MNL-11RFx MNL-13RFx

Transkrypt

MNL-11RFx MNL-13RFx

DO5
C5
3.3
DO1
24VAC
DO2
DO3
24VAC
DO4
Power: 24VAC, 50/60Hz, Class 2,
8.5VA + DO1-DO4 loads.
Ambient Temp: -40°C to +60°C
UI: 5VDC Max, Class 2.
S-LK: 16VDC Max, Class 2.
DO1-DO4: 24VAC, 0.4A Max Total Load.
DO5: 250VAC, 3A Max, COS f = 0.4.
934G
E9429
Temperature indicating and
Regulating Equipment
N2223
CAUTION
T
X
M
I
J1
I/A Series
MNL-11R
GND
0V
24VAC
UI3
COM 0V
UI2
COM 0V
UI1
S-LK
S-LK
LON
LON
SRVC
S
R
R
E
V
C
C
V
DO7
C7
DO1
24VAC
DO2
DO3
24VAC
DO4
N2223
3.3
T
X
M
I
I/A Series ®
MNL-13R
UI: 5VDC Max, Class 2
S-LK: 16VDC Max, Class 2
DO5-DO7: 250VAC, 3A Max,
COS Φ = 0.4
J1
GND
0V
24VAC
UI3
COM 0V
UI2
COM 0V
UI1
S-LK
S-LK
LON
LON
SRVC
S
R
R
E
V
C
C
V
934G
E9429
CAUTION
DO6
C6
DO5
C5
RISK OF ELECTRICAL SHOCK OR FIRE. DO NOT
INTERCONNECT SEPARATE CLASS 2 CIRCUITS.
DISCONNECT POWER BEFORE SERVICING.
DECONNECTER AVANT ENTRETEN.
This device conforms 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.
This Class B digital apparatus meets all requirements of the Canadian InterferenceCausing Equipment Regulations.
Cet appareil numerique de la classe B respecte toutes les exigences du Reglement
F-26887-4
© Copyright 2006 TAC All Rights Reserved.
Printed in U.S.A. 11-06
I N T E R C O N N E C T S E PA R AT E C L A S S 2 C I R C U I T S .
D I S C O N N E C T P O W E R B E F O R E S E RV I C I N G .
D E C O N N E C T E R AVA N T E N T R E T E N .
TAC MicroNet Fan
MNL-13RFx Coil Controller with
Three High Voltage
(MN 130)
Relays
• 3 Universal Inputs
(software-configured)
• 4 DO Triacs, capable of
switching a total load of
0.5 A @ 24 Vac.
• 3 DO Relay Outputs,
250 Vac, 3 A.
• S-Link Support.
MNL-13RFx
TAC MicroNet Fan
Coil Controller with
One High Voltage
Relay
• 3 Universal Inputs
(software-configured)
• 4 DO Triacs, capable of
switching a total load of
0.5 A @ 24 Vac.
• 1 DO Relay Output,
250 Vac, 3 A.
• S-Link Support.
MNL-11RFx
(MN 110)
Inputs / Outputs
Description
Model
This device conforms 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.
This Class B digital apparatus meets all requirements of the Canadian Interference-Causing Equipment Regulations.
Cet appareil numerique de la classe B respecte toutes les exigences du Reglement sur le material brouilleur du Canada
Model Chart
MNL-11RFx
The TAC I/A Series MNL-11RFx (MN 110) and
MNL-13RFx (MN 130) Controllers are interoperable
controllers designed in accordance with LONMARK®
guidelines. When programmed using TAC WorkPlace
Tech Tool, these controllers provide control for fan coil
and unit ventilator applications. These controllers
feature: screw terminal blocks; three universal inputs,
software-configured to respond to one of five input
types; one (MN 110) or three (MN 130) high-voltage
relay output(s); four 24 Vac Triac (digital) outputs; and
an S-Link interface for connection to an optional MN-Sx
digital sensor.
TAC I/A Series® MicroNet™ Fan Coil
Controllers with High Voltage Relay(s)
Installation Instructions
TAC
1354 Clifford Avenue
P. O. Box 2940
Loves Park, IL 61132-2940
www.tac.com
MNL-11RFx
MNL-13RFx
Application
The MN 110 and MN 130 controllers conform to the
LONMARK Fan Coil Unit functional profile (8020)
providing open communication and interoperability with
third party LONMARK devices and greater freedom in
system design. These controllers can function in
standalone mode or as part of a LONWORKS® TP/FT-10
Free Topology network.
Applicable Documentation
F-Number
Description
F-26277
TAC I/A Series MicroNet
MN-Sx Series Sensors
General Instructions
F-27255
TAC I/A Series WorkPlace
Tech Tool 4.0 User’s Guide
F-27254
TAC I/A Series WorkPlace
Tech Tool 4.0 Engineering
Guide
F-26303
System Overview
F-26507
Systems Engineering
Guide
F-26363
EN-206 Guidelines for
Powering Multiple
Full-Wave and Half-Wave
Rectifier Devices from a
Common Transformer
Audience
–
–
–
–
Purpose
Application engineers Provides step-by-step installation, operation, and checkout procedures
for TAC I/A Series MicroNet MN-Sx Series Sensors.
Installers
Start-up technicians
Provides step-by-step instructions for using the TAC WorkPlace Tech
Service personnel
Tool.
Reference for programming TAC MicroNet controllers, using the TAC
– Application engineers
WorkPlace Tech Tool. Gives detailed descriptions of all the Control
– Service personnel
Objects used with MN Series Controllers.
–
–
–
–
Provides an overview of the TAC I/A Series MicroNet System. It
includes brief descriptions of the hardware and software components,
Application engineers and how they may be combined to create TAC MicroNet networks and
Installers
stand-alone systems.
Start-up technicians
Provides engineering and technical information to assist in designing
Service personnel
a complete TAC MicroNet controller system using different
architectures, components, and software.
