Renogy DC-DC User Manual

Dual Input
DC-DC

On Board Battery Charger w/ MPPT

30A | 50A

Version 1.0

Important Safety Instructions

Please save these instructions.

This manual contains important safety, installation, and operating instructions for the DCDC
Battery Charger. Do not operate the Battery Charger unless you have read and understood
this manual and the charger is installed as per these installation instructions. Renogy
recommends that the charger be installed by a qualified professional. Store it in a safe
place.The following symbols are used throughout the manual to indicate poentially
dangerous conditions or important safety information.

DANGER

Safety instruction:Failure to observe this instruction will result in
fatal or serious injury.

WARNING

CAUTION

Safety instruction:Failure to observe this instruction can result in
fatal or serious injury.

Safety instruction:Failure to observe this instruction can lead to
injury.

NOTICE

Failure to observe this instruction can cause material damage and
impair the function of the product.

Supplementary information for operating the product.

NOTE

The manufacturer accepts no liablilty for damage in the following cases:

Faulty assembly or connection.

Damage to the product resulting from mechanical influences and excess voltage.

Alterations to the product without expressed permission from the manufacturer.

Use for purposes other than those described in the operating manual.

For protection，pay close attention to the following basic safety information when
using eletrical sevices:

Electric shock

Fire hazards

Injury

01

General Safety

DANGER

In the event of fire，use a fire extinguisher that is suitable for electrical devices.

WARNING

Only use the product as intended.

Make sure all connections going into and from the product are tight

Disconnect the product from the battery
——each time before cleaning and maintenance
——before a fuse change (only by specialists)

Do NOT allow water to enter the product
——Detach all connections.
——Make sure that no voltage is present on any of the inputs and outputs.

The product may not be used if the product itself or the connection cable is visibly
damaged.

This product may only be repaired by qualified personnel. DO NOT disassemble or
attempt to repair the unit. Inadequate repairs may cause serious hazards.

Electrical devices are not toys.

Always keep and use the product out of the reach of children.

Children must be supervised to ensure that they do not play with the product.

NOTE

Before start-up，check that the voltage specification on the plate is the same as that of
the power supply.

Ensure that other objects cannot cause a short circuit to the contacts of the product.

Store the product in a dry and cool place.

02

Safety when connecting the product electronically

DANGER

Danger of fatal electric shock!

For installation on boats:
If electrial devices are incorrectly installed on boats，this can lead to corrosion damage
on the boat. Have the product installed by a qualified (boat) electrician.

If you are working on electrical systems,ensure that there is somebody close at hand who
can help you in emergencies.

WARNING

Make sure that the cables has a suffcient cross-section.

Lay the cables so that they cannot be damaged by the doors or the bonnet.
Crushed cables can lead to serious injury.

CAUTION

Lay the cables so that they cannot be tripped over or damaged.

NOTICE

Use ductwork or cable ducts if it is necessary to lay cables through metal panels or
other panels with sharp edges.

Do not lay the AC cable and DC cable in the same conduit (empty pipe).

Do not lay the cables so that they are loose or heavily kinked.

Firmly secure the cables,contact with each other.

Do not pull on the cables

NOTICE

03

Charger Safety

NEVER connect the solar panel to the charger without a service battery connection. The

Battery must be connected first.

Ensure the PV input voltage does not exceed 25 Vdc to prevent permanent damage. Use
the Open Circuit Voltage (Voc) at the lowest temperature to make sure the voltage does
not exceed this value when connecting panels together.

Battery Safety

WARNING

Batteries may contain aggressive and corrosive acids. Avoid battery fluid coming into
contact with your body. If your skin does come into contact with battery fluid,thoroughly
wash that part of your body with water. If you sustain any injuries from the acids，contact
a doctor immediately.

CAUTION

When working on batteries,do not wear any metal objects such as watches or rings.
Lead acid batteries can cause short circuits which can cause serious injuries.

Danger of explosions!

Never attempt to charge a frozen or defective battery.
In this situation

，

place the battery in a frost-free area and wait until the battery has

adjusted to the ambient temperature.Then start the charging process.

Wear goggles and pretective clothing when you work on batteries. Do not touch your eyes
when working with batteries.

