Johnson Controls TSS, TSL Installation Operation & Maintenance

SINGLE DUCT VAV TERMINALS

INSTALLATION, OPERATION & MAINTENANCE

New Release

MODELS TSS & TSL

TSS

Form 130.13-NOM1 (114)

TSL

FORM 130.13-NOM1 (114)

TABLE OF CONTENTS

SAFETY CONSIDERATIONS ........................................................................................................................3

INSPECTION .................................................................................................................................................4

STORAGE .....................................................................................................................................................4

PRE-INSTALLATION INSPECTION ..............................................................................................................5

SEQUENCE OF OPERATION .......................................................................................................................5

Single Duct .............................................................................................................................................5

INSTALLATION .............................................................................................................................................5

Clearances .............................................................................................................................................5

Hanging and Mounting Equipment ......................................................................................................5

Unit Weights ...........................................................................................................................................6

Duct Connections
Critically Sound Applications

Coil Connections ...................................................................................................................................7

Electrical .................................................................................................................................................7

OPERATION ..................................................................................................................................................7

Start-Up ..................................................................................................................................................7

3 Phase Balancing .................................................................................................................................7

MAINTENANCE ............................................................................................................................................8

Optional Damper Actuator ....................................................................................................................8

Manual Override ....................................................................................................................................8

Mechanical Angle of Rotation Stops ...................................................................................................8

External Terminal Strip .........................................................................................................................8

Overload Protection ..............................................................................................................................8

Checkout Instructions ...........................................................................................................................8

Damper Shaft .........................................................................................................................................8

Coil ..........................................................................................................................................................8

Cleaning ............................................................................................................................................9

Electric Heat ..........................................................................................................................................9

Minimum Operating Conditions ......................................................................................................9

Electric Heater Rack Replacement .................................................................................................9

Electric Heater Element Replacement ............................................................................................9

Heater Troubleshooting Guide ......................................................................................................10

(SSR) Troubleshooting Guide .......................................................................................................11

..................................................................................................................................6

...............................................................................................................7

Calibration Charts ...............................................................................................................................15

2

JOHNSON CONTROLS

FORM 130.13-NOM1 (114)

SAFETY SYMBOLS

The following symbols are used in this document to alert the reader to areas of potential hazard:

DANGER indicates an imminently
hazardous situation which, if not
avoided, will result in death or serious
injury.

WARNING indicates a potentially
hazardous situation which, if not

avoided, could result in death or se-

rious injury.

SAFETY CONSIDERATIONS

The equipment covered in this manual is designed for
safe and reliable operation when installed and operated

within its’ design specication limits. To avoid personal

injury or damage to equipment or property while
installing or operating this equipment, it is essential

that qualied, experience personnel familiar with local

codes and regulations, perform these functions using

good judgment and safe practices. See the following
cautionary statements.

ELECTRICAL SHOCK HAZARDS

All power must be disconnected prior

to installation and servicing this equip-

ment. More then one source of power
may be present. Disconnect all power
sources to avoid electrocution or shock
hazards.

HOT PARTS HAZARD

Electric resistance heating elements

must be disconnected prior to servic­ing. Electric heaters may start auto-

matically; disconnect all power and
control circuits prior to servicing to
avoid burns.

Check that rigging and lifting equip­ment can safely support the unit as-

sembly and component weights.

CAUTION identies a hazard which
could lead to damage to the machine,
damage to other equipment and/or
environmental pollution. Usually an
instruction will be given, together with
a brief explanation.

NOTE is used to highlight additional
information which may be helpful to
you.

All assemblies must be adequately
secured during lifting and rigging by

temporary supports and restraints un-

til equipment is permanently fastened
and set in its’ nal location.

All unit temporary and permanent
supports must be capable of safely
supporting the equipment’s weight and
any additional live, seismic or dead
loads that may be encountered. All

supports must be designed to meet ap-

plicable local codes and ordinances.

All fastening devices must be designed
to mechanically lock the assembly in

place without the capability of loosen-

ing or breaking away due to system
operation and vibration.

