Hi-Velocity RPM-E Series User manual
www.hi-velocity.com
© 1995-2009 Energy Saving Products Ltd.
*IMPORTANT: The freeze control serves the
purpose of preventing severe icing of the coil in the
event of an undercharge or low load on the coil. This
piece of equipment must be used at all times. Lack
of use of the freeze-stat will result in RPM-E related
warranty issues being voided.
A
A1
B
B1
COIL
Module RPM
Refrigerant Module Installation (RPM-E) (1/5)
Rough Opening Sizes A or B A1 or B1
RPM-E 50 113/4”L X 131/4”H
(298mm X 337mm)
113/4”L X 9”W
(298mm X 229mm)
RPM-E-70 163/4”L X 131/4”H
(425mm X 337mm)
163/4”L X 9”W
(425mm X 229mm)
RPM-E-100 223/4”L X 131/4”H
(578mm X 337mm)
223/4”L X 9”W
(578mm X 229mm)
Module RPM Refrigerant Module Installation (RPM-E) (1/5)
Refrigerant Modules (RPM-E)
The RPM-E series cooling module can be used with the Hi-
Velocity Fancoil, installed in many different positions. It is pre-
piped with an adjustable, heat pump ready, thermal expansion
valve and comes with a bleed port, sight glass, suction and liquid
line access ports, freeze-stat, and two L brackets for mounting.
The RPM-E comes as a complete module and must be installed
in the vertical position on the return air side of the fancoil; the
unit cannot be turned on its side and is a draw through unit
only. The module offers multi-position airow congurations
for horizontal, highboy, or counter-ow congurations. (Fig.
RPM-01)
The TXV (Thermal Expansion Valve), sight glass, access
ports, and freeze-stat* are already installed and are accessible
through an easy to remove access hatch. The liquid and suction
lines have male solder connections at a standard width making
connections to the condenser lines quick and easy.
Fig. RPM-01 - RPM-E Cooling Module Congurations
When installing, follow the recommendations shown in
Table 01, demonstrated in Fig. 01. For example, a horizontal
application could use A to B while highboy applications could
use A to B1. Do not use a combination of A to A1 or B to B1,
as this would bypass the cooling coil completely. A1 is not
to be used for outlet airow. The knock-outs can be removed
with a screw driver and hammer. Use caution when opening
the knock-outs, ensuring you do not damage the coil surface.
Congurations
*B to A and B1 to A congurations are not recommended,
due to a higher chance of carry-over issues.
Important: If side A1 is going to be used in your selected
conguration, the extended drain pan must be removed.
RPM-E Drain Pan Extension
The RPM-E Drain Pan Extension (DPE) is to be removed for
up ow (vertical) return air applications (avoid installing the
RPM-E in counter ow applications).
The lower knockout can now be removed, using a screwdriver
and hammer (Fig-RPM-03). Use caution when removing
knockouts ensuring you do not damage the coil inside the
module.
To remove the pre-installed DPE, rst remove left side access
panel of the RPM-E Module. Remove the 3 - ¼ ” screws
that hold the DPE in place, remove the DPE and replace ¼”
screws into the coil support (Fig. RPM-02). Replace the left
side access panel.
Right Wrong
A to B B1 to A1
A to B1 B to A1
A1 to B A to A1
A1 to B1 B to B1
B to A*
B1 to A*
Table RPM-01 - RPM-E Cooling Module Congurations
Fig-RPM-02 - Remove DPE
Fig-RPM-03 - Remove Knockout
© 1995-2013 Energy Saving Products Ltd.
www.hi-velocity.com
© 1995-2009 Energy Saving Products Ltd.
Two L mounting brackets are shipped loose for attaching the
RPM-E to the fancoil, along with two sided foam tape for an
air seal between the units. When mounting the cooling coil to
the fancoil (Fig. RPM-04), ensure that no screws puncture the
drain pan or coil. It is advised that no screws be placed within
3 inches (76mm) from the bottom of the coil. This will prevent
the drain pan from being accidentally pierced. It is also advised
that care be taken when placing screws in the top left side of
the cooling coil (when looking at the access hatch), as this is
where the top most extent of the cooling coil is located. See
Specication Pages for the dimensions of the fan coil units and
cooling modules.
Mounting the RPM-E
Fig. RPM-04 - Mounting Brackets
(76mm)
(76mm)
(76mm)
(76mm)
P-Trap
Secondary drain pan
Some building codes call for the use of a secondary drain pan
underneath the entire unit (Fig. RPM-05). Any installation that
has the potential of property damage due to condensate must
have a secondary drain pan installed. If the unit is installed in a
high heat and/or high humidity location, extra insulation around
the unit casing may be required. This will prevent excessive
condensate from forming on the outer surface of the casing.