Offers guidelines for avoiding equipment damage associated with
– Application Engineers improperly wiring devices of varying rectifier types. Contains
instructions for identifying device rectifier type, guidelines for correctly
– Installers
powering devices of varying rectifier types, and examples illustrating
– Service Personnel
proper power wiring techniques.
INSTALLATION
Inspection
Requirements
Inspect carton for damage. If damaged, notify carrier immediately. Inspect controllers for
damage upon receipt.
• Installer must be an experienced technician.
• Tools:
– Drill and bits
– Digital Volt-ohm meter (DVM)
– Static protection wrist strap
• Class 2 power transformer supplying a nominal 24 Vac (20.4 to 30 Vac), 50/60 Hz. For
transformer specifications, see the “Power Supply Wiring” section, on page 14.
• Suitable grounded metal enclosure (to prevent the possibility of accidental contact with
the high-voltage terminals)
• Four #6 self-starting screws or 35 mm DIN rail for mounting
• Terminators (if a TAC MicroNet LONWORKS network is used):
– One LON-TERM1 terminator required for each free topology segment
– Two LON-TERM2 terminators required for each bus topology segment
• Accessories (as required):
– MN-Sx TAC I/A Series MicroNet (S-Link) Sensors
– 470k ohm 1/4 watt resistor (if shielded wire is used for S-Link wiring)
– Approved Category 4 or 5, twisted-pair (two conductors) cable (optional LONWORKS
Network connection)
– 0.205 mm2 (#24 AWG) or larger twisted pair, voice grade telephone wire (for UI,
AO, and DI wiring)
– TSMN-57011-850 Series 10K ohm Thermistor Sensor with 11K ohm Shunt Resistor
– TSMN-58011 Platinum Sensor
– TSMN-81011 Balco Sensor
– AD-8969-201 11K ohm Shunt Resistor Kit (if TSMN-57011-850 is not used)
– 1K Balco or platinum element resistive sensor
– 0 to 5 Vdc analog voltage transmitter
– 4 to 20 mAdc analog current transmitter
– Digital dry switched contact (switched contact resistance must be less than
300 ohms for closed contact and greater than 1.5K ohms for open contact)
2
F-26887-4
Precautions
General
Warning: The MN 110 and MN 130 controllers are not suitable for exposed mounting
on a wall or panel, or in any other easily accessible place due to the possibility of
personal contact with the high-voltage terminals. They must be mounted inside a
suitable grounded metal enclosure (Figure-2).
Warning: Electrical shock hazard! Disconnect power from the controller and any digital
outputs before installing or removing the cover.
• Follow Static Precautions when installing this equipment.
• Use copper conductors that are suitable for 75 °C (167 °F).
• Make all connections according to electrical wiring diagram, national and local electrical
codes.
Static Precautions
Static charges damage electronic components. The microprocessor and associated circuitry
are extremely sensitive to static discharge. Use the following precautions when installing,
servicing, or operating the system.
• Work in a static-free area.
• Discharge static electricity by touching a known, securely grounded object.
• Use a wrist strap connected to earth ground when handling the controller’s printed
circuit board.
Federal Communications Commission (FCC)
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 residential installations. This
equipment generates, uses, and can radiate radio frequency energy and may cause harmful
interference if not installed and used in accordance with the instructions. Even when
instructions are followed, there is no guarantee that interference will not occur in a particular
installation. If this equipment causes 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 to an outlet on a circuit different from that to which the receiver
is connected.
• Consult the dealer or an experienced radio/television technician for help.
Canadian Department of Communications (DOC)
Note: This Class B digital apparatus meets all requirements of the Canadian
Interference-Causing Equipment Regulations.
Cet appareil numerique de la classe B respecte toutes les exigences du Reglement sur le
material broilleur du Canada.
European Community Directives
This equipment meets all requirements of European Community Directives for Low Voltage
(72/23/EEC), General Safety (92/59/EEC), and Electromagnetic Compatibility
(89/336/EEC).
Caution:
• This is a Class A product. In a domestic environment this product may cause radio
interference, in which case the user may be required to take adequate measures.
• The LON and S-LK cables must be installed within grounded metallic conduit or
conductive cable trays to fully comply with the EMC requirements of EN61326.
F-26887-4
3
Location
The MN 110 and MN 130 controllers are suitable for indoor use only (IP 20). See Figure-1
for mounting dimensions. When selecting a mounting location, make certain the following
conditions are met:
Warning: The MN 110 and MN 130 controllers are not suitable for exposed mounting
on a wall or panel, or in any other easily accessible place due to the possibility of
personal contact with the high-voltage terminals. They must be mounted inside a
suitable grounded metal enclosure (Figure-2).
Caution:
• Do not install where excessive moisture, corrosive fumes, vibration, or explosive vapors
are present.
• Do not install near large contactors, electrical machinery, or welding equipment.
• Allow 150 mm (6 in.) clearance from contactors, switches, and associated cabling.
• Locate where ambient temperatures do not exceed 55 °C (131 °F) or fall below -40 °C
(-40 °F) and relative humidity does not exceed 95%, non-condensing.
155 mm (6 in.)
14 mm
(9/16 in.)
50 mm
(2 in.)
132.5 mm (5-7/32 in.)
107 mm
(4-3/16 in.)
95.5 mm
(3-3/4 in.)
6 mm
(1/4 in.)
134.5 mm (5-5/16 in.)
9 mm
(3/8 in.)
23 mm
(15/16 in.)
Note: MN 110 shown. Dimensions are the
same for MN 130.
Figure-1 Mounting Dimensions.
Mounting
Panel or DIN Rail Mounting
1. Select a mounting location. Allow a minimum of 50 mm (2 in.) clearance around the
controller.
4
F-26887-4
Metal Enclosure 1
(Grounded)
(4) Screws
OR
DIN Rail
DO1
24VAC
DO2
DO3
24VAC
DO4
DO5
C5
N2223
UI3
GND
0V
24VAC
LON
S-LK
S-LK
S
R
V
C
J1
SRVC
R
E
C
V
COM 0V
UI2
COM 0V
UI1
X
M
I
T
LON
I/A Series
MNL-11R
934G
E9429
3.3
Controller
(MN 110 Shown)
Alternate Mounting
Methods
UI3
GND
0V
24VAC
COM 0V
UI2
COM 0V
UI1
1 This example illustrates the use of a suitable grounded metal
enclosure to mount an MN 110 or MN 130 controller.