Secure all dampers when servicing

damper, actuators or linkage. Damp­ers may activate automatically, discon-

nect the control circuits or pneumatic
control systems to avoid injury.

Protect adjacent ammable material
when brazing. Use ame and heat
protection barriers where needed.

Have re extinguisher ready for im-

mediate use.

JOHNSON CONTROLS

3

FORM 130.13-NOM1 (114)

INSPECTION

Upon receipt of equipment, carefully check all items
against the bill of lading to ensure that all equipment has

been received (including shipped loose items). Note any
discrepancy on the bill of lading before signing.

Inspect all equipment for any signs of damage caused

during transit. On units with re-heat, check the coil
ns and/or ensure that the resistance heat coils are
not damaged. Note any visual damage on the bill of
lading before signing. Immediately report all visual
and concealed damage to the carrier and le a claim
with the carrier.

Locate the model number on the nameplate and check

that the correct units have been received. Verify that all

options have been included, such as controls, heating

coils, etc. Also ensure that unit voltage agrees with the
building parameters. If a discrepancy is discovered

between what was ordered and received, contact your

local Johnson Controls representative immediately.

DO NOT USE FLOW SENSOR,

CONNECTING TUBES, COIL STU-

BOUTS OR DAMPER SHAFT AS

A HANDLE WHEN LIFTING OR

MOVING EQUIPMENT, AS DAM-

AGE MAY OCCUR.

DO NOT HANDLE EQUIPMENT’S

HEATING ELEMENTS, AS PERMA-

NENT DAMAGE MAY OCCUR.

DO NOT work on damper until associ-

ated actuator is disconnected.

NEVER pressurize equipment above
specied test pressure.

PROTECT adjacent ammable ma-

terials when brazing. Use ame and
heat protection barriers where needed.
Have a re extinguisher at hand and
ready for immediate use.

STORAGE

If equipment is to be stored prior to installation, observe
the following precautions:

1. Choose a dry storage site that is reasonably level

and sturdy to prevent undue stress or permanent

damage to the equipment. Set equipment off
ground if in moisture prone areas.

2. Tag and store in a safe place until needed. Cover

entire equipment with protective tarp or moisture

proof cover. Extend cover under equipment if
stored on ground. Secure cover with adequate tie
downs and store indoors. Be sure that piping con­nections have protective shipping caps installed.

CHECK assembly and component
weights to be sure that the rigging
equipment can handle them safely.
Note; also check the centers of gravity
and any specic rigging instructions.

CHECK for adequate ventilation
so fumes do not migrate through
ductwork to occupied spaces when
welding or cutting around the unit.

4

JOHNSON CONTROLS

FORM 130.13-NOM1 (114)

PRE-INSTALLATION INSPECTION

DO NOT USE FLOW SENSOR,

CONNECTING TUBES, COIL STU-

BOUTS OR DAMPER SHAFT AS

A HANDLE WHEN LIFTING OR

MOVING EQUIPMENT, AS DAM-

AGE MAY OCCUR.

DO NOT HANDLE EQUIPMENT’S

HEATING ELEMENTS, AS PERMA-

NENT DAMAGE MAY OCCUR.

Ensure that all linkages are connected properly. Check

the linkage that connects the actuator to the damper shaft

to ensure that the nuts are tight.

While viewing the damper from the discharge of the

unit, rotate the shaft fully. The damper should close

fully and there should be no gaps between the damper

gasketing and the inside of the valve.

INSTALLATION

DO NOT USE FLOW SENSOR,

CONNECTING TUBES, COIL STU-

BOUTS OR DAMPER SHAFT AS

A HANDLE WHEN LIFTING OR

MOVING EQUIPMENT, AS DAM-

AGE MAY OCCUR.

DO NOT HANDLE EQUIPMENT’S

HEATING ELEMENTS, AS PERMA-

NENT DAMAGE MAY OCCUR.

All terminal equipment with electric heaters must

be installed in a horizontal plane with respect to the

airow stream. Low height equipment (Model TSL)
can be ipped over in the eld to vary or change control
section handing.