Do not smoke and ensure that no sparks can arise in the vicinity of the engine or battery.

NOTICE

Only use rechargeable batteries.

Use sufficient cable cross sections.

Protect the positive conduit with a fuse.

Prevent any metal parts from falling on the battery.This can cause sparks or short
circuit the battery and other electrical parts.

Make sure the polarity is correct when connecting.

Follow the instrucions of the battery manufacturer and those of the manufacturer of the
system or vehicle in which the battery is used.

If you need to remove the battery,disconnect it first from the ground connection.
Disconnect all connections from the battery before removing it.

04

Table of Contents

General Information

Product Overview

Identification of Parts

Dimensions

Additional Components

Installation

Mount the Battery Charger

Connect the Battery Charger

Typical Setup

Cable and Fuse Sizing

Operation

LED Indicators

Charging Logic

Solar Charger Algorithm

06

07

07

09

10

11

11

14

15

15

16

16

17

18

Trouble shooting

Technical Specification

05

21

22

General Information

The Renogy Dual Input DC-DC On Board Battery Charger w/ MPPT is designed to charge your
service battery to 100% from two inputs: solar and alternator. Featuring multi-battery
compatibility including Lithium, this DCDC utilizes alternator power, solar power with MPPT
technology, or both to make sure that you're always charged and can enjoy being off the grid
longer!

Key Features

Designed to charge service batteries from two DC inputs—solar panels and alternator

Built-in Maximum Power Point Tracking (MPPT) to maximize the solar power

3-phase charging profile (Bulk, Boost, and Float) ensures your service battery will be
accurately charged at the correct voltage levels to 100%

Compatible with smart alternators (with variable output voltage)

Trickle charges the starting battery via solar panels if the service battery is fully charged

Isolation of the starting battery and the service battery

Temperature and voltage compensation features prolong battery life and improve system
performance

Smart Protection Features: battery isolation, over-voltage protection, battery temperature
protection, over-current protection, overheat protection, reverse current protection, solar
panel and alternator reverse polarity protection

Compatible with multiple battery types: Sealed, AGM, GEL, Flooded, and Lithium

Compact with a sturdy design, it was built tough for all conditions

06

Identification of Parts

BVS+

5

BVS-

1

6
7

IGN+

8
2

9

Product Overview

4

3

Key Parts

07

10

#

1

2

3

4

5

6

7

Labeling

PV+ Positive (+) input terminal for the PV Array. Requires ring terminal

ALT+

OUT+

NEG-

RS485

BTS

BVS

Description

Positive (+) input terminal from the Starter Battery

Positive (+) output terminal for House Battery

Common Negative (-) Terminal for Solar Panel Array,
Starter Battery, and House Batt

Communication port for app and monitoring screen;
future development.

Battery Temperature Sensor port utilizing data for accurate
temperature compensation and charge voltage adjustment

Battery Voltage Sensor (RVSCC) port for measuring the
battery voltage accurately with longer line runs. Due to the
connection and cable resistance, there can be discrepancies in
voltages at the terminal vs the BVS.

11 12 13

Key Parts

#

8

9

10

11

12

13

Dimensions

φ4.5mm

[0.18in]

Labeling

IGN+

TYPE

Description

Ignition Signal Input port for triggering the battery charger for
smart alternators. IGN wire recommended 18-16AWG .

Standard/Traditional Alternator –has a fixed voltage
when charging (Do not connect IGN wire)

Smart Alternator—has a controlled charging output based on
operating conditions Variable. (Requires IGN signal wire).

Battery type push button. Change the LED to the matching
battery type of your application.

Alternator/Charging Indicator

Solar Charging Indicator

Service Battery Indicator

Battery Type Indicator

77mm
[3.03in]

244mm [9.60in]
227mm [8.94in]
215mm [8.46in]

NOTE

The 30A/50A models are the same dimensions.

140mm [5.51in]

146mm [5.75in]

108mm [4.25in]

08

Additional Components

Additional components included in the package:

Battery Temperature Sensor

The proper battery charging voltage is important for optimum battery
performance and longevity. This Remote Temperature Sensor measures
temperature at the battery, allowing the DC-DC charger to use this data for
accurate temperature compensation and charge voltage adjustment.