Dedicated Ground
Wire from Enclosure
This controller is not suitable for exposed mounting on a wall
or panel, or in any other easily accessible place due to the
possibility of personal contact with the high-voltage terminals.
Grounding Point
inside Enclosure
Figure-2 Mounting in Enclosure.
2. Do the following to mount the controller onto a panel (Figure-3):
a.
Place the controller on a panel and mark the location of one top mounting hole.
b.
Drill the marked hole, using a drill bit sized for a #6 screw.
c.
Fasten the controller to the panel with one #6 self-starting screw.
(1) Screw
DO1
24VAC
DO2
DO3
24VAC
DO4
DO5
C5
DO1
24VAC
DO2
DO3
24VAC
DO4
DO5
C5
MNL-11R
GND
UI3
0V
24VAC
COM 0V
UI2
S-LK
J1
LON
LON
S-LK
S
R
V
C
SRVC
R
E
C
V
COM 0V
UI1
X
M
I
T
I/A Series
934G
E9429
N2223
3.3
MNL-11R
GND
0V
24VAC
UI3
COM 0V
UI2
J1
LON
S-LK
LON
S-LK
S
R
V
C
SRVC
R
E
C
V
COM 0V
UI1
X
M
I
T
I/A Series
934G
E9429
N2223
3.3
(3) Screws
Figure-3 Panel Mounting Method.
d.
Level the controller, then mark the locations of the remaining mounting holes.
e.
Drill the marked holes, then fasten the controller, using the three remaining screws.
3. Do the following to mount the controller onto a 35 mm DIN mounting rail (Figure-4):
a.
Hook the mounting tabs, on the back of the controller, onto the top edge of the DIN
rail.
b.
Gently press the bottom of the controller onto the DIN rail so that it snaps into place.
DO1
24VAC
DO2
DO3
24VAC
DO4
DO5
C5
DO1
24VAC
DO2
DO3
24VAC
DO4
DO5
C5
MNL-11R
UI3
GND
0V
24VAC
COM 0V
UI2
LON
S-LK
LON
S-LK
S
R
V
C
J1
SRVC
R
E
C
V
COM 0V
UI1
X
M
I
T
I/A Series
MNL-11R
UI3
GND
0V
24VAC
COM 0V
UI2
LON
S-LK
S-LK
S
R
V
C
J1
SRVC
R
E
C
V
LON
COM 0V
UI1
X
M
I
T
I/A Series
934G
E9429
3.3
934G
E9429
3.3
N2223
N2223
Figure-4 DIN Rail Mounting Method.
F-26887-4
5
Wiring
The following electrical connections can be made to MN 110 and MN 130 controllers:
• Communications wiring, including:
• S-LK wiring between an MN 110 or MN 130 controller and an MN-Sx TAC I/A Series
MicroNet Sensor.
• TAC MicroNet LONWORKS network (LON) connection, including connections to
other MNL-type TAC MicroNet controllers.
• I/O connections, including:
• Three Universal Inputs (UIs)
• One (MN 110) or three (MN 130) high-voltage relay output(s)
• Four Triac digital outputs
• LONWORKS Network Jack
• 24 Vac nominal class 2 (EN 60742) power source and earth ground power connection
Ground
GND
0V
24VAC
UI3
COM 0V
UI2
COM 0V
UI1
S-LK
S-LK
LON
LON
DO1
24VAC
DO2
DO3
Digital (Triac)
Outputs
24VAC
DO4
I/A Series
MNL-11R
DO1
24VAC
DO2
DO3
GND
24VAC
DO4
0V
24VAC
UI3
UI: 5VDC Max, Class 2.
S-LK: 16VDC Max, Class 2.
DO5: 250VAC, 3A Max, COS f = 0.4.
COM 0V
UI2
COM 0V
UI1
S-LK
S-LK
934G
E9429
3.3
C5
TAC MicroNet LONWORKS
Network Connection
J1
N2223
DO5
TAC MicroNet
Sensor Inputs
LON
LONWORKS Network
(LON) Jack
C5
High-Voltage
Relay
Universal
Inputs
LON
DO5
24Vac Power
(Transformer)
SRVC
X
M
I
T
CAUTION
R
E
C
V
S
R
V
C
Service Pin
This device conforms 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.
LEDs
This Class B digital apparatus meets all requirements of the Canadian Interference-Causing Equipment Regulations.
Cet appareil numerique de la classe B respecte toutes les exigences du Reglement sur le material brouilleur du Canada
Figure-5 MN 110 Terminal Connections.
Ground
DO1
Digital (Triac)
Outputs
24VAC
DO2
DO3
I/A Series®
MNL-13R
24VAC
DO1
DO4
DO2
DO3
24VAC
UI: 5VDC Max, Class 2
S-LK: 16VDC Max, Class 2
DO5-DO7: 250VAC, 3A Max,
COS Φ = 0.4
GND
24VAC
DO4
0V
24VAC
UI3
COM 0V
UI2
DO7
DO7
High-Voltage
Relays
C7
DO6
C6
DO5
C5
COM 0V
UI1
C7
DO6
934G
E9429
C6
S-LK
S-LK
LON
N2223
LON
3.3
DO5
GND
0V
24VAC
UI3
COM 0V
UI2
COM 0V
UI1
S-LK
S-LK
LON
LON
Universal
Inputs
TAC MicroNet
Sensor Inputs
TAC MicroNet LONWORKS
Network Connection
J1
C5
CAUTION
24Vac Power
(Transformer)
SRVC
X
M
I
T
R
E
C
V
S
R
V
C
This device conforms 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.
This Class B digital apparatus meets all requirements of the Canadian InterferenceCausing Equipment Regulations.
