Field Assembled
ELECTRONIC
AIR CLEANER
AIR BOSS Model 60 Series
without
Integral Washing System
• INSTALLATION
• OPERATION
• SERVICE
For Model Numbers
60- ___-01
Electrostatic Precipitators for
Commercial & Industrial
Applications
101 McNeill Road • Sanford, NC 27330
(919) 775-2201 • Fax: (919) 774-8771 • (800) 884-0002
MANUAL Form No. 61-0147B • Sept 01
SECTION I DESIGN
To maintain the selected cleaning efficiency, it is
important to assure that the total air volume (capacity in
CFM) is uniformly distributed across the entire face area
of the unit. However, since most air ducts are designed
to handle air velocities greater than the rated velocity of
the air cleaner, it is necessary to properly transition any
attached ducting. If possible, a contraction ratio of 1 in 3
(approximately 20°) should be maintained. If space
prohibits, turning vanes, air baffles or other means may
be utilized. Ducting – where attached to the sheet metal
panels – should be gasketed, caulked or otherwise
made water and airtight.
FOR THE SYSTEM DESIGN ENGINEER
1. General Description
Model 60 equipment consists of factory-assembled
components to be “built-up” in the field into a completed
unit. Depending on the system requirements, the
installation may consist of a single unit or a multi-section
unit. A multi-section unit is simply two or more single
units placed side-by-side.
The factory-assembled components are designed to be
mounted on a field prepared pad in the form of a drain
basin, typically constructed of poured concrete.
When there is a danger of rain, snow or debris being
drawn into the system with outside air, the make-up air
intake should be protected with rain louvers, hooding
and hardware cloth to prevent the rain, snow or debris
from entering the electronic air cleaner.
The standard major components supplied with each unit
for installation are as follows:
A. Framework – Support members, complete with
sheet metal panels on the top and sides, to receive
and locate the ionizing-collecting cells.
Contaminants to be collected – such as oils in vaporous
state – must be condensed into particulate form prior to
entering the ionizing-collecting cells in order to maintain
the anticipated efficiency. Gases, vapors or any non-
particulate cannot be precipitated and will therefore
pass through the air cleaner. Any condensing that takes
place downstream from the air cleaner defeats the
purpose. By the same token, heavy concentrations of
water vapor, or other matter that becomes highly
conductive when condensed, must be prevented from
entering and/or condensing in the collecting elements to
prevent electrical arc over and shorting.
B. Ionizing-Collecting Cells – The elements used to
remove and collect the contaminants from the air
stream.
C. Control/Power Supply Box(s) – Located in the
control enclosure and converts 115VAC to the high
voltage DC required to energize the ionizing-
collecting cells.
The programmable logic controller (PLC) electrically
sequences the washing operation. The Pulse Width
Modulated (PWM) power supplies, providing the
necessary high voltage for the air cleaner and the
controls initiating and sequencing the wash cycle
are furnished in a NEMA 12 enclosure designed for
remote mounting. The distance between the
controller and unit must be determined as the
interconnecting high voltage leads are furnished to
the specified length. Consult factory for distances
greater than 50 ft. Cables are not to be spliced at
any point along their length. In addition, the
enclosure is a central junction for the primary wiring.
SAFETY NOTE:
Factory designed access to all electrically charged
high voltage components contain electrical
interlocks for the safety of operating personnel. Any
additional access that may be provided in the
system, where there is access to high voltage, must
be equipped with such interlocks. Interlocks are
readily available from the factory.
A foundation and drain basin design must be provided
to carry off the wash water used to clean the ionizing-
collecting cells. It is suggested that a new concrete
basin be poured prior to the scheduled shipment of the
hardware. Refer to Figure 3, Recommended Foundation
and Drain Basin Layout Drawing.
D. Accessories – Electrical interlocks, lights and
switches for safety and monitoring.
Serious consideration should be given to any deviation
from the suggested design, which would result in
improper drainage, leakage, air bypass and mounting.
Note: Trion Tridex Detergent is specially formulated
for use with Trion electronic air cleaners. Use of
other cleaners and detergents, not specifically
approved by Trion, will cause possible failures in
the unit and will void any and all warranties on our
equipment.
