white to field					b = weiss = Feld
c = brown to alt D+/62/L/DL					c = braun an D+/62/L/DL
d = 2 x black to alternator neg.					d = 2 x schwarz an Lima negativ-minus
e = split charge diode / relay					e = Trenndiode oder Relais
f = alternator					f = Lichtmaschine
g = starter battery					g = Starterbatterie
h = domestic battery bank					h = Verbraucherbatteriebank
i = red to domestic battery					i = rot an plus der Referenzbatterie
j = black/white to battery negative					j = schwarz-weiss an minus der Referenzbatterie
k = temperature sensor to alternator					k = Temperatursensor für die Lichtmaschine
l = temperature sensor to battery					l = Temperatursensor der Referenzbatterie

Sterling Power Products PDAR, PDARRC User Manual

PowerAdvancedManagementAlternator Regulator
withDisplay and				on/offon/off
AMP HrDiagnosCounterics Panel
Default	Bat14.3514.v4vmTimerPos 4			alarmbeep
volts				alarmbeep
1
Screen	37amps	35 a/hrs
2	Alt 15.4v 134m			lightlight
				lightlight

Help	SystemAmps		Volts
set up	SystemAmps		Volts
3	System Trip			1
	System Disengaged			2
Amp temp4	Low voltage warning			3
hr	System Within Limits			4
	SterlingSterlingpowerpowerproductsproducts			CEE

					yellow to ignition (or D+/L/61)
		fan			white to Field/DF/F				a
		fan			brown to D+/61/L				a
					2 x black to neg on alt
TERLING POWER PRODUCTS					1 x black white to batt neg
UNIVERSAL ADVANCED DIGITAL+				EXTRA
S 4 STEP ALTERNATOR REGULATOR				EXTRA					b
S 4 STEP ALTERNATOR REGULATOR				CONNECTIONS
GREEN: HIGH CHARGE RATE ON				BLOCK
YELLOW: TIMER ACTIVATED				TEMP					c
				ALT					d
GREEN: FLOAT MODE
				BATTERY
ORANGE: LOW VOLTAGE WARNING				TEMP	red to common	j
FLASHING RED: HIGH BATTERY TEMP				D+	red to common
RED ONLY : HIGH BATTERY V TRIP							COMMON
RED: A.G.I.				ALL L.E.D.S			COMMON
BATTERY TYPE: GREEN: GEL/SEALED				SWITCH
YELLOW: OPEN LEAD ACID
GREEN:HIGH ALT TEMP DISENGAGE				FLASHING	starter battery		1
GREEN:HIGH ALT TEMP DISENGAGE				ALTERNATOR	starter battery
BATTERY NEG TRIP FAULT				HIGH				2
				HIGH
				VOLTAGE
				TRIP
YELLOW:12 V SYSTEM SETUP							e
GREEN: 24 V SYSTEM SETUP					POS(+)				POS(+)
SWITCH, INSIDE LID		1 2	1 2	REMOTE					POS(+)
3 BATTERY TYPE	1 2	1 2	1 2
BATTERY TYPE	ON	ON	ON
BATTERY TYPE				CONTROL
PROGRAM SELECTOR				SOCKET
POSITIONS	GEL	LEAD	A.G.M				BOTH
CE	SEALED	OPEN	L.E.D.				g
	L.E.D. L.E.D. ( RED )
	( GREEN ) ( YELLOW )
HELP LINE FOR STERLING POWER PRODUCTS TEL U.K 01905 26166
HELP LINE FOR STERLING POWER PRODUCTS TEL U.K 01905 26166
Fig 5			temperature sensor cable to battery terminal

INSTALLATION WITH

A ROTARY SWITCH:

domestic

battery bank

SELECTORBATTERY Setup Up LED

COLOUR

1	2 1	ON	OPEN	YELLOW
			LEAD ACID	YELLOW
			LEAD ACID

2	2 1	ON
3	2 1	ON
3

GEL-

BATTERIES GREEN (EXIDE SPECIFICATION)

SEALED LEAD	GREEN-YELLOW
ACID & AGM

4	2 1	ON	GEL & AGM	GREEN FLASHING
4			(USA SPECIFICATION)	FOR 5 SEC.
			(USA SPECIFICATION)	FOR 5 SEC.