Clearances

SEQUENCE OF OPERATION

Single Duct

The basic unit consists of a sheet metal casing and an air
valve, which is used to modulate the air being delivered

into the occupied zone. Air enters the air valve inlet
and exits into the sheet metal casing to be distributed

to the occupied zone through ductwork attached to the

discharge of the unit.

The basic unit can be ordered with either a factory

mounted hot water heating coil or an electric heater.

These re-heat units are used primarily to reheat the
air-to-zone temperature when the load in the occupied
space drops off.

The primary air is modulated through the FlowStar™
air valve by rotating the damper blade. The air valves
come in rectangular and round. The round valves only

come in diameters of 4, 5, 6, 8, 10, 12, 14 and 16 inches;

an adapter must be used for metric ductwork.

All equipment covered in this document, including those
with electric heat, are ETL listed for 0.0" clearance to
combustibles. Refer to NEC and/or local codes for
minimum electrical clearances required for service.
Equipment should not make contact with any structure

located above the equipment without appropriate

isolation. Equipment supplied with bottom access
panels requires sufcient clearance to access fasteners,

and to lower and slide panel horizontally until clear of

bottom of unit.

Hanging and Mounting Equipment

Although the basic equipment is generally light enough

that it can be supported by the ductwork, Johnson
Controls strongly recommends that all equipment be
suspended from the upper most ceiling or a structural
element of the building, independent of the false ceiling

grid. Suspension devises are eld supplied, sized and
designed by others. Johnson Controls will not accept
responsibility for unit support. Equipment must be
installed in a level horizontal plane. Failure to level

equipment properly may prevent proper operation of

controls. Provisions for proper support in seismically

active regions is the responsibility of others. See table

1 through 4 for unit weights.

JOHNSON CONTROLS

5

UNIT WEIGHTS

FORM 130.13-NOM1 (114)

TABLE 1 - SINGLE DUCT TERMINAL UNIT WEIGHTS

UNIT
SIZE

SINGLE

04 20 (9) 25 (11) 35 (16) 50 (23) 64 (29) 79 (36)
05 20 (9) 25 (11) 35 (16) 50 (23) 64 (29) 79 (36)
06 19 (9) 24 (11) 34 (15) 49 (22) 62 (28) 77 (35}
08 20 (9) 26 (12) 37 (17) 53 (24) 71 (32) 87 (39)
10 25 (11) 32 (15) 44 (20) 62 (28) 78 (35) 96 (44)
12 28 (13 36 (16) 50 (23) 71 (32) 89 (40) 110 (50)
14 35 (16) 44 (20) 59 (27) 84 (38) 106 (48) 131 (59)
16 37 (17) 47 (21) 63 (29) 90 (41) 113 (51) 140 (64)
19 49 (22) 62 (28) 85 (39) 120 (55) 141 (64) 176 (80)
22 51 (23) 65 (29) 90 (41) 127 (58) 148 (67) 185 (84)

TSS TSS w/ SA TSS w/ EH

SINGLE

WALL

DOU-

BLE

WALL

SINGLE

WALL

DOU-

BLE

WALL

WALL

DOU-

BLE

WALL

TABLE 3 - SINGLE DUCT LOW HEIGHT TERMINAL UNIT
WEIGHTS

UNIT
SIZE

SINGLE

10 26 (12) 30 (14) 43 (19) 58 (26) 62 (28) 77 (35)
12 28 (13) 35 (16) 49 (22) 68 (31) 74 (34) 93 (42)
14 39 (18) 47 (21) 62 (28) 82 (37) 90 (41) 110 (50)
16 45 (20) 55 (25) 73 (33) 96 (44) 103 (47) 126 (57)

TSL TSL w/ SA TSL w/ EH

WALL

DOUBLE

WALL

SINGLE

WALL

DOUBLE

WALL

SINGLE

WALL

DOUBLE

WALL

TABLE 2 - TSS WATER COIL WEIGHT ADDS

UNIT
SIZE

04 4 (2) 5 (2) 8 (4) 12 (5)
05 4 (2) 5 (2) 8 (4) 12 (5)
06 4 (2) 5 (2) 8 (4) 12 (5)
08 4 (2) 6 (3) 9 (4) 13 (6)
10 5 (2) 8 (4) 12 (5) 18 (8)
12 7 (3) 10 (5) 16 (7) 22 (10)
14 9 (4) 14 (6) 21 (10) 30 (14)
16 10 (5) 16 (7) 24 (11) 34 (15)
19 12 (5) 20 (9) 28 (13) 40 (18)
22 13 (6) 22 (10) 32 (15) 44 (20)

Adds for water coils reect actual operating weight.

