Contemporary Controls BASR Series User manual
BASR
Versatile BACnet/IP Controller/Gateway
INSTALLATION GUIDE
(Version 3.5.x and higher)
ATTENTION: The BASremote User Manual can be downloaded at
https://www.ccontrols.com/pdf/TD0403000M3.pdf
INTRODUCTION
The BASremote series provide the system integrator a exible building block
when integrating diverse building automation protocols or when expanding
the number of points in a building automation system. By supporting open
system protocols such as BACnet®, Modbus and Sedona Framework™SOX,
the BASremote series is easily adaptable. For small systems, it can operate
stand-alone. For larger systems, it can communicate to supervisory
controllers over Ethernet. Depending upon the model, the BASremote has
the exibility to provide the following:
Versatile Control Device — remote I/O, router, gateway and controller
•Web-page conguration
•BACnet/IP Remote I/O
•Modbus TCP Remote I/O
•Modbus Serial to Modbus TCP Router
•Modbus Serial to BACnet/IP Gateway
•Modbus Master to Attached Modbus Slaves
•Powered by Sedona Framework™ Controller
•Power over Ethernet (PoE)
•Customisable web pages
Flexible Input/Output — expandable by adding modules
•Six universal input/output points web-page congurable
•Two relay outputs
•Thermistors, voltage, current, contact closure and pulse inputs
•Voltage, current and relay outputs
•2-wire Modbus Serial Expansion port
•2-wire expansion port for up to three expansion I/O modules
BASremote
CONTR LSO ®
CONTEMPORARY
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The BASremote Master provides the ultimate in exibility. It can be used for
expansion I/O at remote locations where an Ethernet connection exists. Its
built-in router and gateway capabilities address unique integration needs where
more than one communications protocol is involved. It can operate as a
function block programmable controller with its resident Sedona Framework
Virtual Machine. Powered by a Linux engine, the BASremote Master can
operate as BACnet/IP and Modbus TCP remote I/O, Sedona Framework
controller, Modbus Serial to Modbus TCP router, Modbus Serial to BACnet
gateway, and Modbus master to attached Modbus slaves all at the same time.
A 10/100 Mbps Ethernet port allows connection to IP networks and popular
building automation protocols such as Modbus TCP, BACnet/IP, and Sedona
SOX. Six universal I/O points and two relay outputs can be congured
through resident web pages using a standard web browser and without the
need of a special programming tool. A 2-wire Modbus serial port can greatly
expand the I/O count with built-in routing to Modbus TCP clients. If BACnet
mapping is preferred, the unit incorporates a Modbus serial to BACnet/IP
gateway. The BASremote Master also allows you to install custom web
pages so you can view the status of your system in a convenient manner.
Additional universal I/O can be achieved with the simple addition of
BASremote Expansion modules. The BASremote PoE has the same
capabilities as the BASremote Master except it is powered over the Ethernet
connection thereby providing a “One Cable Solution”.
The Sedona application can send emails when a specic event occurs in the
Sedona application. These contain text to describe alarms and component
input values. Different emails can be sent to different email addresses.
The BASremote Master rmware can be upgraded via a webpage screen.
Use the browse button to select the rmware le supplied by Contemporary
Controls to upload, and then press Upload.
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TRADEMARKS
Contemporary Controls, ARC Control, ARC DETECT, BASautomation,
EXTEND-A-BUS, RapidRing, and CTRLink are trademarks or registered
trademarks of Contemporary Control Systems, Inc. Specications are subject to
change without notice. Other product names may be trademarks or registered
trademarks of their respective companies. BACnet is a registered trademark of
the American Society of Heating, Refrigeration, and Air-Conditioning
Engineers, Inc. (ASHRAE).
COPYRIGHT
© Copyright 2016 by Contemporary Control Systems, Inc. All rights reserved.
No part of this publication may be reproduced, transmitted, transcribed, stored
in a retrieval system, or translated into any language or computer language, in
any form or by any means, electronic, mechanical, magnetic, optical, chemical,
manual, or otherwise, without the prior written permission of:
Contemporary Control Systems, Inc.