MAX. CHARGING		Fig.1
	ABSORBTION		FLOATING
VOLTAGE		TIME	VOLTAGE
14.8V / 20°C	1	- 3 HRS.	13.65V	/ 20°C
14.4V / 20°C	10	- 12 HRS.	13.8V / 20°C
14.4V / 20°C	4	- 8 HRS.	13.65V / 20°C
14.1V / 20°C	4 - 10 HRS.		13.5V / 20°C

L.E.D. functions

STERLING POWER PRODUCTS

UNIVERSAL ADVANCED DIGITAL+

4 STEP ALTERNATOR REGULATOR

GREEN: HIGH CHARGE RATE ON

YELLOW: TIMER ACTIVATED

GREEN: FLOAT MODE

ORANGE: LOW VOLTAGE WARNING

RED ONLY : HIGH BATTERY V TRIP FLASHING RED: HIGH BATTERY TEMP

BATTERY TYPE: GREEN: GEL/SEALED YELLOW: OPEN LEAD ACID RED: A.G.I.

e f

BATTERY NEG TRIP FAULT	g

Optional connections inside box on P.C.B		GREEN:HIGH ALT TEMP DISENGAGE	h
extend cables as require	Alternator temperature sensor	YELLOW:12 V SYSTEM SETUP	i
POS NEG	a	GREEN: 24 V SYSTEM SETUP	j
		GREEN: 24 V SYSTEM SETUP

FUSE

PowerAdvancedManagementAlternator Regulator

BATTERY TYPE

PROGRAM SELECTOR

withDisplay and

on/offon/off

SWITCH, INSIDE LID

1 2

AMP HrDiagnosCounterics Panel

3 BATTERY TYPE

1 2

Fig.2

Default

Bat14.3514.v4vmTimerPos 4

alarmbeep

POSITIONS

GEL

LEAD

A.G.M

volts

SEALED

OPEN

L.E.D.

Screen

37amps

35 a/hrs

L.E.D.

( RED )

Alt 15.4v 134m

lightlight

( GREEN )

( YELLOW )

HELP LINE FOR STERLING POWER PRODUCTS TEL U.K 01905 26166

Help

SystemAmps

Volts

set up

System Trip

System Disengaged

Amp temp

Low voltage warning

System Within Limits

Alternator type

Battery

SterlingSterlingpowerpowerproductsproducts

CEE

selector inside

type

REMOTE

selector

1 2

PANEL

control box

NEG

TO CONVERT

Battery temperature sensor

POS

UNIT FROM 12 VOLT

TO 24 V OPERATION

CONNECT SUPPLIED

JUMPER ACROSS

FUSE

PIN THESE 2 PINS

Fig 3

Fig 4

remote screen information

PowerAdvancedManagementAlternator Regulator
withDisplay and			on/offon/off
AMP HrDiagnosCounterics Panel
Default	14.35 v	m Pos 4	alarmbeep
volts1	14.35 v	m Pos 4	alarmbeep
	Bat 14.4v Timer
Screen	37amps	35 a/hrs
2	Alt 15.4v 134m		lightlight
			lightlight

Help	SystemAmps		Volts
set up	SystemAmps		Volts	1
3	System Trip			1
	System Disengaged			2
Amp temp4	Low voltage warning			3
hr	System Within Limits			4
	SterlingSterlingpowerpowerproductsproducts			E
				CE

THERE ARE 3 DIFFERENT WAYS TO MOUNT THE REMOTE SLIDE PARTS A TO EXPOSE SCREW HOLES

1)FOR FLUSH MOUNT, REMOVE PART B

2)FOR SURFACE MOUNT KEEP PART B

3)FIT THROUGH A METAL PANEL

AFTER INSTALLATION REPLACE PARTS A

BAT 14.1V BULK ALT 14.4V CALC.

BULK CHARGE

WET OPEN

SYSTEM SET: 12V xxx min. ACTIVE

BAT TEMP: 20C ALT TEMP: 60C

Push the volts button.

this gives the battery voltage and the alternator voltage, this would be the main screen

Push the arrow button.

this give the charger stage , it bulk charger ( high charger rate ) or float charger ( job done ), the bulk charger will change to a count down timer ( ie how long before the bulk charger is over and t will beguine ) l it also gives you the type of battery the system is set up for, ie wet, gel, A.G.M. etc.

Push button setup.

This gives the system set up information, ie it is set for 12 volt operation or 24 v , anh the time the system has been active ( engine running time from start up )

Push button temp.