No temperature compensation when charging lithium battery.

NOTE

IGN Signal Wire for Smart Alternator

Smart alternators allows the vehicle to control the output voltage depending
on the operating conditions whereas traditional alternators output a fixed
higher voltage. If your readings are around 14.4V DC then then you most
likely have the traditional, non-smart alternator. If your reading is closer to

12.5-13.5V then it’s likely that you have a smart alternator. Check with your
vehicle manufacturer to determine alternator status.

Not connected if using traditional alternator.

NOTE

IGN wire recommended 18-16AWG .

RS485 Communication Cable

Communication cable for RS485 port for App and Monitoring Screen; future
development.

Optional Components

Optional components require a separate purchase.

Battery Voltage Sensor (RVSCC)

The Battery Voltage Sensor provides users with more accurate battery
charging giving you peace of mind that the charge controller is operating as
effectively as it should. On certain applications with long line runs, there can
be a difference between the voltage measured at an MPPT/PWM solar
charger’s terminals and that measured at the battery terminals. The BVS is
the perfect solution by providing a more accurate battery voltage to the
controller and allowing it to adjust the charging stage more precisely
resulting in overall extension of your battery life.

09

Installation

Mount the Battery Charger

DANGER

Never mount the product in areas where there is a risk of gas or dust explosion.

CAUTION

Ensure a secure stand!
The product must be set up and fastened in such a way that it cannot tip over or fall down.

NOTICE

Do not expose the product to any heat source (such as direct sunlight or heating).
Avoid additional heating of the product.

Set up the product in a dry location protected from splashing water.

Location Considerations

The battery charger can be installed horizontally as well as vertically.

The battery charger must be installed in a place that is protected from moisture.

The battery charger may not be installed in the presence of flammable materials.

The battery charger may not be installed in a dusty environment.

The place of installation must be well ventilated. A ventilation system must be available for
installations in small, enclosed spaces. The minimum clearance around the battery charger
must be at least 5cm.

The device must be installed on a level and sufficiently sturdy surface.

When selecting a location for the DCDC, make sure that the unit is as close as possible to the
battery you will be charging (auxiliary battery). The charger may be mounted on the cabin of
tthe vehicle, along a chassis rail, the inner guard of a vehicle, behind the grille or headlight or
even on the side of the radiator. However, you want to make sure that the area is not
susceptible to moisture or other substances as well as potentially high temperatures. The
DCDC would operate best if there is some air flow.

10

Connecting Temperature Sensor

The temperature sensor will have a green housing connector on one end and a metal probe
on the other. Simply align and connect the green housing to the BTS terminal on the DCDC.
Place the probe end of the sensor near or on top of the battery to monitor temperature in the
area.

Connecting IGN Signal Wire

Connect the positive line to one of green housing ports on the IGN port. You will need to open
the wire terminal utilizing the screws on top of the green housing. You will then connect the
positive line of the IGN to the ignition circuit.

Standard/Traditional Alternator–has a fixed voltage when charging (Do not connect IGN wire)

Smart Alternator—has a controlled charging output based on operating conditions.
Variable. (Requires IGN signal wire)

NOTE

There are two ports on the green IGN connector housing. Both ports have a positive polarity, so
only one connection is required from either port.

Connect IGN to Vehicle Ignition
for Smart Alternators

11

Connecting Battery Voltage Sensor

Connect the Battery Voltage Sensor connector to the BVS port. Connect the positive line to the
left side of the green housing and then connect the negative line to the right side of the green
housing. You will need to open the wire terminal utilizing the screws on top of the green
housing. You will then need to place the bare wire end onto the respective battery terminal for
accurate voltage sensing.

BVS+
BVS-

Selecting the Battery Type

To change the battery type you will need to press the push button that is located on the PV+
and ALT+ side of the DCDC. The following chart indicates the Battery Type LED .

NOTE

User mode is an extra feature accessed via App or Monitoring Screen; Future Development

12

Connect the Battery Charger

WARNING

Do not reverse the polarity. Reverse polarity of the battery connections can cause
injury and damage the device.

CAUTION

Avoid coming into contact with the battery fluid under any circumstances.

