INS7162 Rev-
TM
INSTALLATION INSTRUCTIONS
ADDITIONAL FUNCTIONS INCLUDE:
• Installer and Advanced Access Levels
• Primary Pump Output
INTRODUCTION
The MP2is capable of controlling the supply water tempera-
ture for up to nine ON / OFF stages based on outdoor tem-
perature, control for the Domestic Hot Water (DHW) gener-
ation, a set point requirement or optionally an external input
signal (0 - 10 V (dc)). A large easy to read display provides
current system temperatures and operating status (FIG. 1).
The control has outputs for a primary pump and a combus-
tion air damper or alarm. Based on the mode of operation
selected, the control can operate different combinations of
boiler stages and boiler pumps.
• Individual Boiler Pump Outputs (in applicable
modes)
• Pump Exercising
• Pump Purging (primary and boiler)
• Boiler Demand for Space Heating Loads
• DHW Demand for DHW Loads
• Set Point Demand for Set Point Loads
• Test Sequence to Ensure Proper Component
Operation
• Setback Input for Energy Savings
• 0 - 10 V (dc) Input Signal
Modes
1
2
3
4
5
6
7
8
Up to 9 On/Off Boilers
Up to 4 On/Off Boilers & 4 Pumps
Up to 4 Lo/Hi Boilers
Up to 3 Lo/Hi Boilers & 3 Pumps
Up to 3 Three Stage Boilers
Up to 2 Three Stage Boilers & 2 Pumps
Up to 2 Four Stage Boilers
1 Four Stage Boiler & 1 Pump
FIG. 1
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DISPLAY
Boiler Demand
DHW / Setpoint Demand
WWSD
External Input Signal
Offset
FIG. 2
SYMBOL DESCRIPTION
FIG. 3
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Set Point
DEFINITIONS
When a set point demand signal from a set point system is
present, the control operates the boiler(s) to maintain the
supply water temperature at least as hot as the SETP set-
ting. Refer to section F.
The following defined terms and symbols are used through-
out this manual to bring attention to the presence of hazards
of various risk levels, or to bring attention to important infor-
mation concerning the life of the product, see Figure 4
below.
External Input 0 - 10 V (dc) or 2 - 10 V (dc)
When an external input signal is present, the control con-
verts the signal to a target supply temperature. The control
operates the boiler(s) to maintain the required supply water
temperature.
FIG. 4
SEQUENCE OF OPERATION
SECTION A: GENERAL OPERATION
POWERING UP THE CONTROL
When the control is powered up, all segments in the LCD
are turned on for two seconds. The control displays the
control type number in the LCD for two seconds. Next, the
software version is displayed for two seconds. Finally, the
control enters the normal operating mode.
FIG. 5
SETBACK (UNOCCUPIED)
To provide greater energy savings, the control has a set-
back feature (FIG. 6). With setback, the supply water tem-
perature in the system is reduced when the building is unoc-
cupied. By reducing the supply water temperature, the air
temperature in the space may be reduced even when ther-
mostat(s) are not turned down. Any time the UnO Sw (5)
and the Com - (1) are connected, the control operates in the
UnOccupied mode. When in the UnOccupied mode, the
UNOCC segment is displayed in the LCD. The control
adjusts the supply water temperature based on the UNOCC
settings made in the control. This feature has no effect when
the control is used in the External Input mode.
OPERATION
The control operates up to nine on / off heat sources to con-
trol the supply water temperature to a hydronic system. The
supply water temperature is based on either the current out-
door temperature, an external 0 - 10 V (dc) or 2 - 10 V (dc)
signal, or a fixed set point.
Boiler Reset (Stand Alone)
When a boiler demand signal from the heating system is
present, the control operates the boiler(s) to maintain a sup-
ply temperature based on the outdoor air temperature and
Characterized Heating Curve settings, see Figure 5.
Domestic Hot Water
When a DHW demand signal from a DHW aquastat is pres-
ent, the control operates the boiler(s) to maintain the supply
water temperature at least as hot as the DHW XCHG set-
ting. Refer to section E.
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ROTATION
The control's Equal Run Time Rotation function is fixed at
48 hours. The firing order of the boilers change whenever
one boiler accumulates 48 hours more running time than
any other boiler. After each rotation, the boiler with the least
running hours is the first to fire and the boiler with the most
running hours is the last to fire. This function ensures that all
the boilers being rotated receive equal amounts of use.
When the Rotate / Off DIP switch is set to the Off position,
the firing sequence always begins with the lowest boiler to
the highest boiler, see Figure 7 below.
FIG. 6
COMBUSTION AIR OR ALARM CONTACT
The control has an isolated contact that can be used as
either a combustion air damper contact or an alarm contact.
This selection is made using the C. A. / Alarm DIP switch.
Combustion Air (C. A.)
When the DIP switch is set to C. A., terminals 12 and 13 can
be used as a switch to operate a combustion air damper.
This contact closes prior to the first stage operating on the
control. The amount of time that the contact closes prior to
the first stage operating is set using the combustion delay
FIG. 7
setting. The combustion air contact remains closed for a Fixed Lead Rotation
minimum of 15 seconds after the last stage is turned off.
In some applications, it may be desirable to have the first
Alarm
boiler fire first at all times while the firing sequence of the
remaining boilers is changed using Equal Run Time
When the DIP switch is set to Alarm, terminals 12 and 13 Rotation. This rotation option is selected by setting the
can be used as a switch to operate an alarm circuit. This Fixed Lead / Off DIP switch to the Fixed Lead position.
contact closes whenever an error message is present on
the control. When the alarm contact is activated, refer to the First On / Last Off or First On / First Off
Error Messages section of this manual to determine the
cause of the alarm. Once the fault has been fixed, the alarm When using the Fixed Lead rotation option, a selection must
can be cleared by pressing either the Menu, Item, up arrow be made between First On / Last Off and First On / First Off
or down arrow button.
using the DIP switch. When First On / Last Off is selected,
the lead boiler is always staged on first and staged off last.