This gives the battery and alterbnator temperature ( if the sensors are

UNIVERSAL DIGITAL ADVANCED REGULATOR FITTING INSTRUCTIONS. This new unit is

suitable for 12 and 24 volt operation, obviously to set this unit up as 24 volt on a 12 volt system, would be

catastrophic and all effort is made to ensure this does not happen. The unit comes preset to 12 volt operation as standard, a small electrical bridge must be made in order for the 24V function to be operated. ( see fig 3 code f , for the bridge position )This bridge is not supplied in the regulator box but is Sellotaped to the centre of these instructions ensuring that it cannot accidentally be installed. For 24V installation please fit the bridge as shown on the diagram now !!.

Thank you for purchasing the most advanced and powerful alternator regulator currently available in the world today. Please do not underestimate the effect this device will have on a conventional charging system. It is important to understand that your existing cables and layout may not be up to dealing with the extra performance from the alternator but do not worry, the Advanced Regulator has many safety devices built in to protect your system from damage in the event of the installation being unable to handle the extra performance caused by this device. The software will pick up any problems and disengage the unit and give a warning.

PRE INSTALLATION:

This device is not difficult to install, if a logical, step-by-step approach is maintained. Please note: The STERLING HELP LINE NUMBER IS UK 01905 26166 and should be used in event of any problems. Some basic tools, a voltmeter and soldering equipment are required for installation.

Because the new regulator has been made to be totally flexible for all battery and alternator types it is important for you to collect the following information about your system. This will enable you to set the Regulator correctly and obtain the maximum results from the device.

Please obtain the following information about your system and fill in the space provided, if nothing else it is about time you knew this information.

Alternator Voltage (12 or 24 volt type).....................	VOLTS
Alternator Current (35amp, 55amp etc)....................	AMPS

Alternator Type: There are two alternator types, negative and positive rotor field control. Do not worry at this stage, which you have, but it is vital that you identify the correct one before connecting the advanced reg ; this will be dealt with later.

My alternator type is: (Neg or Pos).........................

Battery Type: There are four main battery types: all the settings for these 4 battery types are clearly marked on the Advanced Regulator label. There is a lot of conflicting settings for gel and A.G.M. we have shown the setting recommended by Exide ( the major gel manufacturers ) however there are other companies who disagree with this in the U.S.A. so we have a setting for them also, its best to check with your supplier.

Battery Type selector ( fig 1 )

1)Conventional lead acid batteries, where you have access to the liquid level to maintain and top up the batteries. These may be charged at a faster rate and as such, the high charge setting may be used. By far the fasted charging batteries and the lowest cost. setting. Open lead acid/ traction batteries are the best type for fast charging and long life. 14.8 volts max for up to 8 hrs

2)Sealed Lead acid and some A.G.M batteries, not good for fast charging as cannot replace the water loss associated with fast charging. as such the top voltage is reduced to reduce the water loss , 14.4 volts max 4-6 hrs

3)Gel batteries ( Exide setting ) require , 14.4 volts 10-12 hrs on the charge voltage to charge them , as recommended by Exide .

Gel / sealed /A.G.M batteries are not recommended where fast charging is a priority. This is due to there limited ability to absorb high charge currents fast effectively.

4) Gel / some A.G.M settings. Some gel companies in the U.S.A. recommend no more than 14.1 volts so we have a setting for this. some A.G.M. batteries also require this setting.

The new software in the digital regulator automatically calculates the battery bank size, charge state, and alternator output, then using the internal DIGITAL processor sets the timing sequence every time you start the engine.

INSTALLATION:

This is the only hard part, and this will also determine your alternator type, when you have identified the alternator type please fill in the space above. Because there are so many alternators and many are not identifiable, the installation instructions apply to all alternators.

To identify the field control wire: (do not panic about removing an alternator, they are simple devices).

1)Isolate the alternator from the batteries (to prevent any accidents with live cables)

2)Remove all the wires from the back of the alternator (note down on this sheet as you go through the instructions to ensure correct placement of the regulator set-up switches).

3)With all the cables removed, remove the alternator.