1 ROW 2 ROW 3 ROW 4 ROW

# OF ROWS

TABLE 4 - TSL WATER COIL WEIGHT
ADDS

UNIT
SIZE

Adds for water coils reect actual operating weight.

1 ROW 2 ROW 3 ROW 4 ROW

10 9 (4) 12 (5) 15 (7) 18 (8)
12 11 (5) 15 (7) 19 (9) 23 (10)
14 13 (6) 18 (8) 22 (10) 27 (12)
16 15 (7) 21 (9) 27 (12) 32 (15)

# OF ROWS

When requested, equipment is supplied with optional

hanger brackets for use with up to a 3/8" diameter

hanger rod. See submittal drawings for hanger bracket

locations.

Hanger straps may be utilized as an alternate means of

suspending the equipment. Do not secure hanger straps
to electric heaters, coils or control enclosures. Hanger

straps can be mounted directly to the sides and bottom
of equipment casing, such that they do not interfere with
working components or access panels, using screws that

do not penetrate the unit cabinet more than 3/8".

When hanging equipment, always use the support
method as prescribed for rectangular duct in the job

specications.

Duct Connections

When fastening ductwork to equip-

ment, DO NOT use fasteners that
penetrate equipment cabinet more

than 3/8" [10mm]. Fasteners penetrat­ing the equipment cabinet over 3/8"

[10mm] may come in contact with live

electrical parts or penetrate other com-

ponents within the equipment casing
causing damage.

All duct connections should be congured and installed
in accordance with SMACNA guidelines and all local
code requirements.

6

JOHNSON CONTROLS

FORM 130.13-NOM1 (114)

Allow a minimum of 1½-duct diameters of straight
duct prior to equipment inlet and equipment discharge.

The diameter of the inlet duct for round valves must

be equal to the listed size of the equipment. The round
air valve inlet collar of the equipment is 1/8" smaller

then listed size in order to allow the round ductwork to

slip over the air valve inlet collar. DO NOT INSERT
DUCTWORK INTO AIR VALVE INLET COLLAR.

When making ductwork connection to air valve inlet
collar and insulating air valve inlet, take caution not to

damage or remove the ow sensor connections, which
are vital to unit control. Provide insulation around entire
inlet collar (all the way to the equipment casing).

Permissible discharge duct connections are straight
anged, slip and drive or drive and screw.

If equipment is to be installed in a location with high

humidity, external insulation around the heating coil
should be installed.

Sound Critical Applications

Flexible duct connectors are not recommended on
equipment discharge. The sagging membrane of these
ttings can cause turbulence and higher air velocities
that generate noise. Also, lightweight membrane

material allows noise to breakout, which can increase

sound levels in the space below.

Coil Connections

Hot water and steam coils are male sweat connections.

Use appropriate brazing alloy for system temperature

and pressure. Refer to unit construction submittal
drawing for specic connection size. MAXIMUM
HYDRONIC SYSTEM OPERATING PRESSURE
MUST NOT EXCEED 300 PSIG. MAXIMUM
STEAM SYSTEM PRESSURE MUST NOT EXCEED
15 PSIG.

Minimum circuit ampacity (MCA) designates the
maximum operating load of the equipment for sizing
wire feeders. Fuse size of the internal fuse if supplied.
Maximum Overcurrent Protection (MOP) designates

the largest breaker or fuse in the electrical service panel

that can be used to protect the equipment.

Use Copper conductors only.

OPERATION

Start-Up

Thorough safety precautions should always be taken

when performing startup and service. Only qualied
individuals should perform these tasks.

Check that all electrical work is nished and properly
terminated. Check that all electrical connections are
tight and that the proper voltage is connected.