When First On / First Off is selected, the lead boiler is
always staged on first and staged off first. This DIP switch is
Boiler Alarm
The control can monitor the boiler supply temperature and only read by the control when the Fixed Lead / Off DIP
provide an alarm if the temperature does not increase with- switch is set to Fixed Lead.
in a certain amount of time. The amount of time can be set
using the Boiler Alarm setting. This alarm can be used to Fixed Last
determine if the boilers have failed to fire. To reset the
In some applications, it may be desirable to have the last
alarm, press and hold the up and down arrow buttons for 5
boiler fire last at all times while the firing sequence of the
seconds while in the VIEW menu.
remaining boilers is changed using Equal Run Time
Rotation. This rotation option is selected by setting the
Fixed Last / Off DIP switch to Fixed Last. With a fixed last
rotation, the last boiler is the last to stage on and the first to
stage off.
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Resetting the Rotation Sequence
BOILER MAXIMUM
To reset the rotation sequence, set the Rotate / Off DIP
switch to the Off setting for 5 seconds and then return the
DIP switch to the Rotate setting.
The boiler maximum is the highest temperature that the
control is allowed to use as a boiler target temperature. If
the control does target the BOIL MAX setting, and the boil-
er temperature is near the boiler maximum temperature, the
maximum segment will be displayed in the LCD while either
the boiler target temperature or the boiler supply tempera-
ture is being viewed. At no time does the control operate
the boiler(s) above 248°F (120°C).
RUNNING TIMES
The control displays the accumulated running time of each
boiler in the VIEW menu. When using a multi-stage boiler,
the running time that is displayed is the total number of run-
ning hours of the Lo stage of the boiler.
SECTION B: STAGING OPERATION
SECTION B1: STAGING
Mode
Resetting the Running Times
To reset the running time for each boiler, select the appro-
priate running time in the VIEW menu. Next, press the up
and down arrow buttons simultaneously until CLR is dis-
played.
The control is capable of staging single stage, two stage,
three stage or four stage on / off heat sources. In certain
modes of operation the control is capable of controlling the
individual boiler pumps. The control has 8 modes of opera-
EXERCISING
The control has a built-in exercising feature that is selected tion based on the type of staging and pump operation that
through the Exercise / Off DIP switch. To enable the exer- is desired. The following describes the modes of operation:
cising feature set the Exercise / Off DIP switch to Exercise.
If exercising is enabled, the control ensures that each pump Mode 1: 9 Single Stage Boilers and a primary pump.
is operated at least once every 3 days. If a pump has not
Mode 2: 4 Single Stage Boilers with individual boiler pumps
been operated at least once every 3 days, the control turns
and a primary pump.
on the output for 10 seconds. This minimizes the possibility
of the pump seizing during a long period of inactivity. While
the control is exercising, the Test LED flashes quickly.
Mode 3: 4 Lo/Hi boilers and a primary pump.
Mode 4: 3 Lo/Hi boilers with individual boiler pumps and a
primary pump.
Note: The exercising function does not work if power to the
control or pumps is disconnected.
Mode 5: 3 Three Stage Boilers and a primary pump.
Mode 6: 2 Three Stage Boilers with individual boiler pumps
and a primary pump.
RELOADING FACTORY DEFAULTS
To reload the factory defaults, power down the control for 10 Mode 7: 2 Four Stage Boilers and a primary pump.
seconds. Power up the control while simultaneously hold-
Mode 8: 1 Four Stage Boiler with a boiler pump and a pri-
ing the Menu and down arrow buttons. The control will now
mary pump.
display the E01 error message. To clear this error message,
follow the procedure in the Error Messages section of this
manual.
BOILER MINIMUM
The boiler minimum is the lowest temperature that the con-
trol is allowed to use as a boiler target temperature. During
mild conditions, if the control calculates a boiler target tem-
perature that is below the BOIL MIN setting, the boiler tar-
get temperature is adjusted to at least the BOIL MIN setting.
During this condition, if the boiler(s) is operating, the mini-
mum segment is turned on in the display when viewing
either the boiler supply temperature or the boiler target tem-
perature. Set the BOIL MIN setting to the boiler manufac-
turer's recommended temperature.
FIG. 8
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FIG. 9
FIRE DELAY
LO / HI OR LO / LO
The Fire Delay is the time delay that occurs between the
time that the control closes a stage contact to fire a stage
and the burner fires for that stage. The fire delays for the
first and third stages in a boiler are adjustable using the
F DLY 1 and F DLY 2 settings. The fire delay for the sec-
ond and the fourth stages is fixed at 10 seconds, see Figure
10 below.
When using multi-stage boilers, a selection must be made
regarding the staging order of the boiler(s). This adjustment
is made in the ADJUST menu of the control.
Lo / Hi
If the Lo/Hi staging option is selected the control stages in
sequence all of the stages in a single boiler. Once all of the
stages are turned on, the control then stages in sequence
all of the stages in the next boiler in the rotation sequence.
Fire Delay 1
Fire Delay 1 is available in all modes of operation. Fire
Delay 1 is the fire delay of the first stage of the boiler.
Lo / Lo
Fire Delay 2
If the Lo/Lo staging option is selected, the control stages all
of the Lo stage outputs in all of the boilers first. Once all of
the boilers are operating on their Lo stages, the control then
operates the second stage in each boiler in the same order.
Fire Delay 2 is only available in the modes of operation for
Three and Four Stage Boilers. Fire Delay 2 is the fire delay
of the third stage of the boiler.
STAGING
The control operates up to nine stages to supply the
required temperature. After a stage is turned on in the firing
sequence, the control waits for the minimum time delay.
After the minimum time delay between stages has expired,
the control examines the control error to determine when
the next stage is to fire. The control error is determined
using Proportional, Integral and Derivative (PID) logic.
Proportional compares the actual supply temperature to
the boiler target temperature. The colder the supply water
temperature, the sooner the next stage is turned on.
Integral compares the actual supply temperature to the
boiler target temperature over a period of time.