In addition to the governing plumbing codes, the
following points should be considered in the
construction of the basin.
A.) Drain lines must be of adequate size to carry off the
required amount of detergent/wash water used.
Refer to the piping schematic drawing, Figure 4.
B.) Drain lines must be suitably trapped and vented to
prevent line gases from entering the air handling
system.
2. System Design and Floor Layout
The arrangement of the supplied components and the
general layout of the system will vary according to
application, adjoining equipment and available space.
However, there are several basic factors pertaining to
all installations that must be considered:
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C.) The basin floor should be properly pitched and
finished to prevent puddling.
(A) Framework
D.) The cross members containing the anchoring studs
to receive the air cleaner base frame must be even
and level to provide a proper foundation for the
metal framework base.
(B) Ionizing-Collecting Cells
(C) Controller with Power Supplies
(D) Accessories
Where the installation site is not suitable for a poured
concrete basin, rust resistant metal pans may be used.
The metal should withstand the weight of service
personnel in addition to the weight of the unit.
For the protection of the components, it is
recommended that those materials not immediately
needed for installation be stored in the container in
which they are received in a safe, dry and clean
location. This is particularly true with the ionizing-
collecting cells, which may be damaged when not
properly handled.
Each installation varies according to needs, but
normally the controller is located near the air cleaner.
Ideal mounting height is at eye level for ease in reading
the instrumentation and to facilitate service.
For ease in maintenance and component removal,
adequate space, 39” Minimum Required, must be
provided in front of all access doors, motors, pump and
accessory equipment.
2. Assemble Framework
The base frame, two sides and top are match marked
on the air entering side of the air cleaner at the factory
prior to shipment. See Figure 5.
3. Outdoor Installations
Requirements for outdoor protection vary in accordance
to climate and equipment component arrangement for
the particular job. The best approach, for equipment
protection, is the construction of a heated shed or
building over the installation. As an alternative, the
installing contractor should treat the equipment as
required to meet the specific needs.
(A) Position the base frame on the drain basin. Make
sure it is located with the marking “BOTTOM
FRONT” on the air entering side. The anchoring
studs in the drain basin should be located on the
inside of the frame channels and the entire frame
should be level. Shim as necessary.
(B) Secure the base as illustrated. It is important that
the studs do not protrude above the base frame
channel. Cut top of studs, if necessary. Each anchor
should be treated to prevent rust.
(C) Attach the side and top panels, match marking
where the pieces join on the air entering side; A to
A, B to B, etc. The required fasteners are packaged
and marked for the framework.
Controller/PWM Power Supplies
As the controller/power supplies are designed for
remote mounting, they can be, in many cases, located
indoors and still be reasonably close to the main
cabinet. If located outdoors with the cabinet, it must be
weather protected.
(D) After the outside frame structure is complete,
position and secure the intermediate cell supports.
The side to receive the air bypass strips marked
“FRONT” should be positioned toward the air
entering side.
Contact the local Trion Sales Office or the factory if
questions arise, or any additional information is
required.
SECTION II INSTALLATION
3. Attach Adjoining Ductwork
FOR THE INSTALLING CONTRACTOR
Depending on the application, the installation plan may
or may not call for adjoining ductwork on the air entering
and/or air leaving sides of the cabinet.
1. Unpack and Inspect
At the time the unit is received, all shipping containers
and their contents should be examined for damage. Any
damage occurring in shipment must be immediately
reported to the carrier, an inspection report completed
and a claim filed at the receiving point.
When adjoining ducting is to be installed, attach to the
flanges on the air entering and air leaving sides of the
unit. Maintain structural squareness during attachment.
The seam should be made air and watertight by
caulking or gasketing.
The seam between the concrete drain basin and the
metal work must be caulked or grouted to form a good
watertight seal.
The number of shipping containers included in the
shipment is dependent upon the unit size and type.
When packaging the material for shipment,
consideration is given to grouping the components into
the installation categories in which they will be used.
The packing list included with shipment identifies the
various items to a specific box number. In general, the
grouping is as follows:
When a blower is installed downstream from the Trion
cabinet, the ducting between the cabinet and the blower
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will be under negative pressure and should be made air
tight to prevent infiltration of contaminated air.