3 Phase Balancing

AC power imbalance must not exceed 2%. Be sure that

the following guides are met:

1. AC power is within 10% of rated voltage at rated

frequency. (See equipment nameplate for rat-

ings).

2. AC power is within 5% of rated frequency at rated
voltage.

3. A combined variation in the voltage and frequency
of 10% (sum of absolute values) of rated values,
provided the frequency variation does not exceed
5% of rated frequency.

Equipment with electric heat requires
a minimum of 0.1" w.g. downstream
static pressure.

Electrical

All eld wiring must comply with NEC and all local
codes. Electrical and/or control wiring diagrams are
located on the control enclosure box. All electric heaters
are staged per specications.

The installing electrician should rotate the incoming
electric service by phase to help balance the building

electrical load.

JOHNSON CONTROLS

Prior to start-up, the project control sequence/wiring
diagram should be obtained and thoroughly understood.
If factory supplied analog or DDC controls are utilized,
refer to the applicable Operation Manual for start-up
and balancing information.

7

FORM 130.13-NOM1 (114)

MAINTENANCE

Optional Damper Actuator

An optional factory mounted oating type actuator

is available, which mounts directly to the damper

operating shaft. The actuator is not provided with and

does not require any limit switches but is electronically

protected against overload.

Manual Override

A button on the side of the actuator cover disengages
the gear train so the drain shaft can be moved manually.
Releasing the button will re-engage the gear train.

Mechanical Angle of Rotation Stops

The adjustable stops may be field adjusted to halt
the rotation of the damper blade before the damper

blade reaches the damper stops. The actuator can be
indenitely stalled in any position without harm.

1. Loosen the two end stop screws using a No. 2
Phillips head screwdriver, being careful not to
unscrew the captive nut under the slot.

2. Move the stops (in 2.5° steps) to the desired posi­tion and retighten the screws.

External Terminal Strip

Checkout Instructions

1. Disconnect actuator from the controller.

2. Apply 24 VAC to the COM and CW terminals on
the actuator. Actuator should rotate in a clockwise
direction.

3. Apply 24 VAC to the COM and CCW terminals on
the actuator. Actuator should rotate in a counter
clockwise direction.

4. If actuator moves in both directions, it is opera­tional.

5. If the actuator does not rotate, it may be at an end
stop or there is a problem with the damper.

6. Loosen the set screw to free the actuator from the
damper shaft. Check to make sure that the damper
shaft rotates freely.

7. Check to make sure that actuator is not against
stop. Repeat steps 2 and 3.

8. If actuator does not rotate, replace.

Damper Shaft

There is an indicator on the end of the damper shaft that
can be used to determine the position of the damper

blade. If the indicator is horizontal, the damper is
completely open. The damper shaft is ½" diameter.

The external terminal strip is located on the top of the
actuator. Connections are numbered. The terminals
are designed for 26 to 16 gauge wires. For most

installations, 18 or 16 gauge wire will work well with
the actuator (see table 5 for maximum wire lengths).

TABLE 5 - MAXIMUM WIRE LENGTHS

WIRE SIZE MAX FEET

16 GA 1225 FT
18 GA 725 FT
20 GA 400 FT
22 GA 200 FT

Overload Protection

The actuators are electronically protected against

mechanical overload. In the actuator, an electronic

circuit maintains the current at a level that will not
damage the motor while providing adequate holding

torque.

Coil

The frequency of required cleaning is dependent on the

operating hours of the system, lter maintenance and
efciency as well as dirt load.

Important: Coils may become exter­nally dirty as result of normal opera-

tion. Dirt on the surface of the coil
reduces its ability to transfer heat that
can result in reduced performance,
and increased operating energy cost.
If the dirt on the surface of the coil
becomes wet, microbial growth (mold)

can result, possibly causing unpleas-

ant odors and serious health related
indoor air quality problems.

Fin edges are sharp. Fins are fragile;

care must be exercised to avoid damag-

ing ns. Do not use solutions to clean
coils; drain pans are not present to
remove collected solution.