Secondary Drain Pan
Fig. RPM-05 - Secondary drain pan
Drain Connections
All RPM-E modules come with a ¾” (19mm) primary and
secondary outlet. The condensate drain must have a vented p-trap
installed (Fig. RPM-05), and run at a slope of ¼” (6.7mm) per
foot in the direction of the drain. When installing the P-trap, one
must be installed on both the primary and secondary outlets. The
P-traps must have a minimum depth of two inches (51mm). Due
to the high negative pressure of the blower system, the RPM-E
will hold some amount of water during operation. Once this level
has been achieved, condensate will ow from the coil regularly.
When the unit shuts down, or lowers speed, the force is released,
allowing the held condensate to empty from the drain pan.
During this time, condensate may ow from both the primary
AND secondary drains.
Locate the outdoor unit in a suitable location, as close as
possible to the fan coil. Maintain the clearances recommended by
the manufacturers of the outdoor unit, to ensure proper airow.
The outdoor unit must be installed level, in a properly supported
location. A liquid line lter/drier is recommended to be installed.
Outdoor Unit Installation
Make all connections to the outdoor unit with rain tight conduit
and ttings. Most building codes require a rain tight disconnect
switch at the outdoor unit as well (always check local codes).
Run the proper size copper wires to the unit, and connect as per
the manufacturer’s recommendations.
Ensure that the outdoor unit is setup for a TX system. If not, a
hard start kit may be required.
Wiring - Outdoor Unit
Module RPM
Refrigerant Module Installation (RPM-E) (2/5)
Module RPM Refrigerant Module Installation (RPM-E) (2/5)
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© 1995-2009 Energy Saving Products Ltd.
Module RPM
Refrigerant Module Installation (RPM-E) (3/5)
Module RPM Refrigerant Module Installation (RPM-E) (3/5)
Pipe Sizing
When sizing refrigerant piping, follow
the outdoor unit manufacturer’s
recommendations.
Run the pipes in the most direct route possible, taking into
account structural integrity and building details. If the evaporator
is located above the condenser, slope any horizontal runs toward
the condenser. If the condenser is located above the evaporator,
a P-trap must be installed at the bottom of the vertical riser. For
long vertical risers, additional P-traps must be installed for every
twenty feet (6m). For lines running over 50’ (15m), a suction line
accumulator must be installed. Lines running over 100’ (30m) are
not recommended. All lines should be piped so as not to restrict
access to the front panels, lter section, or electrical enclosure.
Piping the RPM-E
Only refrigerant grade pipe and ttings are to be used with
Hi-Velocity Systems. Plumbing ttings may contain wax or other
contaminants which are detrimental to the proper operation of
the system. Insulate the suction line with 3/8” (9.53mm) insulation
such as Armaex. In high heat areas, 1/2” (12.7mm) insulation
may be needed. If the lines are run in an area where temperatures
could exceed 120°F (49°C) or runs longer than 50’ (15.24m), then
the liquid line may need to be insulated as well. Support the pipe
every 5 feet (1.52m), or whatever local code states.
Brazing & Pressure Testing
The RPM-E comes pre-piped with the coil assembly. With the
RPM-E, the Liquid and Suction lines are the only brazing that
need to be done at the fan coil. For charging and brazing, remove
the front access panel of the RPM-E (Fig. RPM-06). With the
access panel removed, the coil assembly will be accessible. Wet
rag the liquid and suction line (or use a heat dissipating paste)
to ensure no overheating occurs to the pre-piped coil assembly.
Excess heat may damage the RPM-E components.
Fig. RPM-06 - Remove Front Access Panel
Once the system has been brazed it must be pressure tested.
Pressure testing must be done with nitrogen and not refrigerant.
Typically, pressures are tested to the maximum operating pressure
that the system will see. Allow the system to hold the nitrogen
charge for at least 15 minutes to ensure there are no leaks. Check
with local codes for proper testing procedures.
After the piping is installed and all components have been
brazed together, a vacuum pump must be used to evacuate the
system from both the low and high side to 1500 microns (200
pa). Add pressure to the system to bring the pressure above zero
psig. After allowing the refrigerant to absorb moisture, repeat the
above procedure. Evacuate the system to 500 microns (67 pa) on
the second evacuation, and ensure that the system holds at the
vacuum pressure. If not, check for leaks and evacuate again. At
this point open service valves on pre-charged condensing units,
and add refrigerant to the system if necessary.
Evacuating
The use of an electronic leak detector is recommended, as it is
more sensitive to small leaks under the low pressures.
Once the system has been determined clean and ready for
charging, refrigerant can be added. The access ports on the
condenser must be open at this point. Never leave the system
unattended when charging. With the system running, slowly
add refrigerant. The typical operating point of an RPM-E coil
is that of a saturated suction temperature of 38-40°F (3-4°C)
and a suction line temperature of 42-44°F (6-7°C). In order to
prevent overcharging during this stage, refrigerant should be
added in steps. This will allow time for the system to settle and
prevent ‘overshooting’ the ideal charge. Condenser pressures and
temperatures remain similar to those in a conventional forced air
system. It is recommended that the coil be charged on a high load
day at the compressor’s highest speed.