2431 Curtiss Street
Downers Grove, Illinois 60515 USA
Tel: 1-630-963-7070
Fax: 1-630-963-0109
E-mail: [email protected]
Web: www.ccontrols.com
Contemporary Controls (Suzhou) Co. Ltd
11 Huoju Road, Science & Technology Park
New District, Suzhou, PR China 215009
Tel: +86-512-68095866
Fax: +86-512-68093760
E-mail: [email protected]
Web: www.ccontrols.com.cn
Contemporary Controls Ltd
14 Bow Court
Fletchworth Gate, CV5 6SP, UK
Tel: +44 (0)24 7641 3786
Fax: +44 (0)24 7641 3923
E-mail: [email protected]
Web: www.ccontrols.co.uk
Contemporary Controls GmbH
Fuggerstraße 1 B
04158 Leipzig, Germany
Tel: +49 0341 520359 0
Fax: +49 0341 520359 16
E-mail: [email protected]
Web: www.ccontrols.de
DISCLAIMER
Contemporary Control Systems, Inc. reserves the right to make changes in
the specications of the product described within this manual at any time
without notice and without obligation of Contemporary Control Systems,
Inc. to notify any person of such revision or change.
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SPECIFICATIONS
Electrical (± 10%) BASR-8M/P BASR-8M BASR-8X
DC AC DC AC DC AC
Input voltage: 48 V N/A 24 V 24 V 24 V 24 V
Input power: 10 W N/A 10 W 17 VA 8 W 17 VA
Input frequency: N/A N/A N/A 47–63 Hz N/A 47–63 Hz
(All modules intended for use with Class 2 circuits only.)
Loop Supply +24 VDC, 150 mA max +24 VDC, 150 mA max
Communications
BACnet/IP or Modbus TCP: ANSI/IEEE 802.3 N/A
10BASE-T/100BASE-TX
Ethernet Data Rates: 10/100 Mbps N/A
Modbus Serial: Modbus Master Serial ASCII or RTU N/A
2-wire, non-isolated EIA-485
2.4, 4.8, 9.6, 19.2, 38.4, 57.6, 115.2 kbps
100 m max segment length
Expansion Bus: N/A Proprietary protocol
100 m max segment length
Protocol Compliance
BACnet/IP: ASHRAE 135-2004, Annex J N/A
B-ASC Prole
Modbus TCP: Modbus Appl. Protocol Spec. V1.1b N/A
Dec. 28, 2006 (modbus.org)
Modbus Messaging on TCP/IP Impl. Guide V1.0b
Oct. 24, 2006 (modbus.org)
Modbus Serial: Modbus over Serial Line Spec. and N/A
Implementation Guide V1.02b
Dec. 20, 2006 (modbus.org)
Regulatory Compliance
CE Mark, CFR 47, Part 15 Class A, RoHS, UL 508, C22.2 No. 142-M1987
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Environmental
Operating temperature: 0°C to +60°C
Storage temperature: –40°C to +85°C
Humidity: 10% to 95%, non-condensing
Universal I/O (Channels 1–6) — Software congurable
All protected for: short-circuit and over-voltage up to 24 VAC
Analog inputs: 10 bit resolution, 0–10 V or 0–20 mA
(Input impedance 100 kΩ on voltage, 250 Ω on current)
Thermistor support: 10 kΩ Type II or Type III
(+40º to +110 ºF / +4.4º to +44ºC)
Digital inputs: dry contact or pulses to 40 Hz with 50% duty cycle
(User scalable, 0–10 VDC or 0–20 mA)
Analog outputs: 12 bit resolution, 0–10 V or 0–20 mA , user scalable
(Max load 750 Ω when using current output.)
Digital Outputs (Channels 7 & 8)
Each channel: “Form C” relay (NO and NC) rated 30 VAC/VDC, 2A
LED Indicators
Status: green/red
Ethernet: green/yellow
I/O Points: green/red
Ethernet Pin Assignments (MDI)
1TD+ 3RD+
2TD– 6RD–
(The pins below are used only on the BASR-8M/P.)
4+48 VDC 7 0 V
5+48 VDC 8 0 V
Mounting DIN-rail or panel-mount
Shipping Weight 1 lb. (.45 kg)
Figure 1 — RJ-45 Jack
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Figure 3 — BASremote Expansion Image
Figure 2 — BASremote Master Image
Reset
Switch
Product Images (WIth Panel-mountIng tabs removed)
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Figure 5 — BASremote Dimensional Drawing for All Models
mechanIcal (WIth Panel-mountIng tabs dIsPlayed)
Figure 4 — BASremote PoE Image
Reset
Switch
Product Image (WIth Panel-mountIng tabs removed)
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The BASR is intended to be mounted in an industrial enclosure or wiring
closet on 35-mm DIN-rail or panel-mounted with screws (not provided). The
panel-mounting tabs are packaged in a plastic bag within the shipping box.