Batteries with a cell short circuit should not be charged as explosive gases may form
due to the battery overheating.

Be careful not to over-torque the terminals on the DCDC. Over-torquing may cause
irreparable damage. Do not exceed 16 N-m / 3.3 ft-lb

NOTE

Make sure the battery poles are clean when connecting the terminals.

Select a sufficient cross-section for the connection cable.

Use the following cable colors:
——Red: positive connection
——Black: negative connection

Tighten the nuts and bolts with proper torque. Loose connections may cause overheating.

For safety, please always connect ground (NEG.-) first and then connect the service battery
positive, starting battery positive and PV positive respectively.

1. Connect a negative power cable to (NEG. -) terminal on the DCDC, and connect the other
end to the negative pole of service battery or directly to the chassis.

2. Connect a positive power cable between (OUT+) terminal on the DCDC, and the positive pole
of service battery.

3. Connect a positive power cable between (ALT+) terminal on the DCDC, and the positive pole
of starting battery.

Optional: Only for system setup with Smart Alternator
Connect the IGN Signal Wire between Ignition Signal Input port on the DCDC, and the vehicle ignition

4. Connect a cable between terminals marked PV+ on the DCDC to the PV positive.

13

Typical Setup

Solar Panel

Adapter Kit

Solar Ad

DC-DC MPPT Charger

Common
NEG-

House
BATT+

House BATT

Cables to

NOTE

ING(D+) Signal Wire for

smart alternator

ANL Fuse

MC-4 INLINE Fuse

Starter BATT

Cables to

Starter BATT+Alternator

PV+

Starter
BATT+

House BATT+

ANL Fuse

Be careful not to over-torque the terminals on the DCDC. Over-torquing may cause
irreparable damage. Do not exceed 16 N-m / 3.3 ft-lb

Cable and Fuse Sizing

Fusing

Model Rated Current Vehicle Input Fuse Rating

DCDC30

DCDC50

30A 45A

50A 75A 65A

Charger Output Fuse Rating

40A

Cable sizing

Model

DCDC30

DCDC50

Cable Length (m)

Cable Length (ft)

Recommended Cable Size

1-5 3-16

5-9 16-30 6-4 AWG

1-5 3-16 6 AWG

5-9 16-30 4 AWG

10-8 AWG

14

LED Indicators

Operation

Solar Charging Indicator

Color

Status

Description

ON Bulk charge (MPPT)

Slow Flashing Boost charge

Red

Single Flashing Float charge

Fast Flashing Equalizing charge

Double Flashing Current-limit charge

OFF Not charging

Service Battery Indicator

Color Status Description

Green ON Battery Full

Yellow

ON Battery voltage normal
ON Battery undervoltage

Red

Slow Flashing Battery over discharged

Fast Flashing Battery over voltage/ over temperature

NOTE

The Charging Indicator may change under the following conditions:

1. Red to Yellow: When the voltage reaches 12.2V under voltage recovery

2. Yellow to Red: When the voltage drops to 12.0V under voltage warning

3. Yellow to Green: A. When it reaches constant voltage charging state, the charging current is
smaller than 3A, lasts for 30 seconds; B. When the charging current is higher than 3A, it keeps
charging until it reaches constant voltage state and the current drops below 3A, lasts 30 seconds.

Alternator/Charging Indicator

Color Status Description

ON Alternator is charging the service battery

Red

Slow Flashing PV is charging the starting battery

OFF Not charging

Battery Type Indicator

Color Status Description

Green ON SLA (Default)

Yellow

Red

Blue

White

NOTE

User mode is an extra feature accessed via App or Monitoring Screen; Future

ON GEL

ON FLD

ON LI

ON User

Development

15

Charging Logic

Alternator Input

Connect alternator with starting battery and service battery (No solar panel, or night time)1.

The DCDC battery charger will connect or disconnect the service battery according to

1.1
the starting battery voltage.

Alternator Type

Traditional Alternator

Smart Alternator

The DCDC will stop charging if the alternator input voltage is higher than 16.5V, and

1.2

＞13.2V, for 15 seconds ＜12.7V

＞12.0V, for 15 seconds ＜11.5V

Starting Battery Voltage

Cut-in Cut-off

recover to charge when the voltage is lower than 15.5V.