The high voltage wiring consists of interconnecting
the ionizing-collecting cells into banks with bus
bars, then wiring each bank of interconnected cells
to its corresponding power supply with the high
voltage cable.
After the ductwork has been installed, clear remaining
material or debris from inside ducts and bottom of
cabinet.
NOTE: IT IS IMPORTANT TO WIRE EACH BANK
OF CELLS TO ITS CORRESPONDING POWER
SUPPLY AS EACH POWER SUPPLY IS
MARKED WITH A SPECIFIC OPERATING
RANGE AND SIZED FOR A GIVEN BANK OF
CELLS.
4. Install Ionizing-Collecting Cells
Before placing the ionizing-collecting cells into the
framework, the electrical cell-to-bus connectors must be
inserted through the holes located in the flanges of the
end plates and secured into place. There are two
connectors per cell, one short collector standoff and a
long ionizer standoff. Connect the bus bars and cell
wiring as shown on Figure 6, 6A, 6B and Figure 7.
Refer to Figure 6A or 6B, and select the
appropriate unit model. Interconnect the cells with
the bus bars as shown. When fully connected, the
cells will be grouped into banks as indicated by the
letters “A” and “B”.
Next, wire the interconnected cell banks to their
corresponding power supplies with the high
voltage cable provided. Depending on the size of
the unit, there may be from 3 to 14 PWM Power
Supplies.
NOTE: Follow the directional arrows located on the
cell end plates. The side of each cell containing the
spiked ionizer blades must be located on the air
entering side of the cabinet.
5. Install Air By-Pass Baffles
The air baffles provided are to be secured to the air
entering side of the unit to block off the air gap between
the frame and the top and the sides of each cell. They
are secured into place with the screws provided. The
vertical baffles for the cell ends are all rubber backed.
The horizontal baffles across the top of each cell are
plain. There are different sizes of each. Refer to Figure
8 and 8A for the arrangement.
NOTE: Each high voltage cable should be run
in a separate conduit and must not be spliced
at any point between the power supply and the
cell termination.
Use the blue cable for the ionizer and the black
cable for the collector plates. At the cell
termination, the outer jacket of insulation should
carefully be stripped back from the inner layer of
insulation a distance of four (4) inches to prevent
tracking.
6. Connect Drain
Connect a drain line to the pipe coupling in the cabinet
drain basin in accordance with the governing plumbing
codes. The drain line must be sealed with a trap or
other means to prevent air by pass. If a trap is used, it
should hold sufficient water column to overcome the
system air pressure and to assure that loss of liquid
from evaporation between cleaning periods will not
break the seal. The drain line should not be smaller than
the drainpipe coupling, or it will otherwise restrict the
flow of water.
Normally the high voltage cable entrance should
be made from the top of the ductwork. If the
installation demands entrance from some other
point, the conduit should be sealed where it
terminated at the duct to prevent moisture from
entering the conduit during the washing operation.
At the power pack termination, be sure the blue
ionizer cable is connected to the terminal marked
IONIZER and the black collector cable is
connected to the terminal marked COLLECTOR.
7. Mount Controller
The Controller should be mounted at eye level and
located as close to the air cleaner as practical. It must
be mounted indoors out of the weather unless supplied
with a weatherproof cabinet. Allow sufficient space in
front of the access door(s) for service. Refer to
appropriate Control/Remote PWM Box Outline Drawing
for mounting hole layout and dimensions.
B. Primary Wiring
(1.) Duct Door Electrical Interlocks
(Two are furnished as standard) - Outside each
duct access door.
(2.) Duct Door Electrical Interlock and Pilot
Lights
(Two are furnished as standard) – Outside each
duct access door and adjacent to the electrical
interlocks.
8. Complete Wiring
A. High Voltage Wiring
WARNING:
(3.) Duct Lights
EXERCISE ALL THE NORMAL PRECAUTIONS
WHEN WORKING WITH HIGH VOLTAGE AND
COMPLY WITH NEC AND ALL APPROPRIATE
LOCAL CODES.
(Two are furnished as standard) – On air entering
side and on air leaving side of air cleaner on the
inside of the ductwork.