Charging
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© 1995-2009 Energy Saving Products Ltd.
Most system start ups require only an adjustment to the
refrigerant level of the system. Should further renement be
required, the TXV may be adjusted. A clockwise turn of the
superheat valve (the direction in which the cap is screwed on)
will result in a closing of the valve while a counterclockwise
turn (the direction in which the cap was unscrewed) will result
in opening of the valve. Always note system conditions before
adjusting the valve and allow 5 minutes for the system to settle
before making any further adjustments. Never adjust the TXV
more than one quarter turn at a time.
Module RPM
Refrigerant Module Installation (RPM-E) (4/5)
Module RPM Refrigerant Module Installation (RPM-E) (4/5)
Freeze Stat
The RPM-E series cooling coil comes equipped with an
anti-freeze control mounted on the suction line. This freeze
control serves the purpose of preventing severe icing of the coil
in the event of an undercharge or low load on the coil. This
piece of equipment must be used at all times. Lack of use
of the freeze-stat will result in RPM-E related warranty
issues being voided. During start-up, it is acceptable to
jumper across the Freeze-Stat. This will prevent the freeze-
stat from shutting the system off while charging a new system
that may be low on refrigerant. Once charged and running,
this jumper must be removed and the Freeze-Stat connected to
the X1 and X2 terminals on the Printed Circuit Board. Should
wiring needs arise in which the outdoor unit is controlled
through another means of wiring, the Freeze-Stat should be
connected in series on the supply side of the control wiring.
Heat Pumps
Traditionally, SDHV systems have been charged to special
guidelines when used in conjunction with heat pumps. This
charging procedure involved charging the units to normal
cooling capacities and reviewing the operation in heating mode.
If head pressures were found to be impinging on the high head
pressure limits, a small amount of refrigerant was removed to
prevent the unit from shutting down. The cause of high head
pressures in heating mode is due to the disparity in sizes of the
indoor and outdoor coils, along with the lower airow rates of
SDHV systems.
The RPM-E coil can operate at a level that is different from
most other conventional system coils. Typically, superheat level
are low, two to four degrees of superheat. Adjustment of the valve
also differs somewhat. Rather than having a large effect on the
range of superheat, adjustment of the valve has a larger effect
on the system pressures; superheat maintaining a fairly constant
point. Opening the valve will increase suction pressures and
decrease liquid pressures, while closing the valve will decrease
suction pressures and raise liquid pressures.
Bi-Flow Receiver
The Bi-Flow Receiver is designed for use with heat pump
systems, up to 5 tons, and with any typical refrigerants. The
receiver allows refrigerant a location to migrate to during the
heating cycle, minimizing head pressures. During cooling mode,
the receiver is empty, allowing the full refrigerant charge to be
utilized for cooling.
The receiver is a horizontal tank with a pair of dip tubes
extending to the bottom of the tank. These two tubes allow for
liquid refrigerant to be drawn from the tank regardless of the
direction of ow. For this reason, the receiver must be mounted
so that the inlet/outlets of the tank come out of the top of the unit.
Mounting brackets are located at the base of the unit for secure
mounting. The receiver is to be located on the liquid line of the
system, anywhere between the indoor and outdoor coils. As the
unit is of a bi-ow design, it does not matter which end faces
towards the indoor coil.
The inlet/outlet ports are constructed of steel and require the
use of a 35-45% Silver Solder and Flux for brazing. The use of
standard copper to copper solders may result in difculty brazing
and the potential for a failure at the weld. Ensure that the tank is
protected from overheating while brazing and that any remaining
ux is cleaned from the unit. If installing outdoors, ensure that
the receiver is insulated and protected from the elements.
With the introduction of newer, larger heat pumps, this issue
is more likely to be experienced. While some heat pump units
may still be charged in the traditional method, the amount of
refrigerant that is required to be removed for heating mode may
leave the system drastically undercharged for cooling mode. For
this reason it is highly recommended that a Bi-Flow Receiver be
used with heat pump applications.
Charging Cont’d
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© 1995-2013 Energy Saving Products Ltd.
Troubleshooting the TXV
When issues arise that bring the function of the TXV into
question, factors must be looked into before replacement. Inspect
the TXV for signs of damage. This may be from a pinched
equalizer line to a burnt valve. These issues will have an adverse
affect on the operation of the valve. Should the equalizer line be
pinched, the valve will no longer be able to supply the proper
amount of refrigerant to the coil. A burnt valve may have an
effect on the refrigerant charge of the TXV bulb or the seal of the
valve. This may again cause an improper amount of refrigerant
to be metered by the valve or cause the valve head to become
seized.