The maximum alternator charging for the DCDC30 is 30A and the DCDC50 is 50A. 1.3

Solar Panel Input

2.

Connect solar panel, starting battery and service battery (Engine not running).

The solar input charges the service battery as priority. If the service battery voltage is

2.1
lower than the boost voltage setting, solar panel will only charge the service battery.

If the service battery is in float charge stage, the starting battery will be charged at the same

2.2
time. The charging voltage is limited at 13.8V. The charging amperage is limited at 25A.

After charging the starting battery for 1 minute, it will disconnect for 30 seconds and

2.3
check the starting battery voltage. It will continue to charge starting battery if the voltage
is lower than 12.7V and will stop charging if the voltage is higher than 13.2V.

Solar charging will be triggered if the PV input voltage is higher than 15V for 10 seconds.2.4

The DCDC will stop charging if the PV input voltage is higher than 25.5V, and recover

2.5
to charge when the voltage is lower than 24.5V.

The maximum solar charging for the DCDC30 is 30A and the DCDC50 is 50A. 2.6

Dual Input (Alternator/Solar)

Connect solar panel, alternator with starting battery and service battery.3.

The DCDC will always take as much power from the solar panel as it can before

3.1
supplementing that power from alternator input, up to the rated charging current.

If the solar input power is able to keep the service battery at constant voltage charge

3.2
stage, alternator wouldn’t charge the service battery.

If the MPPT charging current from solar input is not able to keep the service battery at

3.3
constant voltage charge stage, alternator will cut in to charge the service battery. In
this case, the maximum dual input charging will be limited to 50% from each source.

16

a. DCDC30: 15A from alternator, up to 15A from solar for a total of up to 30A.

b. DCDC50: 25A from alternator, up to 25A from solar for a total of up to 50A.

Operating Temperature4.

The DCDC will lower the output power when its internal temperature is in the range from

4.1
65℃ to 80℃. It will stop charging when the temperature is higher than 80℃, and recover
to charge when the temperature is lower than 60℃.

If the service battery type is set to lead-acid, the DCDC will stop charging the service

4.2
battery when its temperature is lower than -36℃, and recover to charge when it’s higher
than -34℃.

If the service battery type is set to lithium, the DCDC will stop charging the service

4.3
battery when its temperature is lower than 1℃, and recover to charge when it’s higher
than 3℃.

Solar Charge Algorithm

MPPT Technology

The DCDC utilizes Maximum Power Point Tracking technology to extract maximum power
from the solar module(s). The tracking algorithm is fully automatic and does not require user
adjustment. MPPT technology will track the array's maximum power point voltage (Vmp) as it
varies with weather conditions, ensuring that the maximum power is harvested from the array
throughout the course of the day.

Current Boost

In many cases, the MPPT charger will "boost" up the current in the solar system. The current
does not come out of thin air. Instead, the power generated in the solar panels is the same
power that is transmitted into the battery bank. Power is the product of Voltage (V) x Amperage
(A). Therefore, assuming 100% efficiency:

Power In = Power Out

Volts In • Amps In = Volts out• Amps out

Although MPPT chargers are not 100% efficient, they are very close at about 92-95% efficient.
Therefore, when the user has a solar system whose Vmp is greater than the battery bank
voltage, then that potential difference is proportional to the current boost. The voltage
generated at the solar module needs to be stepped down to a rate that could charge the battery
in a stable fashion by which the amperage is boosted accordingly to the drop. It is entirely
possible to have a solar module generate 8 amps going into the charger and likewise have the
charger send 10 amps to the battery bank. This is the essence of the MPPT chargers and their
advantage over traditional chargers. In traditional chargers, that stepped down voltage amount
is wasted because the charger algorithm can only dissipate it as heat. The following
demonstrates a graphical point regarding the output of MPPT technology.

17

Limiting Effectiveness

Temperature is a huge enemy of solar modules. As the environmental temperature
increases, the operating voltage (Vmp
module. Despite the effectiveness of MPPT technology, the charging algorithm will
not have much to work with and therefore there is an inevitable decrease in
In this scenario, it would be preferred to have modules with higher nominal
despite the drop in performance of the panel, the battery is still receiving

) is reduced and limits the power generation of the solar

possibly

performance.

voltage, so that

a current boost

because of the proportional drop in module voltage.