4)Not so bad? Now for the hard bit! We are trying to get to the two brushes, which supply the rotor its current; they are usually connected to the regulator. Remove the regulator from the back of the alternator (usually 2 or 4 screws holding a component onto the back of the alternator) when this is removed the regulator should come away with the brushes attached. This should be no problem for about 80% of you with Lucas, Bosch, Volvo, however, the following things could be different:

a)A brushless alternator, most common S.E.V. Marshell 35 amp alternator fitted to old Volvo/Buch engines, has special instructions. On the alternator regulator is an F or D/F connection, this is the field wire, i.e. where the WHITE wire goes. This alternator is a positive alternator field control; therefore, change the booster setting from negative to positive. (CONNECT THE BROWN WIRE TO THE D+/61 /L TERMINAL, THE REST AS PER STANDARD. The best advice is to use this alternator as a sea anchor, and buy a decent size alternator, a 35 amp high revving alternator is no use to anyone).

Other special instructions relate to the very old Bosch mechanical regulator (about 25 years old), this must not be used in conjunction with the Sterling Regulator, however, conduct the tests as above, you will find the alternator is a positive field control. When the correct field wire is obtained set the Advanced Regulator to positive and remove the old Bosch regulator this is not a common thing).

b)Remote regulators, some alternators have regulators fitted remotely and connected to the alternator via 3-5 small wires (usually on old alternators), advice: The wires are still connected to a brush box on the alternator, remember it is the brushes we are after, locate the brushes as per normal.

c)Yanmar, Hitachi alternators require the alternator case to be split (unbolted, not hit with a sledgehammer), this will reveal the brushes in the back part. Please note for reassembly the two small holes in the brush housing which enable a wire to hold the brushes up when trying to reassemble the alternator.

5)Having found the brushes solder a 100mm length of 10 amp cable to the top of each brush.

Problems: Lucas regulator connectors are made from stainless steel, and as such normal pre-fluxed solder is no use, use standard plumbers flux from a tub and the solder will stick with no problem.

6) Having connected a cable to each brush, reassemble the alternator and replace it on the engine.

Problems: Volvo engines with Valeo alternators require some cutting around the regulator seal. Use your common sense never nip wires between the regulator and alternator case.

7) Ensure the ends of the two new cables are not touching each other, the alternator, or the engine, and reconnect the alternator.

8) After the alternator is reconnected, run the engine as normal, ensure the alternator is working as standard, i.e. the ignition warning light on the dash should out when the alternator is charging as per normal.

WARNING: GO NO FURTHER IF THE ALTERNATOR IS NOT WORKING. The alternator must be in normal working mode before continuing i.e. giving out about 14 volts from the output of the alternator ( x 2 for 24V)

I will say again for people who thing I am joking!

9) This is the most important part. With the engine running well on tick over, using the voltmeter, we require the voltage from both the cables you have just fitted to negative:

Cable 1 = ..............volts cable 2 =...............volts

(Also make a note of the alternators output voltage while doing these tests, if the alternator is working then we would expect to see a voltage of between 13-14 volts, if below 13V then the alternator is not working, if above 14.5 then the alternators own regulator is defective or one or the wires you have connected have shorted to the negative).

For Alternator Type:

If the voltage on any of the cables is between 2-12 volts and the other is 14 volts then this is a negative rotor control, go to the pre installation section and write NEG

If the voltage on any of the cables are 2-10 volts and the other is 0 (zero) volts, the alternator is a positive rotor control, go to the pre installation section and write POS

(For reference only, 90% of alternators in Europe are negative, these include Bosch, Valeo (Volvo), Hitichi (Yanmar), Lucas. The only positive alternators tend to be old alternators with remote regulators and American alternators such as Motorola and AC Delco, (this information is to be used as a rough guide only)).

In either case, we keep the 2-10 volt cable and either remove or cut the 14 or 0 volt cable. (Ensure this cable cannot touch the alternator case).

10) Having found the field wire and identified the alternator type the hard work is over, now to install the

regulator.

Remember to replace the old regulator back into the alternator do not leave it out.

Set Up Advanced Regulator Before Installation

1) By now you should have completed the pre installation section, I will take you through the Regulator set up and also explain what you are doing.

2) Remove the Regulator lid, inside you will see the circuit board with a 2 pin dip switch and a large fuse: See fig 3 , i = large fuse and h = dip switch

Battery Type: Identify the small 2-pin dip switch, and set the battery type as per your battery type, explained earlier . the settings are on fig 1 , and also on the metal lid of the Advanced Regulator.

WARNING: Under no circumstances use the Regulator on gel or sealed batteries if the battery type L.E.D is yellow when on this will permentelly damage the batteries.