To use these tabs, Figure 6 illustrates how the two studs of each tab are press
tted into their respective holes in opposing corners of the case. See Figure 5
for the mechanical details.
Figure 6 — Attaching Panel-Mounting Tabs
connectIng exPansIon equIPment
Input/output points beyond those available from the BASremote Master module
can be increased by adding BASremote Expansion modules or by attaching
Modbus serial devices to the MB bus. The MB port is used for connecting to
2-wire Modbus serial devices while the DN port is used for connecting to
BASremote Expansion modules. Both ports are non-isolated EIA-485
compatible. When installing equipment, make a record that identies the power
source, equipment locations, IP and MAC ID numbers, protocol in use, baud rate,
cable colour coding, etc. — anything that will be helpful for future staff.
Expansion Module Connections
Expansion modules are intended to occupy positions to the right or left of the
master module on the same DIN-rail or on additional DIN-rails within the
same control panel. In this situation only a short 2-wire twisted-pair cable is
needed for making connections between DN on the master module and UP on
the rst expansion module. Up to three expansion modules can attach to the
master module using a daisy-chain wiring scheme. The second expansion
module has its UP port connected to the preceding expansion module’s DN
port. The last expansion module will have a vacant UP port. The D+ terminal
on one device must attach to the D+ terminal on the other. The same applies to
the D– terminals. Bias and termination exists on the UP terminals. See Figure
9 for wiring details. For short connections, unshielded cable can be used.
Expansion modules are automatically assigned Modbus addresses beginning
with 2 based upon its position to the master within the daisy-chain wiring.
INSTALLATION
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Modbus Serial Bus Connections
The Modbus serial expansion port (MB) on the BASremote Master module
is non-isolated EIA-485 compatible. When connecting to other non-isolated
devices, care must be exercised to ensure that all non-isolated Modbus devices
share the same ground reference (COM) with the BASremote Master module.
This is usually accomplished by sharing the same power source. Congure the
Modbus baudrate and protocol using the BASremote Modbus port web page.
Figure 7 — Internal Termination and Bias
When connecting to an isolated 3-wire Modbus device, the signal common
of the isolated device must be connected to the SC pin between the MB
and DN ports. This ties the two reference points together for reliable
communications. Refer to Figure 9 for wiring details.
Modbus serial devices can only be attached to the MB port on the master
module. Refer to Figure 7 for details on the bias and termination network
present on the MB port. Together, these resistors approximate one 120 Ω
terminating resistor. Terminal D+ represents the more positive connection
for the EIA-485 Modbus serial network while D– represents the less positive
connection. Make corresponding connections to Modbus serial devices.
The last device on the bus should have applied bias and termination or
just termination. A shielded twisted-pair cable should be used with inter-
connecting devices. Connect the shields together and attached to chassis at
only one point. Refer to Figure 9 for wiring details.
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cablIng consIderatIons
When attaching cables to the BASR, Table 1 should be considered.
Function Signalling &
Data Rate
Minimum Required
Cable
Maximum
Segment Distance
Ethernet 10BASE-T
10 Mbps
Category 3 UTP 100 m (328 ft)
Ethernet 100BASE-TX
100 Mbps
Category 5 UTP 100 m (328 ft)
I/O Unspecied 18 AWG Unspecied
Expansion Unspecied Belden®9841 or equivalent 100 m (328 ft)
Modbus 2.4–115.2 kbps Belden®9841, 3106A, 9842 100 m (328 ft)
Table 1 — Cabling Considerations
NOTE: If using shielded cable, connect to chassis at only one point. Wire
size may be dictated by electrical codes for the area where the equipment is
being installed. Consult local regulations.
Observe in Table 1 that 10BASE-T segments can successfully use Category 3,
4 or 5 cable — however, 100BASE-TX segments must use Category 5 cable.
Category 5e cable is highly recommended as the minimum for new installations.