Derivative compares how fast or slow the supply water
temperature is changing. If the supply temperature is
increasing slowly, the next stage is turned on sooner. If the
supply temperature is increasing quickly, the next stage is
turned on later, if at all.
FIG. 10
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Fixed Differential
STAGE DELAY
If the user desires to have a fixed differential, this is set
using the BOIL DIFF setting in the ADJUST menu (FIG. 11).
The stage delay is the minimum time delay between the fir-
ing of stages. After this delay has expired the control can
fire the next stage if it is required. This setting can be adjust-
ed manually or set to an automatic setting. When the auto-
matic setting is used, the control determines the best stage
delay based on the operation of the system.
Auto Differential
If the Auto Differential is selected, the control automatically
determines the best differential as the load changes. This
reduces potential short cycling during light load conditions
(FIG. 11).
BOILER MASS
The BOIL MASS setting allows the installer to adjust the
control to the thermal mass of the type of heat sources used
in the application. The BOIL MASS setting also adjusts the
minimum inter-stage delay time when operating with an
automatic differential.
Lo (1)
The Lo setting is selected if the boiler(s) that is used has a
low thermal mass. This means that the boiler(s) has a very
small water content and has very little metal in the heat
exchanger. A boiler that has a low thermal mass comes up
to temperature quite rapidly when fired. This is typical of
many copper fin-tube boilers. The Lo MASS setting pro-
vides the quickest staging on of boilers.
Med (2)
The Med setting is selected if the boiler(s) that is used has
a medium thermal mass. This means that the boiler(s) either
has a large water content and a low metal content or a low
water content and a high metal content. This is typical of
many modern residential cast iron boilers or steel tube boil-
ers. The Med MASS setting stages on additional boilers at
a slower rate than the Lo MASS setting.
FIG. 11
SECTION C: PUMP OPERATION
Hi (3)
SECTION C1: PUMP OPERATION
The Hi setting is selected if the boiler(s) that is used has a
high thermal mass. This means that the boiler(s) has both
a large water content and a large metal content. A boiler that
has a high thermal mass is relatively slow in coming up to
temperature. This is typical of many commercial cast iron
and steel tube boilers. The HI MASS setting stages on
additional boilers at the slowest rate.
PRIMARY PUMP OPERATION
The primary pump operates under the following conditions:
• The control receives a boiler demand and is not in warm
weather shut down (WWSD).
• The control receives a DHW demand when DHW MODE
is set to 3 or 4.
• The control receives a set point demand and set point
MODE is set to 3.
DIFFERENTIAL
An on / off heat source must be operated with a differential
to prevent short cycling. With the control, either a fixed or
an auto differential may be selected. The boiler differential
is divided around the boiler target temperature. The first
stage contact closes when the supply water temperature is
½ of the differential setting below the boiler target tempera-
ture. Additional stages operate if the first stage is unable to
bring the supply water temperature up to the boiler target
temperature at a reasonable rate. As the supply tempera-
ture reaches ½ of the differential above the boiler target
temperature, stages are staged off.
Primary Pump Purge
After a demand is removed, the control continues to operate
the primary pump for a period of time. The maximum length
of time that the primary pump continues to run is adjustable
using the Purge setting. The primary pump continues to run
until either the purging time has elapsed or the boiler supply
temperature drops more than a differential below the boiler
minimum setting, see Figure 12.
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FIG. 12
FIG. 13
BOILER PUMP OPERATION
In certain modes of operation, the control can operate the
individual boiler pumps on each boiler in addition to the pri-
mary pump. The boiler pump turns on prior to the boiler fir-
ing and continues to run after the boiler is turned off. The
amount of time that the boiler pump turns on prior to the
boiler firing is determined by the BOIL MASS setting. If a
BOIL MASS of Lo is selected, the boiler pump turns on 15
seconds prior to the boiler. If a BOIL MASS of Medium is
selected, the boiler pump turns on 22 seconds prior to the
boiler. If a BOIL MASS of Hi is selected, the boiler pump
turns on 30 seconds prior to the boiler. However, if the con-
trol is operating based on a set point demand, the boiler
pump turns on 5 seconds prior to the boiler, see Figure 13.
Boiler Pump Purge
FIG. 14
The amount of time that the boiler pump continues to run
after the boiler turns off is adjustable using the boiler pump
purge setting (PURG Boil Pmp).
BOILER TARGET TEMPERATURE
The boiler target temperature is determined from the char-
acterized heating curve settings and the outdoor air tem-
perature. The control displays the temperature that it is cur-
rently trying to maintain as the boiler supply temperature. If
the control does not presently have a requirement for heat,
it does not show a boiler target temperature. Instead, "- - -"
is displayed in the LCD.
SECTION D: BOILER RESET OPERATION
SECTION D1: BOILER RESET (STAND ALONE)
BOILER DEMAND
When operating in the stand-alone mode, a boiler demand
is required in order for the control to provide heat to the
heating system. A boiler demand is generated by applying
a voltage between 24 and 230 V (ac) across the Boiler
Demand and Common Demand terminals (6 and 7)
(FIG. 14). Once voltage is applied, the Boiler Demand
pointer is displayed in the LCD. If the control is not in
WWSD, the control closes the primary pump contact. The
control calculates a boiler target supply temperature based
on the outdoor air temperature and the characterized heat-
ing curve settings.
CHARACTERIZED HEATING CURVE
The control varies the supply water temperature based on
the outdoor air temperature. The control takes into account
the type of terminal unit that the system is using. Since dif-
ferent types of terminal units transfer heat to a space using
different proportions of radiation, natural convection and
forced convection, the supply water temperature must be
controlled differently. Once a terminal unit is selected, the
control varies the supply water temperature according to the
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type of terminal unit. This improves the control of the air
temperature in the building.