8

JOHNSON CONTROLS

FORM 130.13-NOM1 (114)

Cleaning

1. Disconnect all electrical power to the equipment,
tag and lock out power source.

2. Gain access to coil either through ductwork or
optional coil access panel.

3. Use soft brush and vacuum to remove loose debris
from sides of coil. Do not use uid or solvents to

clean coils, as no provisions for collecting liquids

exist on this type of equipment.

4. Straighten any coil ns that may have been dam­aged during cleaning process with n comb.

5. Replace ductwork or access panel and restore
electrical power to equipment.

Electric Heat

Johnson Controls electric heaters require little or no

maintenance.

Electric heaters come equipped with a primary auto-reset
limit switch. These limit switches provide protection
against overheating. The auto-reset limits switches

automatically cut the heater off when overheating
occurs, and turns the heater back on when the elements

have cooled down. Electric heaters also come equipped
with a secondary one-time trip limit switch. Should

the secondary limit switches trip, they will need to
be replaced with a limit switch that has the same trip

temperature as the one-time trip limit switch that was
originally supplied with the electric heater. An optional

manual reset secondary is available, which can be reset

by depressing the reset switch.

Minimum Operating Conditions

Airow must be at least 70 CFM per kW. A minimum
of 0.1" w.g. external pressure is required.

Electric Heater Rack Replacement

JOHNSON CONTROLS HEATERS

1. Turn off power supply before servicing.

2. Locate T-Plate inside on heater control enclo­sure.

3. Before removing wires from the element rack
T-Plate, mark where the wires are connected so

that they can be reconnected correctly on the new

element rack.

4. Remove the wires and screws holding the heater
T-plate in the control enclosure and remove ele­ment rack.

5. Insert new element rack into control enclosure and

replace screws to secure the element rack to control

enclosure.

6. Replace wires.

7. Close control enclosure cover before turning on
the power.

Electric Heater Element Replacement

TUTCO HEATERS

1. Turn off power supply before servicing.

2. Disconnect eld wiring from Electric Heater Con­trol Enclosure.

3. Disconnect Amp Plug Connectors if equipped.

4. Remove 4 mounting screws from inside Electric
Heater Control Enclosure.

5. Slide entire heater assembly out of Single Duct
Terminal.

6. Remove wires and any jumpers from heater ele-

ment terminal ends, noting which wire and jumper

goes to which terminal.

7. Remove ¼" hex head screws located near terminal
ends.

8. Remove ¼" hex head screws from opposite of
terminal end on heater rack.

9. Remove elements and replace with new ones.

10. Reassemble, replace wires correctly.

11. Close control enclosure cover before turning on
power.

JOHNSON CONTROLS

9

ELECTRIC HEATER TROUBLESHOOTING GUIDE

FORM 130.13-NOM1 (114)

TABLE 6 - HEATER TROUBLESHOOTING GUIDE

Check wiring diagrams to ensure that heater is properly wired.

SYMPTOM POSSIBLE CAUSE CORRECTIVE ACTION

HEATER DOES NOT OPERATE

LOW OR HIGH TEMPERATURE RISE

SHORT CYCLING

HEATER WITH SSR DOES NOT

OPERATE

JOHNSON CONTROLS AND TUTCO

No Power Check Disconnect.

Check Control Signal (i.e. 24 VAC).

No Control Voltage

Blown Fuse Replace fuse.

Open Limit (primary or secondary)

Airow Incorrect Direction Check sensing tube, rotate if needed.

Low Airow Static Pressure Increase airow.

Damaged Elements

Incompatible Thermostat or Controller

Problems with Additional Stages

Incorrect CFM

Improper Airow

Low CFM

Incorrect Signal Applied Verify signal input.

Interface Board Fuse Blown Replace fuse.

See SSR Troubleshooting (next page)

Check transformer and transformer fus-

ing (if applicable), replace if necessary.

Replace limits or reset as applicable.

Check for continuity across limit to de-

termine if open, replace as necessary.

Check for open or damaged elements
and replace as necessary.

Check Wiring.

Check for compatibility.

Check location of thermostat; may be

installed in a “too hot” or “too cold loca-

tion. Check heat outputs on controller.

Check contactors for open coil.