(4.) Disconnect Switch and Pilot Lights
(Four are furnished as standard) – Two on Inside,
Two on Outside of each access door at most
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convenient location near the door. Those located
inside are wired in series with the electrical
interlocks and used as a safety measure to control
the primary power to the high voltage power
supplies from inside the duct. Those located outside
control the duct lights.
that each alternate plate is charged while the
intermediate plates are electrically grounded.
Periodically, depending on the type and concentration of
contamination in the air, the contaminate is washed
from the plates by manually cleaning the cells while in
place or removing them from the unit and then cleaning.
Two major functional components comprise the air
cleaner:
Grounding
An earth ground must be provided to the Model
60 cabinet and control. All ground connections
must be in contact with bare metal and securely
affixed. Ground conductor size and connection
means will be in accordance with all applicable
electrical code standards.
(1) Ionizing-collecting cells to ionize and collect
airborne particulate matter.
(2) Power supply(s) to supply high voltage direct
current to the ionizing-collecting cells.
Normally, systems are designed for collection
efficiencies in the range of 90 percent or more.
9. Check Out for System Start-up
When the installation has been completed, assure that
the equipment is ready for start-up by checking the
following:
Collecting
a
contaminant at these efficiencies,
especially when there are high concentrations can result
in large accumulations in a relatively short period.
Therefore, maintenance must encompass two areas;
the operation of the equipment for efficient collection
and the systematic removal of the collected
contaminant.
A. Ensure all construction debris is removed from the
ionizing-collecting cells, drain basin and ductwork.
B. The drain line from the Trion drain basin is clear and
completely connected to its point of termination.
C. Supply line power is available and electrical wiring
is completed to the following components:
2. General Description
The ionizing-collecting cells (contaminant collecting
elements) are housed in the cabinet on unistrut frames.
They can be removed from the unit as required, from
the backside (downstream airflow side). When installing
cells into the cabinet, observe the directional arrows on
the cell end plates. The side of the cell containing the
spiked ionizer blades always must be located on the air
entering side.
1. Controller
2. Electrical Interlocks
3. Ionizing-Collecting Cells
4. The System Fan
5. Duct Lights, Indicating Lights and Switches
The Power Supply(s) convert the 115 volt, 60HZ, single
phase AC supply to the high voltage DC needed to
power the ionizing-collecting cells. Potential of 13 KVDC
are required for the ionizer sections and 6.5 KVDC for
the collector sections of the cells.
SECTION III OPERATION & SERVICE
WARNING
RISK OF ELECTRIC SHOCK
These servicing instructions are for use by qualified
personnel only. To reduce the risk of electric shock,
do not perform any servicing other than that
contained in the operating instructions unless you
are qualified to do so.
3. Initial Start-up
A. Inspect the inside of the adjoining ductwork and
Trion cabinet to be sure it is clean and free of any
debris or construction materials. Especially note the
opening in the drain basin for any restrictions. The
ducting, where secured to the cabinet collars,
should be sealed water tight either with gasketing or
caulking.
FOR THE MAINTENANCE ENGINEER
1. Introduction and Principle of Operation
The Trion electronic air cleaner is technically known
as an electrostatic precipitator. In this type of
equipment, all airborne particles, even of microscopic
size, are electrically charged (positively) as they pass
through a high voltage ionizer. These charged particles
are then attracted and adhere to a series of parallel
collecting plates, which form the negative elements of
an electrostatic field.
B. Inspect the ionizing-collecting cells to see that all of
the ionizing blades or wires are intact, that no large
pieces of foreign material are lodged between the
plates, and that the cells are properly installed in the
cabinet with the spiked ionizing blades or wires
located on the air entering side.
The ionizer consists of charged stainless steel spiked
blades spaced between grounded electrodes. The
collecting section consists of parallel plates arranged so
C. Check the high voltage leads to see that they are
connected to the proper terminal both at the
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ionizing-collecting cells and inside the controller.
Refer to Figure 14A.
The Air Boss controller (Optional) contains a digital
LED display for kilovolt and milliampere readings.
The milliammeter should be observed on a routine
basis to be sure that it is reading within the
prescribed operating range as marked on the data
plate. For those units containing a voltmeter, the
collector voltage should be between 6 and 7 KV,
and the ionizer between 12.5 and 13.5 KV.