ROOM
The room is the desired room temperature for the building
and provides a parallel shift of the heating curve. The room
temperature desired by the occupants is often different from
BOILER INDOOR DESIGN TEMPERATURE
The indoor design temperature is the room temperature that the design indoor temperature. If the room temperature is
was used in the original heat loss calculations for the build- not correct, adjusting the ROOM setting increases or
ing. This setting establishes the beginning of the character- decreases the amount of heat available to the building. A
ized heating curve, see Figure 15 below.
ROOM setting is available for both the occupied (day) and
unoccupied (night) periods.
TERMINAL UNITS
BOIL DSGN
The control provides for a selection between six different
terminal unit types: two types of radiant floor heat, fancoil,
fin-tube convector, radiator and baseboard. When a termi-
nal unit is selected, the control automatically loads the
design supply temperature, maximum supply temperature,
and minimum supply temperature (FIG. 16). The factory
defaults are listed in Figure 16. These factory defaults can
be changed to better match the installed system. If a facto-
ry default has been changed, refer to section A to reload the
factory defaults.
BOIL IND
FIG. 15
OUTDOOR DESIGN TEMPERATURE
The outdoor design temperature is the outdoor air tempera-
ture that is the typical coldest temperature of the year where
the building is located. This temperature is used when doing
the heat loss calculations for the building. If a cold outdoor
design temperature is selected, the boiler supply tempera-
ture rises gradually as the outdoor temperature drops. If a
warm outdoor design temperature is selected, the boiler
supply temperature rises rapidly as the outdoor temperature
drops.
BOILER DESIGN TEMPERATURE
The design supply temperature is the supply water temper-
ature required to heat the building when the outdoor air tem-
perature is as cold as the outdoor design temperature.
WARM WEATHER SHUTDOWN
When the outdoor air temperature rises above the WWSD
setting, the control turns on the WWSD pointer in the dis-
play. When the control is in Warm Weather Shut Down, the
boiler demand pointer is displayed if there is a boiler
demand. However, the control does not operate the
heating system to satisfy this demand. The control does
respond to a DHW or set point demand and operates as
described in sections E & F.
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FIG. 16
HIGH MASS RADIANT (1)
This type of a hydronic radiant floor is embedded in either a
thick concrete or gypsumpour. This heating system has a
large thermal mass and is slow acting (FIG. 17).
LOW MASS RADIANT (2)
This type of radiant heating system is either attached to the
bottom of a wood sub-floor, suspended in the joist space, or
sandwiched between the sub-floor and the surface. This
type of radiant system has a relatively low thermal mass
and responds faster than a high mass system (FIG. 17).
FANCOIL (3)
A fancoil terminal unit or air handling unit (AHU) consists of
a hydronic heating coil and either a fan or blower. Air is
forced across the coil at a constant velocity by the fan or
blower, and is then delivered into the building space
(FIG. 17).
FIG. 17
BOOST
When the control changes from the UnOccupied mode to
the Occupied mode, it enters into a boosting mode. In this
mode, the supply water temperature to the system is raised
above its normal values for a period of time to provide a
faster recovery from the setback temperature of the build-
ing. The maximum length of the boost is selected using the
BST setting.
FIN-TUBE CONVECTOR (4)
A convector terminal unit is made up of a heating element
with fins on it. This type of terminal unit relies on the natu-
ral convection of air across the heating element to deliver
heated air into the space. The amount of natural convection
to the space is dependant on the supply water temperature
to the heating element and the room air temperature
(FIG. 17).
Typical settings for the boost function vary between 30 min-
utes and two hours for buildings that have a fast responding
heating system. For buildings that have a slow responding
heating system, a setting between four hours and eight
hours is typical. After a boost time is selected, the setback
timer must be adjusted to come out of setback some time in
advance of the desired occupied time. This time in advance
is normally the same as the BST setting.
RADIATOR (5)
A radiator terminal unit has a large heated surface that is
exposed to the room. A radiator provides heat to the room
through radiant heat transfer and natural convection
(FIG. 17).
If the building is not up to temperature at the correct time,
the BST setting should be lengthened and the setback timer
should be adjusted accordingly. If the building is up to tem-
perature before the required time, the BST setting should be
shortened and the setback timer should be adjusted accord-
ingly. If the system is operating near its design conditions
or if the supply water temperature is being limited by set-
tings made in the control, the time required to bring the
building up to temperature may be longer than expected.
BASEBOARD (6)
A baseboard terminal unit is similar to a radiator, but has a
low profile and is installed at the base of the wall. The pro-
portion of heat transferred by radiation from a baseboard is
greater than that from a fin-tube convector (FIG. 17).
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SECTION E: DOMESTIC HOT WATER OPERA-
TION
SECTION E1: DOMESTIC HOT WATER (DHW)
DHW DEMAND
A DHW Demand is required for the control to provide heat
to the DHW system. A DHW aquastat or set point control is
used as a switch in the DHW demand circuit. Once the con-
trol detects a DHW demand, the DHW Demand pointer
turns on in the LCD and the control operates the boiler to
provide a sufficient boiler supply water temperature to the
DHW tank. The control operates the pumps as described
below.
The control registers a DHW Demand when a voltage
between 24 and 230 V (ac) is applied across the Setp /
DHW and Com Dem terminals (8 and 7).
BOILER TARGET DURING DHW GENERATION
The boiler target temperature is at least as hot as the DHW
exchange setting (DHW XCHG). The DHW demand over-
rides the boiler reset target temperature, except when the
boiler reset target is higher than that of the DHW exchange
setting.
DHW MODE & PRIORITY OPERATION
The control has five different settings available for DHW
MODE. The required DHW MODE setting will depend on
the piping arrangement of the DHW tank.
It is often desirable to have a priority for the DHW allowing
for quick recovery of the DHW tank temperature. This is
achieved by limiting or even stopping the flow of heat to the
heating system when the DHW tank calls for heat see
Figure 18.
FIG. 18
DHW MODE 2 - DHW IN PARALLEL NO PRIORITY
When a DHW Demand is present, the Relay 9 / DHW con-
tact (terminals 30 and 31) closes with the DHW demand.