Check for damaged elements.

Check for blocked duct or location of
heater.

Check for even airow across the face
of the element section.

Check for blocked duct.

Verify installation per SMACNA and
ASHRAE guidelines.

Check for dirty lters.

See remedies for “Improper Airow”.

Check air velocity of 70 CFM per kW.

10

JOHNSON CONTROLS

PROPORTIONAL HEAT CONTROL

(SSR) TROUBLESHOOTING GUIDE

Johnson Controls Heaters

FORM 130.13-NOM1 (114)

Lethal voltages are present in the
heater control enclosure. Use extreme
caution when taking measurements in
these units. Always disconnect power
before removing or re-applying any
connections.

1. Before applying power, verify wiring matches

diagram in cover of heater control enclosure, and
that correct line voltage has been wired to heater

line block.

2. Verify 24 VAC +15% or -10% between P1 and P2
of interface circuit board (ETPHCI, ETPHCV2,
etc., depending on input).

3. The table below lists responses to input signal by
interface model as explained in step 4. If any of

these inputs cannot be obtained, refer to the litera­ture on the device that is supposed to provide the

input. Otherwise, proceed to step 4.

INTERFACE

MODEL
ETPHCI 12.0 mA 4.0 mA 20.0 mA Sig, Com

ETPHCV2 6.0 VDC 2.0 VDC

ETPHCC 50% 0 VAC 24 VAC Sig, Com

ETPHCC1 50% 0 VAC 24 VAC

“PULSE”

INPUT

FULL

OFF

INPUT

4. Apply Full Off Input per table above. If the unit
is three phase, verify that the LED on the SSR
(solid state relay) is off. If the unit is single phase,
measure voltage between P4 and P6 and verify 0.3
VDC + or - 0.3 VDC. Replace the interface circuit
board if the voltage is higher than specied, or the
LED is on.

5. Apply Full On Input per table above. If the unit is
three phase, verify that the LED on the SSR (solid
state relay) is on. If the unit is single phase, mea­sure voltage between P4 and P6 and verify between
3 and 5 VDC.

FULL

ON

INPUT

10.0

VDC

INPUTS

Sig, Com

+18,

Com

6. If the module provided is an ETPHCC or ET­PHCC1, go to step 7. Apply “Pulse” Input per
table above. If the unit is three phase, verify that
the LED on the SSR (solid state relay) is ashing
at an interval of about one second. If the unit is
single phase, the voltage between P4 and P6 of the
interface board should vary between the Full Off
and Full On voltages in steps 4 and 5 in intervals
of about one second.

Some voltmeters will not respond this
quickly, so the value of the voltages
may not appear to be correct; however,
if the voltage appears to be changing

at regular intervals, it may be as-

sumed that this function is operating
properly.

This completes the low voltage portion of the unit

test. Go to step 8.

7. For the ETPHCC or ETPHCC1, the associated

consignment controller must be directed to output

a 50% On pulse width modulation signal. For three
phase, verify that the LED is pulsing at regular
intervals. The rate of the pulse is based on the
output from the consignment controller. If the unit
is single phase, the DC voltage between P4 and P6

of the interface board should vary between the full

Off and full On voltages in steps 4 and 5.

Some voltmeters will not respond this
quickly, so the value of the voltages
may not appear to be correct; however,
if the voltage appears to be changing

at regular intervals, it may be as-

sumed that this function is operating
properly.

JOHNSON CONTROLS

11

8. If the heater always remains energized when power
is applied, remove the wire from P4 of the interface
circuit board. If the heat remains on, there is a
wiring error or the SSR is defective.

Remove Power From the Unit Before
Proceeding With the Next Step.

9. If the heater is always de-energized when power

is applied, remove the line and load connections
to the proportional heat control and temporarily

tie them together. If the system is a three phase
arrangement, do the phases one at a time.

Always remove power from the unit
before moving to the next phase).

FORM 130.13-NOM1 (114)

Make sure there is no danger of the temporary

connection shorting to another component or the

chassis. Briey reapply power. If the section of
heat under test now energizes, the SSR is defective.