Cet appareil numerique de la classe B respecte toutes les exigences du Reglement
LONWORKS Network
(LON) Jack
Service Pin
LEDs
Figure-6 MN 130 Terminal Connections.
6
F-26887-4
Communications
Wiring
Communications wiring includes wiring between the MN 110 or MN 130 controller and one
MN-Sx TAC I/A Series MicroNet Sensor, as well as wiring between the MN 110 or MN 130
controller and a TAC MicroNet LONWORKS Network (LON). For additional information on the
TAC I/A Series MicroNet Sensors, including a list of available inputs, refer to the TAC
I/A Series MicroNet Sensor General Instructions, F-26277.
S-Link and LON Wiring Precautions
Caution:
• Communication wire pairs must be dedicated to S-Link and LON communications. They
cannot be part of an active, bundled telephone trunk.
• The LON and S-LK cables must be installed within grounded metallic conduit or
conductive cable trays to fully comply with the EMC requirements of EN61326.
• Shielded cable is not required for S-Link or LON communications wiring. If shielded wire
is used, the shield must be connected to earth ground at only one end, using a 470k
ohm 1/4 watt resistor, and the shield must be continuous from one end of the trunk to
the other.
• Conduit between a TAC I/A Series MicroNet Sensor and a controller can be shared by
S-LK wiring and LON wiring, provided that this conduit does not also contain wiring for
power, UI, AO, DI, or DO. However, the S-Link and LON wiring must be separate
cables.
Sensor Link (S-Link) Wiring
Using S-LK wiring, an MN 110 or MN 130 controller may be connected to one MN-Sx TAC
I/A Series MicroNet sensor. S-Link wiring powers and enables the sensor. The S-Link
requires at least 0.205 mm2 (#24 AWG), twisted pair, voice-grade telephone wire. The
capacitance between conductors cannot be more than 32 pF per 0.3 m (1 ft). If shielded
cable is used, the capacitance between any one conductor and the others, connected to the
shield, cannot be more than 60 pF per 0.3 m (1 ft). The maximum wire length is 61 m
(200 ft).
Note:
• The MN 110 or MN 130 controller can support one MN-Sx TAC I/A Series MicroNet
Sensor.
• S-Link wiring is not polarity-sensitive.
Connect the MN 110 or MN 130 controller to an MN-Sx TAC I/A Series MicroNet Sensor as
follows:
1. Strip 6 mm (1/4 in.) of insulation from one end of the S-LK wires.
2. Connect the stripped wires to the S-LK terminals of the controller (Figure-5 or Figure-6).
The S-LK connection is not polarity-sensitive.
3. Strip 6 mm (1/4 in.) of insulation from the other end of the S-LK wires.
MN-Sx Series
TAC I/A Series
MicroNet Sensor
MNL-11RFx
MNL-13RFx
1
1
S-LK
1
S-LK
2
S-Link
Terminals
1 The S-Link connection is
not polarity sensitive.
Figure-7 MN 110 and MN 130 S-Link Terminal Connections.
4. Connect the other end of the S-LK wires to the sensor, according to the TAC I/A Series
MicroNet Sensor General Instructions, F-26277.
F-26887-4
7
TAC MicroNet LONWORKS Network (LON) Wiring
Approved Category 4 or 5, twisted-pair (two conductors) cable may be used for the
LONWORKS Network connection between the MN 110 or MN 130 controller and a TAC
MicroNet LONWORKS Network, or for the optional LONWORKS Network connection between
the controller and an MN-Sx TAC I/A Series MicroNet Sensor.
Caution:
• See the section, “S-Link and LON Wiring Precautions,” on page 7.
• Do not mix LON network wiring with power, UI, AO, DI, or DO types of wiring.
• Conduit between an MN-Sx TAC I/A Series MicroNet Sensor and a controller can be
shared by LON wiring and S-LK wiring, provided that this conduit does not also contain
wiring for power, UI, AO, DI, or DO. However, the S-Link and LON wiring must be
separate cables.
Note: For complete details on designing and wiring TAC MicroNet networks, including
approved cable models, refer to the TAC I/A Series MicroNet System Engineering Guide,
F-26507.
Connect the MN 110 or MN 130 controller to a TAC MicroNet LONWORKS Network or an
MN-Sx TAC I/A Series MicroNet Sensor as follows:
1. Strip 6 mm (1/4 in.) of insulation from one end of the LON wires.
2. Connect the stripped wires to the LON terminals of the controller (Figure-8). The LON
connection is not polarity-sensitive.
3. Strip 6 mm (1/4 in.) of insulation from the other end of the LON wires.
MNL-11RFx
MNL-13RFx
1
LON
LON
TAC MicroNet
LONWORKS
Network
1 The LONWORKS connection is not polarity sensitive.
Figure-8 MN 110 and MN 130 LONWORKS Network Terminal Connections.
4. If the MN 110 or MN 130 controller is to be connected to a LONWORKS network,
determine the topology chosen for the TP/FT-10 segment, then connect to additonal
controllers. To allow the MN 110 or MN 130 to share data with other LONWORKS
devices, the controller must be addressed and the desired network bindings must be
made. Refer to the section, “Installation on a LONWORKS Network,” to accomplish this.
Note:
• The MN 110 and MN 130 controllers use the LONWORKS Free Topology Transceiver
(FT 3150®). It may be connected to other controllers freely, using multiple wiring
tees and stars (Free Topology) or using a daisy-chain topology. If a daisy-chain
topology is chosen, the controllers must be connected only in a device-to-device
fashion (Bus Topology). A maximum of 62 nodes can be connected per wiring
segment.
• See the TAC I/A Series MicroNet System Engineering Guide, F-26507, to design a
TAC MicroNet LONWORKS TP/FT-10 network, including recommended topologies
and approved cable types.
5. If the MN 110 or MN 130 controller is to be wired to a TAC MicroNet sensor, make the
LONWORKS Network connection according to the TAC I/A Series MicroNet Sensor
General Instructions, F-26277.
8
F-26887-4
Note:
• Use of the LON terminals to connect to the MN-Sx sensor permits use of the
sensor’s built-in LONWORKS Network Jack.