The Ethernet port of the BASR employs Auto-MDIX technology so that either
straight-through or crossover cables can be used to connect to the network.
reset sWItch
To reset the Master module to its default values of the IP address (192.168.92.68),
gateway address (192.168.92.1) and netmask (/24 or 255.255.255.0), use a
paperclip or similar tool to press the reset switch (see Figure 2 for location) while
the unit is repowered and until the reboot is complete. Once the Status LED stops
ashing, release the reset switch. The unit will now use the default values.
authentIcatIon
If prompted for a user ID and password (each at least 5 alphanumeric characters)
when rst accessing the BASremote webpage, the default user ID and password
are admin / admin. The default Sedona user ID and password were admin / blank
before rmware 3.7.0 — but admin / admin thereafter. Pressing the reset IP
address switch restores the webpage authentication to the default values.
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PoWerIng
The unit (except for the BASR-8M/P) requires 24 VDC or VAC from a source
via a three-pin removable keyed connector. The proper connections for various
power options are illustrated below.
NOTE: This device is intended for use with Class 2 circuits only.
Figure 8 — Power Options
The recommended size for power conductors is 16–18 AWG (solid or
stranded). Ground is directly connected to zero volts. Input connections are
reverse-polarity protected.
An internal source provides 24 VDC (allowing a maximum current draw of
150 mA) to power external transmitters connected as inputs to the BASR — so
a separate loop supply is unneeded.
WARNING: Powering devices can present special hazards. Read the
following text carefully.
Power Supply Precautions
Internally, the BASR utilizes a half-wave rectier and therefore can share the
same AC power source with other half-wave rectied devices. Sharing a
common DC power source is also possible. Sharing AC power with full-wave
rectied devices is NOT recommended. Full-wave rectied devices usually
require a dedicated AC power source that has a secondary elevated above
ground. Both secondary connections are considered HOT. AC power
sources that power several half-wave devices have a common secondary
connection called COMMON, LO, or GROUND. This connection might be
tied to earth. The other side of the secondary is considered the HOT or HI
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side of the connection. Connect the HOT side of the secondary to the HI input
on the BASR and the LO side to COM on the BASR. All other half-wave
devices sharing the same AC power source need to follow the same convention.
When using a DC power source, connect the positive terminal of the source
to the HI input and the negative terminal to COM on the BASR. Reversing
polarity to the BASR will not damage the BASR.
WARNING: Devices powered from a common AC source could be damaged if
a mix of half-wave and full-wave rectied devices exist. If you are not sure of
the type of rectier used by another device, do not share the AC source with it.
Limited Power Sources
The BASR should be powered by a limited power source complying with the
requirements of the National Electric Code (NEC) article 725 or other
international codes meeting the same intent of limiting the amount of power
of the source. Under NEC article 725, a Class 2 circuit is that portion of the
wiring system between the load side of a Class 2 power source and the
connected equipment. For AC or DC voltages up to 30 volts, the power
rating of a Class 2 power source is limited to 100 VA. The transformer or
power supply complying with the Class 2 rating must carry a corresponding
listing from a regulatory agency such as Underwriters Laboratories (UL).
IndIcator lIghts
Status: During boot-up, this LED ashes green. Once all les are loaded, it
glows solid green to indicate the unit is operational. If a problem exists, it
will glow solid red.
Ethernet: This LED glows if a valid link exists to an operating Ethernet
device. It indicates speed by colour: green for 100 Mbps and yellow for
10 Mbps. It ashes to indicate activity.
I/O: Each of these LEDs glows green when the associated I/O point is in
normal condition. Depending on the programmed function, some of these
LEDs will glow red to indicate abnormal conditions. Refer to the User
Manual for a complete explanation of these LEDs.
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FIeld connectIons
When attaching devices, observe proper cabling using Figure 9 as a guide.
Figure 9 — Sample Wiring Diagram
Wire Channels 1–6 so the most positive wire goes
to the “A” terminal and the most negative wire to
the “B” terminal.
The wiring options for Channels 1–6 are shown in
Figure 10. For each case in which polarity matters,
proper polarity is indicated.
Considerations in making eld connections for
various types of input and output devices are
discussed in the following pages. Figure 10 — I/O Options
(Channels 1–6)
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Thermistors
The BASremote has built-in calibration curves for 10 kΩ Type II or Type III
thermistors. These devices are nonlinear with a negative coefcient of
resistance to temperature and provide a nominal resistance of 10 kΩ at 25°C.
Using the web server, congure an input for either Type II or Type III
thermistor. As shown in Figure 11, connect the two-wire thermistor to points
A and B. Polarity is not an issue. If averaging of temperature is desired,
connect multiple thermistors in a series-parallel combination so that the
nominal resistance remains at 10 kΩ as shown. Make sure that all devices
are of the same type. The effective range of temperature measurement is
from +40° to +110°F (+4.4° to +44°C). An open input results in a fault
condition that produces a red LED indication for that channel.