D. Be sure that the drain lines from the Trion cabinet
drain basin are completely connected and properly
terminated. A trap or seal of some type should be
incorporated in the line to prevent air bypass.
E. Be sure that electrical power is available, that the
wiring is completed, and that the system blower is
ready to energize.
The ATS controller and remote PWM box both have
LED indicating lights to show power to the PWM
power supplies. Flickering or failed LED’s indicate
electrical arcing and/or power failure.
F. Be sure that all access door interlocks are closed.
G. Close the system electrical supply switches, making
power available to the Trion controller and the
system fan.
5. Periodic Maintenance
A. Controller -
Every 12 Months
The inside of the controller cabinet should be
examined for accumulated dirt and dust. If required,
the components should be cleaned using a good
brand of electrical contact cleaner. All terminal
connections should be checked for securement and
tightened or reworked as required.
H. Turn the controller selector switch to the “ON”
position. The blower should run (if installed) and the
power supply(s) should be energized. Electrical
arcing within the ionizing-collecting cells may occur.
It is a normal occurrence caused by accumulation of
dusts from construction or other sources in the
cell(s) and should subside quickly. If the arcing is
continuous and does not subside, recheck the
routing of the high voltage leads between the power
supply(s) and the cell(s). Refer to the field-wiring
diagram. The ionizer lead must be connected to the
ionizer and the collector lead to the collector.
B. Ionizing-Collecting Cell –
Every 6 to 12 Months
Remove and inspect the ionizing-collecting cells for
excessive dirt accumulations. Manually clean as
required in a soak tank, commercial car wash, or
with a pressure hose or pressure cleaner using a
low-pressure setting. At this time, particular care
should be taken in cleaning each of the insulators.
4. Routine Maintenance
A. Washing Frequency
The frequency that the collected dirt is to be washed
from the unit depends upon the type and amount of
dirt in the air to be cleaned. Dirt, which is greasy in
nature, tends to harden after collection and should
be washed away often. Likewise, units operating
under extremely heavy dirt loads should be washed
more often as a large build-up of collected material
will have a tendency to “blow-off” if permitted to
remain on the collecting elements for long periods
of time. In that the type and amount of dirt varies
geographically (and from one location to another in
any given area) it is recommended to start operation
with a washing frequency of at least once a month.
This schedule may then be altered as needed after
visual examinations of the collected material
contained on the ionizing-collecting cells.
WARNING:
DO NOT USE HIGH PRESSURE STEAM CLEANING
EQUIPMENT TO CLEAN CELLS. THE EXCESSIVE
HEAT AND PRESSURE WILL CAUSE THE PLATES
TO WARP AND IN TURN POSSIBLY CAUSE
EXCESSIVE ARCING.
C. Filter Devices –
Every 4 to 6 Months
Hoods, impingers, metal mesh filters, ducts and
other appurtenances shall be cleaned to bare metal
at frequent intervals prior to surfaces becoming
heavily contaminated with grease, oil or other
contaminate. It may be advantageous to clean
readily removable items, such as impingers, metal
mesh filters or other permanent filter devices in a
soak tank, with a pressure hose or pressure cleaner
low setting. After cleaning to bare metal,
components shall not be coated with powder or
other substance.
B. Detergent
Effective washing is dependent upon detergent. The
detergent, as supplied by Trion, Inc., is formulated
specifically for electronic air cleaners. If substitutes
are used, they must be approved by Trion, so as to
not void the warranty. They should be safe for use
in ventilation systems and non-caustic, as 95% of
the ionizing-collecting cells are constructed of
aluminum, special high voltage insulation and
gasket seals.
When a cleaning service is used, a certificate
showing dates of inspection and/or cleaning shall be
maintained on the premises.
WARNING
Flammable solvents or other flammable
cleaning aids shall not be used.
C. Electrical Operation
7
At the start of the cleaning process, electrical
switches that could be accidentally activated shall
be locked out. Components of the fire suppression
system (if installed) shall not be rendered
inoperable during the cleaning process.
The most common outage is a short in the
secondary circuit and is best located through the
process of elimination. Symptoms are a flickering
indicating light accompanied by an arcing noise in
the ionizing-collecting cell(s) or an indicating light
that is not glowing.