The primary pump does not turn on, but may operate based
on a Boiler Demand or External Input Signal. Refer to sec-
tions E and G. It is assumed that the DHW pump will pro-
vide adequate flow through the heat exchanger and the
boiler.
DHW MODE OFF - NO DHW
The DHW feature is not selected. This allows for Set Point
operation as described in section F.
DHW MODE 1 - DHW IN PARALLEL NO PRIORITY
When a DHW Demand is present, the Relay 9 / DHW con-
tact (terminals 30 and 31) closes and the primary pump con-
tact is opened. It is assumed that the DHW pump will
provide adequate flow through the heat exchanger and
the boiler.
DHW MODE 3 - DHW IN PRIMARY / SECONDARY NO
PRIORITY
When a DHW Demand is present, the Relay 9 / DHW con-
tact (terminals 30 and 31) is closed and the primary pump
contact is closed. This mode can be used if a DHW tank
is piped in direct return and a DHW valve is installed.
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DHW MODE 4 - DHW IN PRIMARY / SECONDARY WITH CONDITIONAL DHW PRIORITY
PRIORITY
The Conditional DHW Priority Override applies to DHW
MODE 2 and 4. If the boiler supply temperature is main-
tained at or above the required temperature during DHW
generation, this indicates that the boiler(s) has enough
capacity for DHW and possibly heating as well. As long as
the boiler supply temperature is maintained near its target
and the heating and DHW targets are similar, DHW and
heating occurs simultaneously.
When a DHW Demand is present, the Relay 9 / DHW con-
tact (terminals 30 and 31) is closed and the primary pump
contact is closed. Priority can only be obtained using exter-
nal wiring. During a priority override, the Relay 9 / DHW
contact is opened until the heating system has recovered
before returning to DHW operation, see Figure 19. This
mode can be used if a DHW tank is piped in direct
return and a DHW valve is installed.
DHW POST PURGE
After the DHW Demand is removed, the control performs a
purge on the boiler(s). The control shuts off the boiler(s)
and continues to operate either the DHW pump or the DHW
valve and the system and boiler pump if applicable. This
purges the residual heat from the boiler(s) into the DHW
tank. The control continues this purge for a maximum of two
minutes or until the boiler supply water temperature drops
20° F (11°C) below the boiler target temperature during the
DHW operation. The control also stops the purge if the boil-
er supply temperature is close to the current boiler target
temperature.
DHW MIXING PURGE
FIG. 19
After DHW operation, the boiler(s) is extremely hot. At the
same time, the heating zones may have cooled off consid-
erably after being off for a period of time. To avoid thermal-
ly shocking the boiler(s) after DHW in parallel with priority
DHW PRIORITY OVERRIDE
The DHW Priority Override applies to DHW MODE 2 and 4. (DHW MODE 2), the control shuts off the boiler(s), but con-
To prevent the building from cooling off too much or the pos- tinues to operate the DHW while restarting the heating sys-
sibility of a potential freeze up during DHW priority, the con- tem. This allows some of the DHW return water to mix with
trol limits the amount of time for DHW priority. The length of the cool return water from the zones and temper the boiler
DHW priority time is determined using the Priority Override return water (FIG. 21).
setting. Once the a llowed t ime for priority has elapsed, the
control overrides the DHW priority and resumes space
heating.
To provide external DHW priority in DHW Mode 4, the space
heating zones must be interlocked with the Relay 9 / DHW
contact, Figure 20. During DHW demands, the Relay 9 /
DHW contact must remove any power to all space heating
zone valves or zone pumps.
FIG. 21
DHW DURING UNOCCUPIED
If the control receives a DHW Demand during an unoccu-
pied period, the control can either continue operation of the
DHW system as it would during the occupied period or the
control can ignore a DHW Demand for the duration of the
unoccupied period.
FIG. 20
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For correct operation, close attention must be paid to the
mechanical layout of the system. When the control turns off
the primary pump (Prim P1), flow to the heating system
must stop. If flow is not stopped, the temperature in the
heating system can exceed the maximum desired tempera-
ture and can result in damage to the heating system.
NUMBER OF BOILERS USED FOR DHW GENERATION
The number of boilers used for DHW generation can be
selected from one to the maximum number of boilers using
the BOIL DHW setting. This applies when only a DHW
Demand is present. If there are other demands present, the
control does not limit the number of boilers operated.
DHW MODE 4 OPERATION
SECTION E2: DHW WITH LOW TEMPERATURE BOILERS
In DHW MODE 4, the space heating zones must be pre-
vented from coming on during DHW demands using exter-
nal wiring. This can be done using an external relay to
remove power from zone pumps or zone valves while a
DHW Demand is present. During a DHW Demand, the con-
trol closes the primary pump (Prim P1) contact and the
Relay 9 / DHW contact. Once the DHW Demand is
removed, or during a DHW Priority Override, the Relay 9 /
DHW contact is opened, and the external wiring should
allow the space heating zones to operate.
If DHW is to be incorporated into a low temperature system
such as a radiant heating system, a mixing device is often
installed to isolate the high DHW supply temperature from
the lower system temperature. If a mixing device is not
installed, high temperature water could be supplied to the
low temperature system while trying to satisfy the DHW
demand. This may result in damage to the low temperature
heating system. The control is capable of providing DHW in
such a system while maximizing the chance that the tem-
perature in the heating system does not exceed its allowed
maximum setting.
There is no mixing purge available in DHW MODE 4. After
DHW priority, the boiler supply water temperature may
exceed the design water temperature of the space heating
system and can result in damage to the heating system.
To prevent high temperature water from being introduced
into the heating system, the primary pump (Prim P1) must
be turned off during a call for DHW. To do this, the control
must be set to DHW MODE 2 or DHW MODE 4 and Boil
MIN must be set to OFF, see Figure 22 below.
SECTION F: SET POINT OPERATION
SECTION F1: SET POINT
Set point operation is only available when DHW MODE is
set to OFF.
SET POINT
The control can operate to satisfy the requirements of a set
point load in addition to a space heating load. A set point
load overrides the current outdoor reset temperature and
WWSD setting in order to provide heat to the set point load.