Figure 11 — Thermistor Connections
Contact Closure
The BASremote can sense the make or break of a contact from a relay or
push-button. The contacts being sensed must be absent of any applied source
of energy, and be rated for low-voltage, low-current switching. The
BASremote will provide the electrical energy to be sensed. Using the web
server, congure an input for contact closure. As shown in Figure 12, simply
connect the contacts between points Aand B. For common mechanical
contacts, polarity is not an issue. The open-circuit voltage is 24 VDC and
the short-circuit current is 2 mA.
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Figure 12 — Contact Closure Connections
For solid-state switches, there are further concerns. It is recommended that a
solid-state device have an opto-isolated open-collector NPN transistor output
stage with a collector-emitter output voltage (Vce) of at least 30 V. Output
sinking current should be greater than 5 mA. The collector-emitter saturation
voltage should be less than 0.2 V when sinking 2 mA. The emitter should be
connected to point Band the collector to point Awhich is the more positive
point. This polarity must be observed when using solid-state devices. When
an input is congured for a contact closure, the BASremote sets the low
threshold to 2 V and the high threshold to 3 V. When a contact is made or the
solid-state switch is on (resulting in a saturated output), the voltage at point A
is close to zero volts. The corresponding LED for that channel will be on. If
the contact is opened or the solid-state switch is turned off, the voltage at
point B will quickly begin to rise towards 24 V. Once the voltage passes the
3 V high-threshold, the input channel will sense the “off” state. To return to
the “on” state, this voltage needs to return to 2 V. The one-volt difference is
called hysteresis. There is no need to add an external pull-up resistor when
using a contact closure input.
Contact closure inputs are sampled every 10 ms and for a change of state to
be recognized, the input state must be stable for two consecutive samples.
Therefore, contact closure response is from 20–30 ms.
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Pulse Inputs
A variation on contact closure inputs is pulse inputs. In this situation speed is
critical so the input ltering that limits the time response is removed. When
an input is congured for Pulse Input, a pulse rate up to 40 Hz can be
measured, assuming a 50% duty cycle. The pulse device could have an opto-
isolated open-collector NPN transistor output stage like the one identied
under Contact Closure, or it could provide an active sinusoidal output signal
that needs to be detected. Data is in the form of accumulated pulse count.
The Pulse Input voltage range is 0–10 VDC and the installer can set both the
low-threshold and high-threshold on the Pulse Input web page. The difference
in the two thresholds is the hysteresis. You can detect sinusoidal input signals
by setting the high threshold below the positive peak and the low threshold
above the negative peak. Setting the two thresholds well toward the centre of
the sinusoidal waveform (rather than near its peaks) offers some noise
immunity. It is not necessary for the input signal to swing from zero to 10 V.
Any substantial swing within this range can be detected. The input impedance
using Pulse Input is 100 kΩ. Connect the output of the pulse device to point A
and the common to BASremote common as shown in Figure 13.
Figure 13 — Pulse Input Connections
The pulse output could be sinusoidal with no DC offset so the BASremote
could experience both positive and negative excursions of the signal. The
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BASremote can only detect positive voltages so the negative excursions will
be ignored. It is still possible to detect the input signal by only sensing the
positive excursions.
When interfacing to a pulse device that has an opto-isolated open-collector
output, a pull-up resistor must be added to the device output. In Figure 13, a
3-phase wattmeter has three opto-isolated open-collector outputs, each
requiring an external pull-up resistor. Since each of the opto-isolators is
rated for 60 VDC, install a 100 kΩ pull-up resistor between each output and
the +24 V loop supply. The common of the opto-isolators connects to the
common of the BASremote. Since each BASremote input has a 100 kΩ input
impedance, the resulting voltage divider sets the off-state voltage to 12 V.
Even though the BASremote input range is 0–10 VDC, this will not harm it.
Set the two thresholds to 2 V and 3 V. The threshold points on digital signals
are not critical. Consult the pulse device manual for more guidance.
Analog Input
Either voltage in the range of 0–10 VDC or current in the range of 0–20 mA
can be measured with an analog input. Transmitters that produce an elevated
“zero” such as 2–10 VDC or 4–20 mA can be measured as well. Using the
web page, congure the input for either voltage or current and select an
appropriate range. Scaling the input is accomplished by assigning the low
and high points to engineering units. When set as a voltage input, the input
impedance is 100 kΩ and for a current input, the impedance is 250 Ω.