• To preserve the integrity of the network, the LONWORKS Network wiring connecting
a TAC I/A Series MicroNet controller to an MN-Sx sensor must be run to the sensor
and back, in daisy-chain fashion. A wire “spur” must not be used to connect the
sensor to the controller.
• While the MN-Sx sensor is not counted as a “node” in the LONWORKS Network
(LON), all LONWORKS Network wiring to the sensor must be counted when
determining the length of the TP/FT-10 wiring segment.
6. Install terminators as required.
I/O Wiring
I/O connections include three software-configured universal inputs (UIs), one (MN 110) or
three (MN 130) high-voltage relay output(s) (DOs), and four Triac outputs. The Triac outputs
are for switching 24 Vac pilot-duty loads. See Figure-5 and Figure-6 for wire terminal
information.
Warning: Electrical shock hazard. Remove all power from both the controller and digital
outputs before making terminations.
UI, AO, and DI wiring require at least 0.205 mm 2 (#24 AWG), twisted pair, voice grade
telephone wire. The capacitance between conductors cannot be more than 32 pF per 0.3 m
(1 ft). If shielded cable is used, the capacitance between any one conductor and the others,
connected to the shield, cannot be more than 60 pF per 0.3 m (1 ft). Refer to Table-1 for
wiring specifications.
Table-1 UI, AO, and DI Wiring Specifications.
Connection
UI, AO, and DI
Gage
mm2 (AWG)
Maximum Distance
m (ft)
0.823 (18)
91 (300)
0.518 (20)
61 (200)
0.326 (22)
38 (125)
0.205 (24)
23 (75)
Universal Inputs (UI)
The Universal Inputs’ characteristics are software-configured to respond to one of the
following input types:
1. 10K ohm Thermistor with 11K ohm Shunt Resistor (refer to Figure-9).
2. 10K ohm Resistive.
3. 1K ohm Balco (refer to Figure-10).
4. 1K ohm Platinum (refer to Figure-10).
5. 1K ohm Resistive.
6. Analog Voltage (refer to Figure-11).
7. Analog Current (refer to Figure-12).
8. Digital Dry Switched Contact (refer to Figure-13).
Caution:
• If shielded cable is used for universal inputs (UI), connect only one end of the shield
to a single COM 0V terminal (not to GND).
• If shielded cable is used for other I/O, connect only one end of the shield to a single
earth ground point, at the controller’s ground (GND) terminal.
• Input and output devices cannot share common wiring. Each connected device
requires a separate signal and return conductor.
• UI, S-Link, and LON wiring cannot share a conduit with either power wiring or
high-voltage relay wiring.
F-26887-4
9
Note: UI and S-Link wiring can share a single conduit.
10K Thermistor with 11K Shunt Resistor
Any of the MN 110 or MN 130 controller’s UI inputs can be configured for Thermistor input.
When configured in this way, a 10K ohm Thermistor with 11K ohm shunt resistor (TAC
TSMN-57011-850) may be connected to the MN 110 or MN 130 controller to sense the
space temperature. See Table-2 for temperature versus resistance data for this thermistor.
Table-2 Temperature Versus Resistance for TSMN-57011-850 Thermistor.
Temperature
°C (°F)
Resistance
ohms
Temperature
°C (°F)
Resistance
ohms
4 (40)
7596
30 (86)
4696
10 (50)
6938
40 (104)
3707
20 (68)
5798
50 (122)
2875
25 (77)
5238
60 (140)
2206
Make the Thermistor connections according to the diagram in Figure-9.
MNL-11RFx
MNL-13RFx
1
UI1
COM 0V
TSMN-57011-850
1
Any one of the three Universal Inputs (UI1, UI2,
or UI3) may be programmed for Thermistor
input. Connection to UI1 is illustrated here as an
example only.
2
Applications that use a non-850 series 10K
thermistor sensor require an 11K ohm Shunt
Resistor Kit, AD-8969-206. Install this resistor
across the Universal Input and the Common.
2
1
10K ohm
Thermistor
2
11K ohm
± 0.1%
Shunt
Resistor
Figure-9 Typical Wiring for 10K Thermistor with 11K Shunt Resistor (TSMN-57011-850).
Resistive — 1K Balco or 1K Platinum Input
Any of the MN 110 or MN 130 controller’s UI inputs can be configured for the 1K Balco or
Platinum Element Resistive Sensor. Make the connections according to the diagram in
Figure-10.
MNL-11RFx
MNL-13RFx
1
1K Resistive Sensor
Balco or Platinum
Element
UI1
COM 0V
1
Any one of the three Universal Inputs (UI1, UI2,
or UI3) may be programmed for Balco or
Platinum Sensor input. Connection to UI1 is
illustrated here as an example only.
Figure-10 Typical Wiring for 1K Balco or 1K Platinum Sensor Input.
10
F-26887-4
Analog Voltage Input
Any of the MN 110 or MN 130 controller’s UI inputs can be configured for the 0 to 5 Vdc
Analog Voltage Transmitter input. Make the connections according to the diagram in
Figure-11.
MNL-11RFx
MNL-13RFx
1
0 to 5 Vdc
Transmitter
Power
Source
+
UI1
COM 0V
_
1
Any one of the three Universal Inputs (UI1, UI2, or UI3) may be
programmed for 0 to 5 Vdc Analog Voltage input. Connection to
UI1 is illustrated here as an example only.
2
Input signals of 1 to 11 Vdc must be converted to 0.45 to 5 Vdc
with a Voltage Divider, AD-8961-220.
Figure-11 Typical Wiring for 0 to 5 Vdc Analog Voltage Input.
Analog Current Input
Any of the MN 110 or MN 130 controller’s UI inputs can be configured for the 4 to 20 mAdc
Analog Current Transmitter input. Make the connections according to the diagram in
Figure-12.
MNL-11RFx
MNL-13RFx
1
4 to 20 mA
Transmitter
+
UI1
250 ohm
2
COM 0V
Power
Source
1
programmed for 4 to 20 mAdc Analog Current input. Connection
to UI1 is illustrated here as an example only.