If heater still will not energize, one of the heater

safety devices (limits, safety contactor or airow
switch) or elements is defective.

12

JOHNSON CONTROLS

PROPORTIONAL HEAT CONTROL

(SSR) TROUBLESHOOTING GUIDE

Tutco Heaters, All Power Modules

FORM 130.13-NOM1 (114)

JOHNSON CONTROLS

13

FORM 130.13-NOM1 (114)

PROPORTIONAL HEAT CONTROL

(SSR) TROUBLESHOOTING GUIDE

Tutco Heaters, R820 SCR’s

14

JOHNSON CONTROLS

CALIBRATION CHARTS



Flow Star Calibration Chart



Model TSS

FlowStar Calibration Chart

(For dead-end differential pressure transducers)

FORM 130.13-NOM1 (114)

Model TSS

400 SERIES

(PNEUMATIC)

STANDARD CON-

UNIT

SIZE

4 43 250 35 250 30 43 55 250 250
5 68 350 50 350 48 65 88 350 350
6 75 490 60 550 53 75 97 435 530

8 145 960 115 1000 105 145 190 840 1000
10 235 1545 185 1600 165 235 305 1355 1600
12 340 2250 285 2300 240 340 440 1975 2300
14 475 3100 390 3100 335 475 615 2750 3100
16 625 4100 520 4100 440 625 805 3595 4100
19 1180 6500 1025 6500 845 1180 1510 6375 6500
22 1730 8000 1450 8000 1260 1730 2200 8000 8000

Notes:

1. Minimum and maximum airow limits are dependent on the specic DDC controller supplied. Contact the control vendor to obtain the
minimum and maximum differential pressure limits (inches w.g.) of the transducer utilized with the DDC controller.

2. Maximum CFM is limited to value shown in General Selection Data.

3. FlowStar™ differential pressure tubing connections: High side indicated by red tubing; Low side indicated by black tubing.

4. Electric heat will not operate below 0.03” w.g. differential pressure

JOHNSON CONTROLS

TROLLER

MIN. MAX. MIN. MAX.

7000 SERIES

ANALOG

ELECTRONIC

DDC CONSIGNMENT CONTROLS

(See Notes Below)

MIN. MAX.

Min. transducer differential

pressure (in. w.g.)

0.015 0.03 0.05 1.0 ≥1.5

Max. transducer differential

pressure (in. w.g.)

15

FlowStar Calibration Chart

(For dead-end differential pressure transducers)



Model TSL

NOTE: Maximum and minimum CFM limits
are dependent on the type of controls that are
utilized. Refer to the table below for specic
values. When DDC controls are furnished by
others, the CFM limits are dependent on the
specic control vendor that is employed. After
obtaining the differential pressure range from
the vendor, the maximum and minimum CFM
limits can be obtained from the chart to the left
(many controllers are capable of controlling
minimum setpoint down to 0.015”w.g.)

400 SERIES

(PNEUMATIC)

STANDARD

UNIT
SIZE

10 235 1545 170 1600 170 235 305 1370 1600
12 340 2250 240 2300 240 340 435 1955 2300
14 495 3100 350 3100 350 495 640 2855 3100
16 660 4100 465 4100 465 660 850 3800 4100

Notes:

1. Minimum and maximum airow limits are dependent on the specic DDC controller supplied. Contact the control vendor to obtain the
minimum and maximum differential pressure limits (inches w.g.) of the transducer utilized with the DDC controller.

2. Maximum CFM is limited to value shown in General Selection Data.

3. FlowStar™ differential pressure tubing connections: High side indicated by red tubing; Low side indicated by black tubing.

4. Electric heat will not operate below 0.03” w.g. differential pressure

CONTROLLER

MIN. MAX. MIN. MAX.

7000 SERIES

ANALOG

ELECTRONIC

DDC CONSIGNMENT CONTROLS

(See Notes Below)

MIN. MAX.

Min. transducer differential

pressure (in. w.g.)

0.015 0.03 0.05 1.0 ≥1.5

Max. transducer differential

pressure (in. w.g.)

Form 130.13-NOM1 (114) Supersedes:130.13-NOM1 (808)