Care should be taken not to apply cleaning
chemicals on any fusible links or other detection
devices of the automatic extinguishing system.
A flickering light with an arcing noise is an indication
of a high resistance short circuit and a light that is
not glowing is an indication of a dead short. (A light
that is not glowing can also be an indication of an
open circuit in the primary circuit. Refer to the
paragraph on open circuits.) The short may be in
the power supply, the high voltage cables or the
ionizing-collecting cell(s). To isolate the short to any
one of these three components, proceed as follows:
6. Troubleshooting
WARNING:
EXERCISE THE USUAL PRECAUTIONS WHEN WORKING
WITH HIGH VOLTAGE. THE MAXIMUM OPERATING
OUTPUT FROM THE POWER SUPPLY IS 15,000 VDC AND
5.5 MA. to 11.0 MA. WHEN IN PARALLEL.
WARNING
IF SAFETY SWITCHES ARE CLOSED AND CIRCUIT IS
ENERGIZED, DO NOT TOUCH HIGH VOLTAGE. WHEN
THE CIRCUIT IS DE-ENERGIZED, ALWAYS BLEED OFF
REMAINING STATIC CHARGE WITH AN INSULATED
HANDLED SCREW DRIVER BY SHORTING to GROUND
THE POINTS OF HIGH VOLTAGE DC POTENTIAL.
When safety interlock switches are closed, do not
come in contact with high voltage components. The
operating output from the high voltage power
supply(s) is 12,600 VDC and 6 MA. to 11.0 MA.
When the power supply(s) is de-energized there Is a
20 second delay for the voltage to decay. Always
short from ground to a point of high voltage with a
well Insulated jumper wire or an insulated handled
screwdriver to bleed-off any remaining residual
charge.
WARNING
Risk of Electrical Shock
The servicing Instructions are for use by qualified
personnel only. To reduce the risk of electric shock,
do not perform any servicing other than that
contained in the service instructions unless you are
qualified to do so.
1. Disconnect both high voltage leads from their
respective terminals in the power supply and
support them away from any point of contact.
A. Introduction
This section on troubleshooting provides
a
2. Energize the power supply:
description of potential malfunctions, their cause,
location and correction. A Trouble Reference Chart
listing the most probable causes and corrections
follows the general text.
a. If the light still flickers or does not glow, the
trouble is indicated to be in the power supply. First,
check the inline fuse mounted on the circuit board
and replace if it is blown. Second, replace the power
supply in its entirety.
The electronic air cleaner is the unit within the
system that has the highest efficiency collection
rating and is also the one with the highest potential
for malfunction. When a malfunction does occur, the
outage is usually found in the electrical secondary
circuit in the ionizing-collecting cell(s).
b. If the light glows steady with the leads
disconnected the power supply is indicated to be
normal.
Indicating lights are installed in the face panel of the
control to monitor the electrical operation of each
power supply and the ionizing-collecting cell(s) they
energize. The quantity of power supplies per unit is
dependent upon unit size with one or two power
supplies for each ionizing-collecting cell tier in
height. Other than the basic hand tools, it is
advantageous to have a volt/ohm/milliammeter with
a 20 KVDC high voltage probe. These instruments
NOTE: It will be necessary to close the access door
electrical interlock switch operated by the access
door, to complete the primary circuit to the power
supply.
3.Next reconnect both high voltage leads to their
respective terminals inside the power supply and
disconnect them at the ionizing-collecting cell(s).
Support them away from any point of contact and
energize the power supply.
are
standard
catalog
items
by
several
manufactures.
B. Secondary Short Circuit
a. If either high voltage lead is defective the light will
indicate the trouble. Each lead may then be checked
8
separately by disconnecting them, one at a time, from
their respective terminals at the power supply. When
a lead is found to be defective, replace it in its
entirety. Do not repair or splice.
Although open circuits can occur in the secondary they
usually take place in the primary. If the unit contains
only one power supply and the indicating light does not
glow the outage is probably one of the following.
(1) Supply line power to the control disconnected.
Reconnect.