Four Charging Stages

The DCDC

MPPT charge controller has a 4-stage battery charging algorithm for a rapid,
efficient, and safe battery charging. They include: Bulk Charge, Boost Charge, Float Charge, and
Equalization.

Battery
Voltage

Equalize
Boost

Float
Recharge

A B C

Bulk Charge

Constant charging

Float Charge

Boost

Bulk

Time

Battery
Current

Duration Time:2h

(Range:10-180min)

Max Current

Cumulative Time:3h

Time

Bulk Charge: This algorithm is used for day to day charging. It uses 100% of available solar
power to recharge the battery and is equivalent to constant current. In this stage the battery
voltage has not yet reached constant voltage (Equalize or Boost), the charger operates in
constant current mode, delivering its maximum current to the batteries (MPPT Charging).

18

Constant Charging: When the battery reaches the constant voltage set point, the charger will
start to operate in constant charging mode, where it is no longer MPPT charging. The current will
drop gradually. This has two stages, equalize and boost, and they are not carried out constantly
in a full charge process to avoid too much gas precipitation or overheating of the battery.



Boost Charge: Boost stage maintains a charge for 2 hours by default.

Float Charge: After the constant voltage stage, the charger will reduce the battery voltage to

a float voltage set point. Once the battery is fully charged, there will be no more chemical
reactions and all the charge current would turn into heat or gas. Because of this, the charger will
reduce the voltage charge to smaller quantity, while lightly charging the battery. The purpose for
this is to offset the power consumption while maintaining a full battery storage capacity. In the
event that a load drawn from the battery exceeds the charge current, the charger will no longer
be able to maintain the battery to a Float set point and the charger will end the float charge stage
and refer back to bulk charging.

Equalization: Is carried out every 28 days of the month. It is intentional overcharging of
the battery for a controlled period of time. Certain types of batteries benefit from periodic
equalizing charge, which can stir the electrolyte, balance battery voltage and complete
chemical reaction. Equalizing charge increases the battery voltage, higher than the standard
complement voltage, which gasifies the battery electrolyte.

WARNING

Over-charging and excessive gas precipitation may damage the battery plates
and activate material shedding on them. Too high of equalizing charge or for
too long may cause damage. Please carefully review the specific
requirements of the battery used in the system.

Four Charging Stages

The charger has a reactivation feature to awaken a sleeping lithium battery. The
protection circuit of lithium battery will typically turn the battery off and make it unusable if
over-discharged. This can happen when storing a lithium battery pack in a discharged
state for any length of time as self-discharge would gradually deplete the remaining
charge. Without the wake-up feature to reactivate and recharge batteries, these batteries
would become unserviceable and the packs would be discarded. The charger will apply a
small charge current to activate the protection circuit and if a correct cell voltage can be
reached, it starts a normal charge.

Lithium Battery Activation

The charge controller has a reactivation feature to awaken a sleeping lithium battery. The
protection circuit of lithium battery will typically turn the battery off and make it unusable if
over-discharged. This can happen when storing a lithium battery pack in a discharged
state for any length of time as self-discharge would gradually deplete the remaining
charge. Without the wake-up feature to reactivate and recharge batteries, these batteries
would become unserviceable and the packs would be discarded. The charge controller
will apply a small charge current to activate the protection circuit and if a correct cell
voltage can be reached, it starts a normal charge.

19

Troubleshooting

CAUTION

NOTE

Do not open the device. You risk exposing yourself to an electric shock by doing this.

If you have detailed questions about the battery charger, please contact our
customer support (addresses on the back of the instruction manual).

Solar Charging Indicator

OFF

Service Battery Indicator

Solid Red

Fast Flashing Red

Slow Flashing Red

Troubleshoot

Ensure that the Solar Panel is not being shaded (by a tree
etc.) Verify the Solar Panel voltage is higher than 15V
threshold with a multi-meter and check the electric
connections.

Turn off any loads connected to the battery and recharge
battery to a good SOC

Verify the service battery being used is a 12V unit.

Ensure the place for battery installation is well ventilated. Avoid
additional heating of the battery.