With voltage measurement, connect the more positive voltage to point Aand
the less positive to BASremote common as shown in Figure 14. On three-wire
devices such as damper actuators, the output signal is referenced to the
damper’s power supply common. That common must be at the same
reference as the BASremote common. Notice the connections in the
diagram. In this situation it is only necessary to attach the transmitter output
to point Aon the BASremote input.
When measuring current, remember the BASremote sinks current to ground.
A 250 Ω impedance is effectively applied between points Aand Bon the
input. To measure current, it must be driven into point Awith respect to
point B. For two-wire current transmitters, the more positive point on the
transmitter attaches to the +24 V on the BASremote loop supply or it can
attached to an external loop supply as long as that loop supply has a common
connection with the BASremote. The less positive connection is made to
point Aon the input.
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Figure 14 — Analog Input Connections
Care should be exercised when connecting to a three-wire current transmitter.
These are usually non-isolated devices between the power source and signal
output. The BASremote will sink current from its input to ground so the
transmitter must source current from a positive potential to ground. If the
three-wire transmitter works in this manner, it can be accommodated.
Four-wire transmitters usually have isolation between power supply and signal
output so their output stage can usually be treated as a two-wire transmitter.
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Analog Output
Either voltage in the range of 0–10 VDC or current in the range of 0–20 mA
can be outputted by assigning analog outputs. Congure an output using a
web page. Select the appropriate range. For DC voltage, the output voltage
is applied to point Awith respect to common. For DC current, the output
current is sourced from point Ato common so there is no need for a loop supply.
A current output can source up to 20 mA into a resistive load not exceeding
750 Ω. Verify the burden that a current output device will present. The
BASremote cannot generate enough voltage to drive loads with higher resistance.
Figure 15 — Analog Output Connections
Figure 15 illustrates connections to a three-wire damper actuator. The
damper requires a 0–10 V command signal which can easily be accomplished
by the BASremote. To drive a point requiring a 2–10 VDC input signal with
a 4–20 mA current source, install an external 500 ohm resistor as shown.
Notice that in this case a connection to pin B is not needed.
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NEED MORE HELP INSTALLING THIS PRODUCT?
Additional information can be found in the technical documentation available
on our web site at www.ccontrols.com. When contacting one of our ofces,
just ask for Technical Support.
WARRANTY
Contemporary Controls (CC) warrants its new product to the original purchaser for two
years from the product shipping date. Product returned to CC for repair is warranted
for one year from the date that the repaired product is shipped back to the purchaser or
for the remainder of the original warranty period, whichever is longer.
If a CC product fails to operate in compliance with its specication during the warranty
period, CC will, at its option, repair or replace the product at no charge. The customer
is, however, responsible for shipping the product; CC assumes no responsibility for the
product until it is received.
CC’s limited warranty covers products only as delivered and does not cover repair of
products that have been damaged by abuse, accident, disaster, misuse, or incorrect
installation. User modication may void the warranty if the product is damaged by the
modication, in which case this warranty does not cover repair or replacement.
This warranty in no way warrants suitability of the product for any specic application.
IN NO EVENT WILL CC BE LIABLE FOR ANY DAMAGES INCLUDING LOST
PROFITS, LOST SAVINGS, OR OTHER INCIDENTAL OR CONSEQUENTIAL
DAMAGES ARISING OUT OF THE USE OR INABILITY TO USE THE PRODUCT
EVEN IF CC HAS BEEN ADVISED OF THE POSSIBILITY OF SUCH DAMAGES,
OR FOR ANY CLAIM BYANY PARTY OTHER THAN THE PURCHASER.
THE ABOVE WARRANTY IS IN LIEU OF ANY AND ALL OTHER WARRANTIES,
EXPRESSED OR IMPLIED OR STATUTORY, INCLUDING THE WARRANTIES
OF MERCHANTABILITY, FITNESS FOR PARTICULAR PURPOSE OR USE,
TITLE AND NONINFRINGEMENT.
RETURNING PRODUCTS FOR REPAIR
Return the product by following the instructions at:
https://www.ccontrols.com/rma.htm
DECLARATION OF CONFORMITY
Information about the regulatory compliance of this product can be found at:
https://www.ccontrols.com/basautomation/basremote.php
25 August 2016
This manual suits for next models
3
Table of contents