The TXV bulb location and mounting should also be inspected.
The bulb should be securely mounted on the top half of the
suction line. If the bulb is loose or on the lower half of the line,
the bulb will not properly sense the refrigerant temperature and
will not meter the proper amount of refrigerant. Ensure that the
bulb is also properly insulated, as a lack of insulation will expose
the bulb to conditions well outside those of the coil. This will
cause an overfeed of refrigerant to the system.
Should the installation of the valve be proper, and no damage
is evident, inspect the operation of the valve. If the TXV bulb
is removed and held in ones hand, the valve should react
accordingly. This sudden increase in heat will open the valve.
This will cause a rise in suction pressure and a drop in liquid
pressure. Should nothing happen, the valve is likely seized and
will need to be replaced.
Specications RPM-E-50 RPM-E-70 RPM-E-100
Matching Fan Coil HE-Z/HE/HV - 50 / 51 / 52
LV-5 0
HE-Z/HE/HV - 70 / 71
LV-7 0
HE-Z/HE/HV - 100 / 101
LV-120/140
Part Number 20090200050 20090200070 20090200100
Refrigerant Type R-410A R-410A R-410A
TX Cooling MBH1 18-24 (5.3-7.0 kW) 30-36 (8.8-10.6 kW) 42-60 (12.3-17.6 kW)
Latent Cooling MBH 6.8-8.9 (2.0-2.6 kW) 11.7-13.7 (3.4-4.0 kW) 16.0-22.2 (4.7-6.5 kW)
Fin Material Aluminum Aluminum Aluminum
Tubing Material Copper Copper Copper
Type of Fins .006 Al .006 Al .006 Al
Connection Sizes
Liquid Line (Lq) 3/8” (9.5mm) 3/8” (9.5mm) 3/8” (9.5mm)
Suction Line (S) 7/8” (22.3mm) 7/8” (22.3mm) 7/8” (22.3mm)
Drain Connection 3/4” (19mm) 3/4” (19mm) 3/4” (19mm)
TXV with Built in Check Valve & Bypass Yes Yes Ye s
Site Glass Yes Yes Ye s
Access Ports Yes Yes Ye s
Freeze Stat Yes Yes Ye s
Shipping Weight (lbs) 48 (22kg) 59 (27kg) 74 (34kg)
Module Size (L x W x H) 191⁄4” x 145⁄8” x 181⁄2”
(489mm x 371mm x 470mm)
241⁄4” x 145⁄8” x 181⁄2”
(616mm x 371mm x 470mm)
32” x 145⁄8” x 181⁄2”
(813mm x 371mm x 470mm)
Tons21.5 - 2.0 (5.3 - 7.0 Kw) 2.5 - 3.0 (8.8 - 10.6 Kw) 3.5 - 5.0 (12.3 - 17.6 Kw)
1) Smaller condensers may be matched to the fan coil when needed (match TXV to condenser size)
MBH = Thousand British Thermal Units per Hour TX = Thermal Expansion TXV = Thermal Expansion Valve
2) Minimum of 8 full 2” (51mm) outlets per ton of cooling needed (4 outlets for HE)
and outdoor unit, on and off. This often takes the form of very
short and frequent on cycles. There are many factors that may
contribute to short cycling of the refrigerant system. These issues
can generally be broken down between airow related issues,
refrigerant issues, and installation issues.
Low airow rates are one of the most common causes of short
cycling. As the airow rate is lowered across the cooling coil,
the coil pressure drops along with it. This lowers the temperature
of the coil and may cause the freeze-stat to trip. As the system
settles, the freeze-stat closes and the cycle begins again, as the
unit does not run long enough for the space to become adequately
conditioned. Ensure that the proper amount of airow is provided
to the coil. Check for proper air ows and return air practices.
Improperly charged systems run the risk of short cycling as
well. An undercharged system will react much the same as a
system with low airow. If the charge is low enough, it may trip
out on low pressure. If a system is overcharged, it may trip out on
high head pressure. Ensure that the system charge is within the
bounds described in section “Piping the RPM-E”.
System set-up and installation should be checked as well.
Piping practices should be within the bounds described in section
“Piping the RPM-E” and within the realms of the outdoor unit
manufacturer. Extreme and often unnecessary adjustment of the
TXV can create conditions similar to an undercharged coil. A
poorly placed T-stat, such as underneath a vent, can cause short
cycling. This happens due to the T-stat being satised very
shortly after the unit has begun to operate.
Module RPM
Refrigerant Module Installation (RPM-E) (5/5)
Short Cycling
Short cycling is the unnecessary running of the indoor
Module RPM Refrigerant Module Installation (RPM-E) (5/5)
This manual suits for next models
6
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