Alternator Type: You should have established what the alternator field type is by now , it should be a negative or positive field control, ensure you have the correct information.

To set the alternator type, see fig 4. for neg, the fuse should be inboard of the edge of the case, if a pos unit then it should be beside the case edge

There is a standard automotive 5 amp fuse in the Regulator, there are three legs which will hold that fuse, the fuse should come standard set to the neg position. In order to convert the Regulator to a pos remove the fuse and reposition it in the other slot. The negative and pos positions are clearly marked on the printed circuit board drawing and on the instructions fig 4. Failure to get this right will result in damage to the advanced regulator and maybe the alternator's standard regulator.

EQUALIZING TIME CYCLE:

The software in the new Digital Regulator automatically calculates the equalizing time cycle every time the engine is started. This will range between 1-12 hours depending on the rise time between engine on and time to reach 14 volts; this will be different every time the engine is started, and varies from battery type setting . The internal computer software will look after this function.

The cables positions are marked on fig 4 and 5

a:Yellow: This is a simple ignition feed and should be connected to the ignition switch or any 12/24 volt supply which is live when the engine is running i.e. if there is no ignition switch then any good 12 volt supply will do with a simple on/off toggle switch to switch the unit on or off, i.e. when the engine starts switch this cable on, and when the engine stops switch this off. extend as long as you want

b:White:(Previously Green - changed due to new C.E regulations) The white is the alternator control cable, and should be connected to the field wire you fitted to the alternator earlier. This wire can be connected or disconnected with the alternator running, there may be cases where the Advanced Regulator needs to be switched off (i.e. small engine on a boat and a fast current) the Regulator has been known to knock off 1.5 knots of small boats with a 10-15 hp engine, however, most people usually connect and disconnect this cable (out of curiosity) to see the difference the Advanced Regulator makes to their system (with the Pro Digital, this unit can be switched on and off using the remote control). Extend as little as possible

c:Brown: The brown goes to the D+ on the back of the alternator, this is the small cable which is usually marked on the alternator case as “D+” or “ING” or “ L” or “61” it is the cable which feeds the warning light on the dash. Connect the brown to the same terminal leaving the existing cable in place some modern alternators have no D+ in this case connect to the B+ (the main positive output). extend as little as possible

d:Blacks x 2: There are two black cables, these cables, if extended must be extended as two cables and connected to the alternator B- (B negative) or to the alternator case. If these wires are extended then please extend as 2 x separate wires and join at the negative at the alternator, I know this sounds stupid but trust me.

Extend a little as possible

i:Black/white stripe: This is a new cable, which connects to the main domestic battery bank negative rail. This cable measures the negative at the battery banks, and checks it to the true negative at the alternator and ensures there is not to big a voltage drop in the negative cables. Any voltage drop in excess of 1.5 volts will trigger an alarm and shut down the Advanced Regulator on high negative volt trip. extend as long as you want

j:Red: The red is the sense wire, wherever it is placed on the Regulator and will regulate the voltage of that spot, therefore, it is important that the end of the red cable and the alternator must never be isolated when the engine is running.

The position of the red wire varies depending on what your charging system is:

Split charge diode: If your alternator charging circuit has a split charge diode fitted, position the sense on the battery side of the diode, on the side with the largest battery bank, (in the event of only two identical batteries either side will do).

Split charge relays: Same as above, however be warned, most low cost relays in the marine industry are approx 25 mm cubed, these relays may have been good enough for your old poor charging system, but when an Advanced Regulator is used do not be surprised if after a short period of time the relay melts. Only use good relays.

Rotary switch: Most yachts are fitted with a rotary switch, i.e. a switch with bat 1, bat 2, and both. With this type of charging system, position the sense on the back of the switch on the common point, remember that the only batteries to be charged are then dictated by you i.e. 1 or 2 or both. Due to the limitations and the constant changing of the switch, it would be my personal recommendation that, at a later date, you separate the charge line from the common starter feed and charge through a split charge diode.

Boats that have their bow thrusters positioned some distance away from the two main battery banks should place the battery sense wire (red) at the main battery bank and not at the bow thrusters. This is because the increase in battery voltage caused by the excessive distance between the battery banks can be too much for the main battery to deal with. The bow thrusters' battery will still benefit from the Advanced Regulator even if the sense wire is placed at the main battery bank.