SET POINT DEMAND
A set point demand is required for the control to provide
heat to the set point load. The control registers a set point
demand when a voltage between 24 and 230 V (ac) is
applied across the Setp / DHW and Com Dem terminals (8
and 7) (FIG. 23).
FIG. 22
DHW MODE 2 OPERATION
Once voltage is applied, the Set Point Demand pointer turns
on in the LCD. The control operates the boiler(s) to main-
tain at least the set point setting.
On a call for DHW, the control provides DHW priority by
shutting off the primary pump (Prim P1) for a period of time.
This time is based on the DHW Priority Override setting.
However, if the DHW Demand is not satisfied within the
allotted time, the boiler(s) shuts off and the heat of the
boiler is purged into the DHW tank.
Once the boiler supply temperature is sufficiently reduced,
the Relay 9 / DHW contact shuts off. The heating system is
turned on for a period of time to prevent the building from
cooling off. After a period of heating, and if the DHW
Demand is still present, the control shuts off the heating sys-
tem and provides heat to the DHW tank once again.
FIG. 23
14
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operates set point and heating simultaneously by turning on
the primary pump (Prim P1).
BOILER TARGET DURING SET POINT
The boiler target temperature during a set point demand is
increased to at least the Set Point setting. This temperature
is maintained as long as the control has a set point demand.
CONDITIONAL SET POINT PRIORITY
If the boiler(s) supply temperature is maintained at or above
the required temperature during set point generation, this
indicates that the boiler(s) has enough capacity for set point
and possibly heating as well. As long as the boiler target
temperature is maintained and the heating and set point
targets are similar, set point and heating occur at the same
time.
SET POINT MODE
SETP MODE 1 - Setpoint in Parallel
Whenever a set point demand is present, the boiler(s) is
operated to maintain the set point target. The primary pump
does not turn on, but may operate based on a Boiler
Demand or an External Input Signal, see Figure 24.
SECTION G: EXTERNAL INPUT OPERATION
SECTION G1: EXTERNAL INPUT
It is assumed that the Set Point pump will provide ade-
quate flow through the heat exchanger and the boiler.
EXTERNAL INPUT
SETP MODE 2 - Set Point in Parallel with Priority
The control can accept an external DC signal in place of the
outdoor sensor. The control converts the DC signal into the
appropriate boiler target temperature between 50°F (10°C)
and 210°F (99°C) based on the External Input Signal and
Offset settings. To use the external input signal, the
External Input / Stand Alone DIP switch must be set to
External Input.
Whenever a set point demand is present, the boiler(s) is
operated to maintain the set point target and the primary
pump (Prim P1) contact is opened.
It is assumed that the Set Point pump will provide ade-
quate flow through the heat exchanger and the boiler.
When operating in the external input mode, an external sig-
nal is required in order for the control to provide heat to the
heating system. An external signal is generated by apply-
ing a voltage between 0 V (dc) and 10 V (dc) across the Out
+ and Com - terminals (4 and 1) (FIG. 25). Once voltage is
applied, the External Input Signal pointer is displayed in the
LCD and the control closes the primary pump contact. The
control calculates a boiler target supply temperature based
on the external input signal and the settings made in the
control. The control then fires the boiler(s), if required, to
maintain the target supply temperature. If the external sig-
nal goes below the minimum voltage, the External Input
Signal pointer is turned off in the display. The boiler target
temperature is displayed as " - - - " to indicate that there is
no longer a call for heating. The primary pump and boiler
pumps operate as described in section C.
SETP MODE 3 - Primary Pump during Set Point
Whenever a set point demand is present, the primary pump
(Prim P1) is turned on and the boiler(s) is operated to main-
tain the set point target.
Apply Power
Apply Power
Do Not
Do Not
FIG. 24
SET POINT PRIORITY OVERRIDE
–
–
The set point has a Priority Override while in SETP MODE
2. In order to prevent the building from cooling off too much
or the possibility of a potential freeze up during set point pri-
ority, the control limits the amount of time for set point prior-
ity. The length of Set Point priority is determined by the
Priority Override setting. Once the allowed time for priority
has elapsed, the control overrides the set point priority and
+
FIG. 25
15
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INPUT SIGNAL
EXTERNAL INPUT SIGNAL CONVERSION TABLES
The control can accept either a 0 - 10 V (dc) signal or a 2 -
10 V (dc) signal. The External Input Signal setting must be
set to the proper setting based on the signal that is being
sent to the control.
0 - 10 V (dc) or 0 - 20 mA
When the 0 - 10 V (dc) signal is selected, an input voltage
of 1 V (dc) corresponds to a boiler target temperature of
50°F (10°C). An input voltage of 10 V (dc) corresponds to a
boiler target temperature of 210°F (99°C). As the voltage
varies between 1 V (dc) and 10 V (dc) the boiler target tem-
perature varies linearly between 50°F (10°C) and 210°F
(99°C). If a voltage below 0.5 V (dc) is received the boiler
target temperature is displayed as " - - - " indicating that
there is no longer a call for heating.
A 0 - 20 mA signal can be converted to a 0 - 10 V (dc) sig-
nal by installing a 500 ohm resistor between the Out + and
Com - terminals (4 and 1).
2 - 10 V (dc) or 4 - 20 mA
When the 2 - 10 V (dc) signal is selected, an input voltage
of 2 V (dc) corresponds to a boiler target temperature of
50°F (10°C). An input voltage of 10 V (dc) corresponds to a
boiler target temperature of 210°F (99°C). As the voltage
varies between 2 V (dc) and 10 V (dc) the boiler target tem-
perature varies linearly between 50°F (10°C) and 210°F
(99°C). If a voltage below 1.5 V (dc) is received the boiler
target temperature is displayed as " - - - " indicating that
there is no longer a call for heating.
A 4 - 20 mA signal can be converted to a 2 - 10 V (dc) sig-
nal by installing a 500 ohm resistor between the Out + and
Com - terminals (4 and 1).