Disconnect all loads and chargers from the battery and allow
battery temperature to decrease to operational specifications

Check fuses are intact and properly connected.

Check the cable connections.

Turn off any loads connected to the battery and recharge
battery to a good SOC.

Alternator Indicator

OFF

Ensure the engine is running.

If using a traditional alternator, verify the alternator input
voltage is higher than 13.2V threshold with a multi-meter.

If using a smart alternator, verify the alternator input voltage is
higher than 12V threshold with a multi-meter. Also verify the
IGN Signal Wire is connected.

Check fuses are intact and properly connected.

Check the cable connections.

20

Technical Specification

Product

System Voltage

Battery Voltage Range

Maximum Charging Current

Battery Type

Service Battery Charging Mode
Charging Efficiency
Max. Solar Input Voltage

Max. Solar Input Power

Alternator Input Voltage

Max. Alternator Input Power

Temp. Compensation Coefficient

Self-consumption

Operating Temperature Range

Storage Temperature Range

Humidity Range

Dimensions

Weight

Terminal Size

Communication Protocol

Grounding

Certifications

RBC30D1S

12VDC

9~16VDC

30A 50A

SLA, GEL, FLD, LI, USER

MPPT

Up to 97%

25V

400W 660W

Traditional Alternator: 13.2-16VDC

Smart Alternator (Euro 6): 12-16VDC

400W 660W

-3mV/℃/2V

60mA

﹣35℃~65℃ / -31°F~149°F
﹣40℃~80℃ / -40°F~176°F

0%~95% (NC)

244*146*77 mm / 9.6 x 5.7 x 3.0 in

1.42 Kg / 3.13 lbs
M8x1.25-10mm

RS485

Common Negative

CE; ROHS; FCC Part 15 Class B

RBC50D1S

21

Battery Charging Parameters

Battery Type GEL FLOODED

Over-voltage Warning

Charging Limit Voltage

Over-voltage Recover
Boost Charge Voltage

Float Charge Voltage
Equalization Voltage
Boost Return Voltage

Under Voltage Warning
Under Voltage Recover
Over-discharge Warning

Over-discharge Recover
Boost Duration
Equalization interval
Equalization Duration

NOTE

User mode is an extra feature accessed via App or Monitoring Screen; Future Development

SEALED/AGM

16 V 16 V

15 V 15 V15 V 15 V

14.6 V 14.6 V 14.4 V

13.8 V 13.8 V

----- -----

12V

12.2V

11.1V

12.6 V 12.6 V

----- -----

-----

16 V

15.5 V

14.2 V

13.8 V

13.2 V

12.6 V

2 hours2 hours 2 hours

15.5 V15.5 V

14.8 V

13.2 V13.2 V
12V12V

12.2V12.2V

11.1V11.1V

28 days
2 hours

LI (LFP)

16 V

15.5 V

-----

-----

13.2 V

12.1V

12.3V

11.1V

12.6 V

-----

-----

----------

USER

9~17V
9~17V

9~17V

9~17V
9~17V

9~17V

9~17V
9~17V
9~17V
9~17V
9~17V

0-120min

0-30 Days

0-120min

This equipment has been tested and found to comply with the limits for a class B digital device,
pursuant to part 15 of the FCC Rules. These limits are designed to provide reasonable
protection against harmful interference in a residential installation. This equipment generates,
uses and can radiate radio frequency energy and if not installed and used in accordance with
the instructions, may cause harmful interference to radio communications. However, there is no
guarantee that interference will not occur in a particular installation. If this equipment does
cause harmful interference to radio or television reception, which can be determined by turning
the equipment off and on, the user is encouraged to try to correct the interference by one or
more of the following measures:

Reorient or relocate the receiving antenna.
Increase the separation between the equipment and receiver.
Connect the equipment into an outlet on a circuit different from that to which the receiver is
connected.
Consult the dealer or an experienced radio/TV technician for help.

This device complies with Part 15 of the FCC Rules. Operation is subject to the following two
conditions: (1) this device may not cause harmful interference, and (2) this device must accept
any interference received, including interference that may cause undesired operation.

22

RENOGY.COM

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the contents of this manual without notice.

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