Special vehicles: with no split system, connect the sense to the vehicle battery positive. extend as long as you

want

Testing the system:

Start the engine up as usual, the green boost light and the float light (yellow or green depending on booster settings) should be on,( the green boost light will flash for 2 mins on start up to show the slow start, this is to reduce belt slip ) the battery voltage should be measured to ensure the voltage works its way up to 14.4/14.8 depending on its settings. This could take between 1 minute and many hours depending on the battery bank size.

The voltage may vary slightly from alternator ie +/- 0.1 of a volt,. DO NOT ALTER THE FACTORY

SETTINGS the internal pots are set up reference voltages for the new software control system, and not external voltage adjustment pots (as in the older, non digital models were).

A word of warning, the most likely fault (assuming the Regulator is correctly connected) will be the high alternator voltage trip warning (all lights flashing), This is a unique safety device to prevent you setting fire to your boat. The trip consists of two sensors; one is sensing the battery voltage and will trip if the batteries exceed 15.5 volts (this will only happen if the standard voltage regulator on the alternator is defective, or the Advanced Regulator is defective). The other sensor is connected to the alternators D+ (the brown wire), this trips the Regulator if the voltage exceeds 17.5 volts at the alternator (all L.E.D's will flash together) the reasons for this tripping are usually poor cable connections, long cable runs or too thin a cable to carry the current now being produced or simply a failure in the connection between the alternator and the batteries) or the most common cause is a inline amp metre. Please be aware of cable runs with amp metres in the system. A good question to ask yourself is what is the cable length between the alternator and the batteries, you may think about 4 ft, but on further investigation you could find that the alternator output goes up to a dash mounted amp metre, then back down to the engine room and then through a diode to the batteries, total length about 15 feet. This is totally unacceptable and will require doubling up the cable thickness or replacing the amp meter with a shunt type or induction type (see the Sterling Power Management Panel)

In order to find the fault, switch the engine on and increase the engine revs to just below where the high voltage trip is going on. Test the battery voltage (must not ever be above 14.5 volts gel, or 15 volts normal), now we must measure the voltage drops in the cable between the positive terminal on the largest battery bank and the alternator itself. Place the negative probe of your volt metre on the positive terminal of the batteries and measure the voltage between the posivtive of the batteries and the posivtive of the alternator. Under normal circumstances there should be a 1.2-1.5 voltage drop across the diode and about 1 volt max drop in the cables = 2.5 volts drop in the charging system, any more than this is excessive cable loss due to poor connections or thin cables. This will show itself as heat, the best thing to do find the fault, is to carefully feel all the connections on the positive (AND NEGATIVE) sides of the charging circuit, if the main cable is warm to the touch the or connections are hot, then double up on charging cable and re do battery connections.

In order to accurately monitor what is going on in your system I suggest you look at the Sterling Power Management Panel / Amp Hour Counter because without this, you have no way of knowing what is going on your system and will be unable to diagnose any other faults on the electrical system.

Battery Maintenance.

Up until now you may never have maintained your batteries but with the regulator on the high charge rate you would expect to use much more water out of your batteries. It is therefore very important to regularly inspect and refill your batteries water level. For fast, high charging use only conventional lead acid batteries, do not use gel, or sealed batteries unless the maintenance free aspect is a priority and performance is not. The term 'maintenance free' may be on the side of your lead acid battery but this is not true in marine work cycle mode. Please ignore any reference to maintenance free on any open lead acid battery; this is for automotive cycles only. Remember

fast charging cost water, check your batteries water level regularly.

Temperature sensing: see fig 3 a= alt temp sensor, c = bat temp sensor

Connect the temperature sensor to a domestic battery terminal and to the 2 x terminals inside the Regulator (see internal drawing) and extend the cables as required. There is no polarity to these cables so connect any way round. Ensure the sensor is not crushed or nipped, in the event or the sensor becoming broken then the unit will revert to a standard 20 deg setting, however, if the wire is nipped and a 12 volt feed is fed up the wires this will destroy the unit . CONNECT TO THE NEG TERMINAL OF THE BATTERY ONLY NOT THE POS