2
Input signals of 4 to 20 mAdc must be converted to 1 to 5 Vdc
with a 250 ohm Shunt Resistor Kit, AD-8969-202. Install the
resistor across the Universal Input and Common terminals.
_
Figure-12 Typical Wiring for 4 to 20 mA Analog Current Input.
Digital Dry Switched Contact Input
Any of the MN 110 or MN 130 controller’s UI inputs can be configured for the Digital Dry
Switched Contact input. Make the connections according to the diagram in Figure-13.
Note: If the maximum closed switch voltage is not more than 1.0 V and the minimum open
switch voltage is at least 4.5 V, then solid state switches may be used for a UI when
configured as a DI.
MNL-11RFx
MNL-13RFx
1
Digital Dry
Switched
Contact
UI1
1
programmed for Digital Dry Switched Contact input. Connection
to UI1 is illustrated here as an example only.
2
Switched contact resistance must be less than 300 ohms for
closed contact and greater than 1.5K ohms for open contact.
2
COM 0V
Figure-13 Typical Wiring for Digital Dry Switched Contact Input.
F-26887-4
11
Digital Triac Outputs (DOs)
The MN 110 and MN 130 controllers contain four 24 Vac (digital) Triac outputs. Before wiring
these outputs, refer to Table-3 for their electrical specifications.
Table-3 Triac Output Electrical Specifications.
Characteristic
Specification
Maximum Triac Switched Output Voltage 24 Vac terminal voltage a
Minimum Triac Switched Output Voltage
24 Vac terminal voltage a - 2.0 Vac
Rating
12 VA (0.5 A) @ 24 Vac at each output.
Total of 12 VA @ 24 Vac for all outputs that are ON at any
one time.
Motor Requirements
NA
Default Output State
OFF (inactive)
Output Short Circuit Protection
Internal current limiting
Maximum Off-State Leakage Current
2.0 mA
Minimum Permissible Load
50 mA
a
Switched output voltage is equivalent to the value of the input voltage.
Caution:
• Do not mix DO wiring with power, high-voltage relay, DI, UI, S-Link, LON, or AO wiring.
• The total output load for DO1 through DO4 is 12 VA. This limit applies whether one, two,
three, or all four DOs are ON at the same time. Exceeding this limit may result in the
loss of controller power until the external fault is removed and the internal PTC (Positive
Temperature Coefficient) device cools sufficiently. The PTC is a current-limiting thermal
safety device.
Triac output terminals accept one 0.823 mm2 (#18 AWG) or smaller wire. The selected
wire gage must be consistent with the load current rating.
•
Note:
• DO1 through DO4 are Triac outputs for switching 24 Vac loads only, such as pilot-duty
relays and floating control actuators.
• Triac outputs switch the load circuit to ground and are supplied through the 24VAC
terminals.
Connect the MN 110 or MN 130 controller’s Triac output terminals (DO1, DO2, DO3, and
DO4) as follows:
1. Connect one side of a 24 Vac load to one of the 24VAC terminals.
Caution: Whenever the MN 110 or MN 130 is connected to share I/O with other
controllers, care must be exercised to connect the power for the inputs in a consistent
manner. Refer to the wiring diagram on the cover.
2. Connect the other side of the load to a Triac output terminal (DO1, DO2, DO3, or DO4).
See Figure-14.
24 Vac Load
(Cooling)
Open B3
1
COM
R1
MNL-11RFx
MNL-13RFx
DO1
24Vac
Close W2
DO2
24 Vac Load
(Heating)
Open B3
DO3
1
COM
R1
Close W2
24Vac
DO4
0V
24Vac
1 The example shown here is for controlling two 24 Vac floating valve actuators (e.g. MF-631x3 Series).
Figure-14 24 Vac Loads Switched by Triac Outputs.
12
F-26887-4
High-Voltage Relay Output
The MN 110 controller contains one high-voltage relay output and the MN 130 controller
contains three such outputs. Before wiring a high-voltage output, refer to Table-4 for its
electrical specifications.
Table-4 High-Voltage Relay Output Load Specifications.
Specification
Value
Maximum Relay Contact Switched Output Voltage
250 Vac
Maximum Output Load (cos φ = 0.4)
3.0 A
Minimum Controllable Load @ 5 Vdc
10.0 mA
Maximum Off-State Leakage Current
100 µA
Minimum Cycles at Rated Load @ 0.4 Power Factor
100,000 cycles
Caution:
• Do not mix high-voltage relay wiring with any other controller wiring.
• High-voltage relay terminals accept one 2.08 mm2 (#14 AWG) or smaller wire. The
selected wire gage must be consistent with the load current rating.
Connect the MN 110 or MN 130 controller’s high-voltage relay terminal(s) (DO5 and C5 for
the MN 110; DO5, C5, DO6, C6, DO7, and C7 for MN 130) to 230 Vac power and the
switched 230 Vac motor(s) as shown in Figure-15 and Figure-16.
MNL-11RFx
230 Vac
3A Motor
DO5
C5
230 Vac
Power
Figure-15 MN 110 Connection to 230 Vac High-Voltage Relay.
MNL-13RFx
230 Vac
3A Motor
#3
DO7
C7
230 Vac
Power
DO6
230 Vac
3A Motor
#2
C6
230 Vac
Power
DO5
230 Vac
3A Motor
#1
C5
230 Vac
Power
Figure-16 MN 130 Connections to 230 Vac High-Voltage Relays.
F-26887-4
13
Power Supply Wiring
Power Supply Wiring Precautions
Caution:
• The MN 110 and MN 130 controllers contain a non-isolated half-wave rectifier power
supply and must not be powered by transformers used to power other devices
containing non-isolated full-wave rectifier power supplies. Refer to EN-206, Guidelines
for Powering Multiple Full-Wave and Half-Wave Rectifier Devices from a Common
Transformer, F-26363, for detailed information.
• Do not mix power wiring or high-voltage relay wiring with any other controller wiring.