OFFSET
The Offset setting allows the boiler target temperature to be
fine tuned to the external input signal. The control reads the
external input signal and converts this to a boiler target tem-
perature. The Offset setting is then added to the boiler tar-
get temperature.
16
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• All wires are to be stripped to a length of 3/8" (9 mm) to
ensure proper connection to the control.
INSTALLATION
ƽ
CAUTION
• If an Outdoor Sensor TST2311 is used, install the sensor
according to the installation instructions in the INS7141 and
run the wiring back to the control.
Improper installation and operation of this control could
result in damage to the equipment and possibly even
personal injury. It is your responsibility to ensure that this
control is safely installed according to all applicable
codes and standards. This electronic control is not
intended for uses as a primary limit control. Other con-
trols that are intended and certified as safety limits must
be placed into the control circuit. Do not open the con-
trol. Refer to qualified personnel for servicing. Opening
voids warranty and could result in damage to the equip-
ment and possibly even personal injury.
• Install the TST2311 sensor according to the installation
instructions in the Data Brochure D 070 and run the wiring
back to the control.
• If a TST2311 sensor is used, install the sensor according
to the installation instructions in the Data Brochure D 070
and run the wiring back to the control.
• Run wire from other system components (pumps, boilers,
etc.) to the control.
STEP ONE ----- GETTING READY
• Run wires from the 115 V (ac) power to the control. Use a
clean power source with a 15 A circuit to ensure proper
operation. Multi-strand 16 AWG wire is recommended for
all 115 V (ac) wiring due to its superior flexibility and ease of
installation into the terminals.
Check the contents of this package. If any of the contents
listed are missing or damaged, please contact your whole-
saler or Lochinvar sales representative for assistance.
MP2 includes: One Boiler Control MP2, One Outdoor Sensor
TST2311, Two Temperature Sensors TST2313, Instruction
Manuals INS7141 and INS7162
STEP THREE ----- ELECTRICAL CONNECTIONS TO THE
CONTROL
Note: Carefully read the details of the Sequence of
Operation to ensure that you have chosen the proper con-
trol for your application.
General
The installer should test to confirm that no voltage is pres-
ent at any of the wires. Push the control into the base and
slide it down until it snaps firmly into place.
ƽ STEP TWO ---- ROUGH-IN WIRING
All electrical wiring terminates in the control base wiring
chamber. The base has standard 7/8" (22 mm) knockouts
which accept common wiring hardware and conduit fittings.
Before removing the knockouts, check the wiring diagram
and select those sections of the chamber with common volt-
ages. Do not allow the wiring to cross between sections as
POWERED INPUT CONNECTIONS
115 V (ac) Power
Connect the 115 V (ac) power supply to the Power L and
Power N terminals (10 and 9) (FIG. 26). This connection
the wires will interfere with safety dividers which should be provides power to the microprocessor and display of the
control. As well, this connection provides power to the Prim
P1 terminal (11) from the Power L terminal (10).
installed at a later time.
Power must not be applied to any of the wires during
the rough-in wiring stage.
Boiler Demand
To generate a boiler demand, a voltage between 24 V (ac)
and 230 V (ac) must be applied across the Boil Dem and
Com Dem terminals (6 and 7) (FIG. 26).
DHW Demand
To generate a DHW Demand, a voltage between 24 V (ac)
and 230 V (ac) must be applied across the Setp / DHW and
Com Dem terminals (8 and 7) (FIG. 26). If using DHW, the
last boiler in MODE 1, 4 or 5 must be set to OFF and DHW
MODE must also be set to 1 through 4.
17
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Set Point Demand
ƽ OUTPUT CONNECTIONS
To generate a setpoint demand, a voltage between 24 V
(ac) and 230 V (ac) must be applied across the Setp / DHW
and Com Dem terminals (8 and 7) (FIG. 26). The DHW
MODE must be set to OFF.
Primary Pump Contact (Prim P1)
The Prim P1 output terminal (11) is a powered output.
When the relay in the control closes, 115 V (ac) is provided
to the Prim P1 terminal (11) from the Power L terminal (10).
To operate the primary pump, connect one side of the pri-
mary pump circuit to terminal 11 and the second side of the
pump circuit to the neutral (N) side of the 115 V (ac) power
supply, see Figure 28.
10
9
er
w
Po
11
Prim
P1
10
r
9
Po
e
w
L
7 8
Setp/
DHW
Com
Dem
FIG. 28
Combustion Air / Alarm Contact (C.A./Alarm)
The Combustion Air / Alarm Contact (C.A./Alarm) terminals
(12 and 13) (FIG. 29) are an isolated output in the control.
There is no power available on these terminals from the
control. These terminals are to be used as a switch to either
make or break power to the combustion air damper or
alarm. Since this is an isolated contact, it may switch a volt-
age between 24 V (ac) and 230 V (ac).
FIG. 26
External Input (0 - 10 V dc)
To generate an external input signal, a voltage between 0
and 10 V (dc) must be applied to the Com - and Out + ter-
minals (1 and 4) (FIG. 27).
A 0 - 20 mA signal can be converted to a 0 - 10 V (dc) sig-
nal by installing a 500 ohm resistor between the Com -
and Out + terminals (1 and 4) (FIG. 27).
.A./
C
Alarm
A 4 - 20 mA signal can be converted to a 2 - 10 V (dc) sig-
nal by installing a 500 ohm resistor between the Com -
and Out + terminals (1 and 4) (FIG. 27).
FIG. 29
Relay 1 to Relay 9
r
r
owe
Apply P
owe
Apply P
Not
Not
Do
Do
The Relay 1 to Relay 9 terminals (14 and 15 to 30 and 31)
(FIG. 30) are isolated outputs in the control. There is no
power available on these terminals from the control. These
terminals are to be used as a switch to either make or break
power to a boiler stage or a boiler pump. Since this is an
isolated contact, it may switch a voltage between 24 V (ac)
and 230 V (ac).