(2) Open access door interlock in control of electronic
air cleaner. Be sure all access doors are properly closed
and secured.
b. If the light glows steady with the leads disconnected
at the ionizing-collecting cell(s) the trouble is then
indicated to be in the ionizing-collecting cell(s).
The trouble can then be isolated to a single cell, or the
ionizing or collector section of a given cell as follows:
(3) Blown in-line fuse- Replace Power Supply.
(4) Outage in the power supply. Look for charred or
burned components or a loose wiring connection.
Replace power supply or reconnect wiring.
(5) Defective indicating light. Replace light.
(1) First determine if the short is in the ionizing
section or the collecting section by connecting
each high voltage lead to its respective section,
one at a time, and energizing the power pack.
(The lead not connected must be supported
away from any point of contact.) The short
symptoms will still exist for the section in which
the short is located. If the trouble causing the
short is bridging both sections, then the short will
be indicated in both sections when they are
individually connected.
d. Malfunctions other than short or open circuits. Refer
to troubleshooting reference chart in this section.
7. Spare Parts
Recommended spare part quantities are usually based
on the unit size and the amount of units per installation.
For specific recommendations, consult the Trion factory
or nearest Sales Office. Consideration, however, should
be given to stocking the following components;
(2) When the short is isolated to a cell tier, remove
all the cells within the tier and visually check the
sections indicated to contain the short.
(a). If the short is in the ionizer section, look for a
broken or defective insulator.
(b). If the short is in the collector section, look for
a large piece of foreign material bridging the
collector plates or a defective insulator.
DESCRIPTION
PWM Power Supply
Cell Insulators
LED
QTY.
2
6
2
(c). If the short is indicated to be in both sections,
it will probably be a foreign object bridging the air
gap between the ionizer and the collector.
Part Numbers are not listed as they are subject to
change. Always state Unit Model and Serial Numbers
when ordering parts.
c. Open Circuits
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Troubleshooting Reference Chart
PROBLEM/
SYMPTOM
PROBABLE
CAUSE
LOCATION
REASON - CORRECTION
Ionizing Section of Cell
Collecting Section of Cell
High Voltage Leads
Power Supply
1. Dirty insulator(s) – Clean
2. Defective insulator(s) – Replace
3. Foreign Object Between Ionizing Bar and Ground
electrode - Remove
1. Dirty insulator(s) - Clean
2. Defective insulator(s) – Replace
3. Foreign Material Bridging Plates - Remove
4. Bent Plates – Straighten or Replace
1. Disconnected High Voltage Lead Contacting Ground
- Reconnect
Short Circuit
Indicating Light
Not Glowing
2. Defective Lead/Insulation Breakdown – Replace
Entire Lead
Charred/Over Heated Components – Replace
Power Supply
Control
1. Disconnected Supply Line Power – Reconnect
2. Faulty indicting Light - Replace
1. Blown Fuse – Replace Power Supply
2. Disconnected Wire – Replace
3. Charred/Over Heated Components – Replace
Power Supply
Power Supply
Indicating Light Open Circuit
Not Glowing
Electronic Air Cleaner
Housing
1. Electrical Interlock Switch Not Closed – Close
Access Door
2. Faulty Electrical Interlock Switch - Replace
1. Ionizer High Voltage Lead Connected to Plate
Section and Plate Lead to Ionizer – Reconnect
Leads
2. Loose or Disconnected High Voltage Lead-Tighten
or Reconnect
Indicating Light High Resistance
High Voltage Circuit
Flickering
Short
3. Loose or Defective Intercell Connection (on Multicell
Units) – Tighten or Replace
4. Foreign Object Adrift in Ionizer or Plate Section of
Cell - Remove
10
Model 60 Control Schematic
THIS PAGE INTENTIONALLY LEFT BLANK
DETAILED SCHEMATIC DRAWINGS WILL BE PROVIDED
BASED ON THE SIZE AND CONFIGURATION
OF YOUR UNIT ORDERED.
FIGURE 11
Model 60 Field Wiring
THIS PAGE INTENTIONALLY LEFT BLANK
DETAILED FIELD WIRING DRAWINGS WILL BE PROVIDED
BASED ON THE SIZE AND CONFIGURATION
OF YOUR UNIT ORDERED.
FIGURE 12
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