• Use a Class 2 power transformer supplying a nominal 24 Vac (20.4 to 30 Vac),
50/60 Hz. It must have a minimum rating of 9.5 VA plus the DO1 through DO4 total
output load of 12 VA maximum, up to a total of 21.5 VA per controller. In the European
Community, a safety-isolating SELV (Safety Extra Low-Voltage), limited energy source
(<100 VA) transformer that conforms to EN 60742 must be used.
• The transformer frame must be grounded, and the supply to the transformer must have
a circuit breaker or disconnect.
Note:
• 24 Vac power wiring can be intermixed with DO wiring.
• Twisted or untwisted cable can be used for power wiring.
• To preserve the integrity of the network, the LONWORKS Network wiring connecting a
TAC I/A Series MicroNet controller to an MN-Sx sensor must be run to the sensor and
back, in daisy-chain fashion. A wire “spur” must not be used to connect the sensor to
the controller.
Power Wiring
Refer to Figure-17 and Figure-18 for acceptable wiring configurations.
1. Connect the power ground wire to the Ground terminal (GND).
2. Connect the 24 Vac power wiring to the power terminals (24 VAC and 0V).
24 Vac
Secondary
Class 2
Primary
S-Link
MN-Sx
Sensor
1
LON
LON
LON
S-LK
S-LK
0V
24VAC
GND
2
MNL-11RFx
MNL-13RFx
To rest of the LONWORKS
network
1
Optional connection provides local
access to the LONWORKS network.
2
Ground the frame of the transformer
to a known ground.
Figure-17 Power Supply Connection — Single Controller Powered from a Separate Class 2 Power Source.
14
F-26887-4
To other TAC MicroNet LONMARK
and LONWORKS Controllers
24 Vac
Secondary
Class 2
Primary
To rest of the
LONWORKS network
S-Link
MN-Sx
Sensor
LON
LON
S-LK
S-LK
0V
24VAC
GND
2
LON
1
MNL-11RFx
MNL-13RFx
3
S-Link
LON
LON
S-LK
S-LK
24VAC
0V
GND
MN-Sx
Sensor
LON
1
MNL-11RFx
MNL-13RFx
S-Link
1
LON
LON
S-LK
LON
S-LK
24VAC
0V
GND
MN-Sx
Sensor
MNL-11RFx
MNL-13RFx
S-Link
1
LON
Class 2 wiring.
LON
3
S-LK
Ground the frame of the transformer
to a known ground.
LON
S-LK
2
24VAC
Optional connection provides local
access to the LONWORKS network.
0V
1
GND
MN-Sx
Sensor
MNL-11RFx
MNL-13RFx
To rest of the
LONWORKS network
Figure-18 Power Supply Connection — Multiple Controllers Powered from a Separate Class 2 Power Source
and Sharing Communications in a Free Topology Segment.
F-26887-4
15
Installation on a
LONWORKS Network
In addition to functioning in standalone mode, the MN 110 or MN 130 controller may be
connected to a LONWORKS network for data sharing with other LONWORKS devices. This is
made possible by addressing the controller on the network and performing the desired
network bindings.
LONWORKS Network Addressing
Address the controller on the LONWORKS network, as follows:
1. Verify that the controller is powered and connected to the network.
2. Perform the necessary steps to configure the controller, using the TAC WorkPlace Tech
Tool (WP Tech). This involves the creation and downloading of control logic to the
controller. Refer to the TAC WorkPlace Tech Tool 4.0 User’s Guide, F-27255.
Note: The TAC WorkPlace Tech Tool must be Version 4.0 or greater when it is used to
configure the MN 110 and MN 130 controllers on a LONWORKS network.
3. Using an appropriate network management tool, proceed to address the controller on
the LONWORKS network, up to the point at which the tool asks for the controller’s unique
Neuron® ID. This address will consist of a domain, subnet, and node.
4. Obtain the controller’s Neuron ID, using either of the following methods:
Service Pin Button
a.
Make the network tool “listen” for the service pin message.
b.
Press and release the controller’s service pin button. This sends a broadcast
message containing the controller’s Neuron ID (the controller’s LONWORKS serial
number). Service pin messages can be sent from a controller, whether addressed
or not, as many times as necessary.
Caution: Do not hold the service pin button in the pressed position. Holding the
service pin button for 6 seconds or longer will completely unconfigure the
controller.
Note: If an MN-S2, MN-S3, MN-S4, or MN-S5 sensor is connected to the
controller, the sensor’s override button can also be used to generate a service pin
message from the controller. For more information, refer to the TAC I/A Series
MicroNet Sensor General Instructions, F-26277.
Manual Method
a.
Indicate to the network tool that you will enter the Neuron ID manually.
b.
Locate the controller’s Neuron ID. The MN 110 or MN 130 controller’s Neuron ID is
printed on a pair of barcode labels attached to the controller at the factory. One of
the labels remains on the controller permanently, while the other label can be
detached and placed on a job site’s node list plan.
c.
Manually enter the Neuron ID into the tool, or scan the barcode.
5. Proceed to finish commissioning the controller on the LONWORKS network.
Network Bindings
Using an appropriate network management tool, perform the desired network bindings to
enable the sharing of data over the LONWORKS network. Refer to the TAC I/A Series
WorkPlace Tech Tool 4.0 Engineering Guide, F-27254, for information on the network
variables available in the MN 110 or MN 130 controller’s Fan Coil profile.
16
F-26887-4
Checkout
Mechanical Hardware Checkout
1. If an MN-Sx TAC I/A Series MicroNet Sensor is connected to the controller, verify that
the wiring between the sensor and the controller is installed according to the job wiring
diagram and national and local wiring codes.
Note: Wiring of the S-Link and TAC MicroNet LONWORKS network between the sensor and
the controller is not polarity sensitive.
2. If the controller is part of a TAC MicroNet LONWORKS network, verify that the TP/FT-10
LONWORKS network wiring between the controller and other devices is installed
according to the job wiring diagram and the national and local electrical codes.