The new Advanced Regulator has in built temperature compensation based on the graphs supplied by the battery manufactures. There are three graph types programmed into the software and are automatically selected with the battery type choice. There is also an alarm/shut down function in the event of catastrophic failure of the batteries or the Advanced Regulator, it may be left off if not required or fitted. This device will reduce the charge voltage as the battery temperature increases and switches off the Regulator and gives an L.E.D. alarm in the event of the batteries over heating. This function is good in the following conditions A) defective battery, all other trips are catered for electrically, remember this will only trip the Sterling Advanced Regulator, your standard regulator could continue to boil the batteries in the event of a bad battery fault or a standard regulator fault. The Sterling can only look after problems relating to the Sterling system B) defective Regulator: in the event of a defective Sterling Regulator or standard regulator the batteries will start to over heat, the Regulator will pick this up and shut down the Sterling Regulator only, it cannot shut down the standard regulator in the event of it failing closed, however the alarm function will be on.

False readings: the temperature sensor is designed to fit on the battery terminal post to pick up the electrolytic temperature inside the battery case. In the event of the post having bad connections of very high current flow, the

post may increase in temperature due to electrical resistance caused by bad connections, which could result in misleading temperature readings by the sensor. This would result in the Regulator shutdown with no fault with the batteries, a simple visual check and touching the battery case and battery terminals should establish if the electrolyte and the terminal are the same temp or the terminal is much hotter than the electrolyte, in which case, the problem could be bad electrical connections at your battery. One of the limitations of battery temperature sensing is that you could have 6 batteries and 1 sensor. The battery the sensor is connected to could be OK but battery number 5 could fail and the sensor is on battery number 2, the sensor would not pick up that problem. Other new features on this unit:

Dash warning light, some new alternators have a high voltage warning build into their alternators regulators, this switches on the ignition warning light in the event of fitting the Advanced Regulator (the Advanced Regulators higher voltage control makes the standard regulator think that it has failed).WARNING: TO DATE, THERE IS ONLY 1 MARINE ALTERNATOR WITH THIS PROBLEM (ON SOME FORD ENGINES) AND ONLY A FEW AUTOMOTIVE ALTERNATORS WITH THIS. SO PLEASE PHONE BEFORE ASSUMING THIS IS A PROBLEM. A small relay is built into the Regulator to disengage the D+ warning when the alternator has started up. This was a special function for a special vehicle where Sterling Power Products had a demand, however, it may become more common in the future.

WHAT TO EXPECT ON THE L.E.D. DISPLAY and what to do about it

see fig 2 for the relevent l.e.d. .

a:Green High Charge Rate On: (top L.E.D. 1) This should be on form start up and shows that the alternator should be working at it’s maximum. It should remain on until L.E.D. 3 comes on and shows the high charge rate is over.

b:Yellow Timer Activated: This comes on when the voltage reaches about 13.9 - 14 volts and depending on how long it takes to come on, the software will calculate the timing for the high charge rate. This will vary from 1 - 6 hours and the time will be displayed on the remote panel and a count down shown. This light will remain on until the high charge rate light goes out.

c:Green Float Mode: This indicates that all the high charge cycles are now over and should remain on after all the high charge lights are out. The system is now running at a standard charge rate only (about 14 volts) regulated on the battery.

d:Orange Low Voltage Warning: This is simply saying that there is a low voltage at the main battery bank and has no active function. For information only, this usually indicates a defective alternator.

e:Red Dual Information L.E.D: This L.E.D. Has two functions and as such, has two display modes.

Display Mode 1: Solid red L.E.D on indicates a high battery voltage trip, suggesting that the voltage exceeds 15.5 volts. There are three things that can cause this.

1)The alternator’s own regulator has failed closed, if the voltage continues to climb after the trip light has come on then the alternator’s own regulator is usually to blame (or there is an installation fault). STOP as soon as possible and disconnect the alternator wires. Then continue on your journey and fix the problem at the first opportunity. Sterling are unable to defend you against this fault other than warn you as it is on your basic system over which we have no control. Failure to react to this problem will result in your batteries boiling.

2)The Advanced Regulator’s own regulator has failed closed. If the battery voltage returns to 14 volts after the trip light has gone off then the Sterling Regulator has failed and the unit should be returned for repair/replacement as soon as possible. It is, however, still safe to use in an emergency case only, as when the batteries are flat the unit will charge them to 15.5 volts and then switch off. It should be stressed that this is for emergency, get me to port use only!

3)Some other charging source has failed, ie: the battery charger/wind generator /solar panels etc. In this case, the voltage would continue to rise even when the engine is switched off.

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