3. Verify that 24 Vac power is provided from a Class 2 power transformer, and that wiring
is installed according to the job wiring diagrams and the national and local electrical
codes.
4. If multiple devices are powered from the same transformer (Figure-18), verify that wiring
polarity has been maintained between all connected devices, and that all other issues
associated with powering multiple devices from a common transformer have been
addressed.
Note: For more information, refer to EN-206, Guidelines for Powering Multiple Full-Wave
and Half-Wave Rectifier Devices from a Common Transformer, F-26363.
5. Verify that the digital outputs and the high-voltage relay(s) are wired according to the
job wiring diagram and the national and local electrical codes.
6. Make certain that the current requirements of the controlled device do not exceed the
rating of the controller’s digital outputs.
Communications Hardware Checkout
In addition to functioning in standalone mode, the MN 110 or MN 130 controller may be
connected to a LONWORKS network for data sharing with other LONWORKS devices. If so,
check the status of its network communications according to the following procedure:
1. Verify that all controlled equipment is in a manually controlled, safe state.
2. Place the controller’s power circuit breaker in the ON position. See the job wiring
diagrams for the location of this breaker.
3. Observe the green Data Transmission LED (Figure-19) and do the following:
a.
If the green Data Transmission LED is steady ON or blinking, go to step 4.
b. If the green Data Transmission LED is OFF, check the power to the controller.
4. Observe the red Service LED (Figure-19) and do the following:
a.
If the red Service LED is off or flashing, proceed with downloading an application
using TAC WorkPlace Tech Tool and configuring the controller with a third party
network management tool. Refer to TAC WorkPlace Tech Tool 4.0 Engineering
Guide, F-27254, for details on downloading applications.
b. If the red Service LED is steady ON, turn OFF the power to the controller, wait five
seconds, then turn the power ON. If the red Service LED is still steady ON, turn the
power OFF and replace the controller.
5. If necessary, perform additional checks and take the appropriate corrective action,
according to Table-5.
F-26887-4
17
Power and Data
Transmission LED
(Green)
Data Reception LED
(Amber)
LONWORKS
Network Jack
Service LED
(Red)
Service Pin
Figure-19 Location of Controller LEDs.
18
F-26887-4
Table-5 LED Indication.
Indicator
Data Reception LED – amber
Context
Anytime
Status
Corrective Action
Blinks when the controller receives data from the
LONWORKS Network.
None required.
On indicates a possible network connection problem, or
a large amount of network traffic is present.
Remove the LONWORKS Network
connections from the controller and
determine if the LED goes off. If the
LED does not go off, replace the
controller. If the LED does go off,
check the network topology (connections to each node, routers, terminators, etc.) and the amount of
traffic on the network.
Off indicates that data reception is not taking place.
Blinks when the controller transmits data to the
LONWORKS Network.
Data Transmission LED –
Green
Anytime
Off indicates no power to controller.
Check power
Power-up
The LED blinks once to indicate successful power-up.
Wink mode
Blinks (3 seconds on, 1 second off) three times to
indicate physical location of the controller. If a sensor
(MN-Sx) is connected, its red occupancy LED will flash
(1/sec) during the wink period.
Anytime
On indicates that the neuron application is not running.
Neuron applications are not field replaceable.
Replace the controller.
Blinks (1/sec) to indicate that the neuron application is
loaded, but the neuron’s communication parameters
are not loaded, are being reloaded, or have been
corrupted. Neuron is considered unconfigured.
Communication parameters cannot be configured by
field personnel.
Use a third party network management tool to commission the controller, or use the change state tool in
TAC WorkPlace Tech Tool (version
4.0 or greater) to set the Neuron® to
the configured/on-line state.
While the controller is unconfigured,
WP Tech can be used to download
an application, but at the completion
of the download, WP Tech versions
4.0 and higher will restore the Neuron to the unconfigured state.
Anytime
Off may indicate that the neuron application is loaded
but the device is off-line. In this state, a pre-loaded
HVAC application will not run.
Use a third party network management tool to commission the controller, or use the change state tool in
TAC WorkPlace Tech Tool (version
4.0 or greater) to set the Neuron to
the configured/on-line state.
While the controller is off-line, WP
Tech can be used to download an
application, but at the completion of
the download, WP Tech versions 4.0
and higher will restore the Neuron to
the off-line state.
Anytime
Off usually indicates a normal state. In this state, the
controller operates normally, and you can download
and/or run HVAC applications.
If the controller is able to accept
and/or run a downloaded HVAC
application, no action is required.
Anytime
Service LED – Red
F-26887-4
None Required
On indicates that the controller is not transmitting data.
On also indicates that power is being applied to the
controller.
None Required
19
Service
Components within the MN 110 and MN 130 controllers cannot be field repaired. If there is
a problem with the controller, follow the steps outlined in the “Checkout“ section. If the
problem persists, record the following hardware setup information before contacting your
local Invensys Building Systems office:
•
•
•
•
Copyright 2006, TAC
All brand names, trademarks and registered
trademarks are the property of their respective
owners. Information contained within this
document is subject to change without notice.
Version number of the application software.
The controller’s firmware version number.
Information regarding the network management tool being used.
A complete description of the difficulties encountered.
TAC
1354 Clifford Avenue
P.O. Box 2940
Loves Park, IL 61132-2940
F-26887-4
www.tac.com
Distributed, manufactured, and sold by TAC. I/A SERIES trademarks
are owned by Invensys Systems, Inc. and are used on this product
under master license from Invensys. Invensys does not manufacture
this product or provide any product warranty or support. For service,
support, and warranty information, contact TAC at 1-888-444-1311.

MNL-11RFx MNL-13RFx

Transkrypt

Podobne dokumenty

- Odbiory.pl

MNL-5Rxx - Odbiory.pl

MNL-10Rxx Series MNL-15Rxx Series MNL-20Rxx Series

MNL-V3RVX - Odbiory.pl

MNL-PROV-WAL

SC 200 Digital Controller, 2 x Digital, 3x extra mA OUT

radio controller rx-2k satel

remote controlled tv switch mst-01