–
–
+
+
FIG. 27
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Boiler Return Sensor
If a boiler return sensor is used, connect the two wires from
the TST2311 sensor to the Com - and Boil Ret terminals (1
and 3) (FIG. 31). The boiler return sensor is used by the
control to measure the boiler return water temperature.
4
3
2
1
Com
–
Out
+
Boil
Ret
Boil
Sup
4
Out
+
3
Boil
Ret
2
1
Com
–
Boil
Sup
FIG. 30
4
Out
+
3
2
1
Com
–
Boil
Ret
Boil
Sup
Relay 9 / DHW
If a DHW pump or DHW valve is connected to the Relay 9 /
DHW contact (30 and 31) (FIG. 30), make sure the power to
the pump or valve circuit is off and install a jumper between
those terminals. When the DHW circuit is powered up, the
DHW pump should turn on or the DHW valve should open
completely. If the DHW pump or valve fails to operate, check
the wiring between the terminals and the pump or valve and
refer to any installation or troubleshooting information sup-
plied with these devices. If the DHW pump or valve oper-
ates correctly, disconnect the power and remove the
jumper.
FIG. 31
UnOccupied Switch
If an external timer or switch is used, connect the two wires
from the external switch to the Com - and UnO Sw terminals
(1 and 5) (FIG. 32). When these two terminals are shorted
together, the control registers an UnOccupied signal.
ƽ SENSOR AND UNPOWERED INPUT CONNECTIONS
Do not apply power to these terminals as this will dam-
age the control.
Outdoor Sensor
If an outdoor sensor is used, connect the two wires from the
Outdoor Sensor TST2311 to the Com - and Out + terminals
(1 and 4) (FIG. 31). The outdoor sensor is used by the con-
trol to measure the outdoor air temperature.
FIG. 32
STEP FOUR ----- TESTING THE WIRING
Boiler Supply Sensor
ƽ GENERAL
Connect the two wires from the TST2311 sensor to the Com
- and Boil Sup terminals (1 and 2) (FIG. 31). The boiler sup-
ply sensor is used by the control to measure the boiler sup-
ply water temperature.
Each terminal block must be unplugged from its header on
the control before power is applied for testing. To remove
the terminal block, pull straight down from the control.
The following tests are to be performed using standard test-
ing practices and procedures and should only be carried out
by properly trained and experienced persons.
19
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A good quality electrical test meter, capable of reading from DHW Demand
at least 0 - 300 V (ac) and at least 0 - 2,000,000 ohm, is
essential to properly test the wiring and sensors.
If a DHW demand is used, measure the voltage between
the Setp / DHW and the Com Dem terminals (8 and 7)
(FIG. 35). When the DHW demand device calls for heat, a
voltage between 20 and 260 V (ac) should be measured at
the terminals. When the DHW demand device is off, less
than 5 V (ac) should be measured.
ƽ TEST THE SENSORS
In order to test the sensors, the actual temperature at each
sensor location must be measured. A good quality digital
thermometer with a surface temperature probe is recom-
mended for ease of use and accuracy (FIG. 33). Where a
digital thermometer is not available, a spare sensor can be
strapped alongside the one to be tested and the readings
compared. Test the sensors according to the instructions in
INS7141.
Set Point Demand
If a set point demand is used, measure the voltage between
the Setp / DHW and the Com Dem terminals (8 and 7) (FIG.
35). When the set point demand device calls for heat, you
should measure between 20 and 260 V (ac) at the termi-
nals. When the set point demand device is off, you should
measure less than 5 V (ac).
FIG. 33
TEST THE POWER SUPPLY
Make sure exposed wires and bare terminals are not in con-
tact with other wires or grounded surfaces. Turn on the
power and measure the voltage between the Power L and
Power N terminals (10 and 9) (FIG. 34) using an AC volt-
meter, the reading should be between 103.5 and
126.5 V (ac).
10
9
V
103.5 to 126.5 V (ac)
Power
L
N
FIG. 35
External Input
If an external input is used, measure the voltage between
the Com - and the Out + terminals (1 and 4). When the
external input device calls for heat, you should measure
between 0 and 10 V (dc) at the terminals.
FIG. 34
ƽ TEST THE POWERED INPUTS
Boiler Demand
If a boiler demand is used, measure the voltage between
the Boil Dem and the Com Dem terminals (6 and 7)
(FIG. 35). When the boiler demand device calls for heat,
you should measure between 20 and 260 V (ac) at the ter-
minals. When the boiler demand device is off, you should
measure less than 5 V (ac).
FIG. 36
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bleshooting information supplied with the boiler. (The boiler
may have a flow switch that prevents firing until the primary
pump (P1) or boiler pump is running.) If the boiler operates
properly, disconnect the power and remove the jumper.
ƽ TEST THE OUTPUTS
Primary Pump (Prim P1)
If a primary pump is connected to the Prim P1 terminal (11),
make sure that power to the terminal block is off and install
a jumper between the Power L and Prim P1 terminals (10
and 11) (FIG. 37). When power is applied to the Power N
and Power L terminals (9 and 10) (FIG. 37), the primary
pump should start. If the pump does not turn on, check the
wiring between the terminal block and pump and refer to
any installation or troubleshooting information supplied with
the pump. If the pump operates properly, disconnect the
power and remove the jumper.
If a boiler pump is connected to the Relay 1 terminals (14
and 15) (FIG. 39), make sure that power to the terminal
block is off and install a jumper between the terminals.
When power is applied to the circuit, the boiler pump should
start. If the pump does not turn on, check the wiring
between the terminal block and pump and refer to any
installation or troubleshooting information supplied with the
pump. If the pump operates properly, disconnect the power
and remove the jumper. Repeat the above procedure for
Relay 2 to Relay 9.
11
0
1
9
Prim
P1
Power
L
N
15
15
14
14
Relay
Relay
1
1
1
1
N
L
FIG. 37
FIG. 39
Combustion Air or Alarm (C.A. / Alarm)
Relay 9 / DHW
If a combustion air damper or an alarm is connected to the
C.A. / Alarm terminals (12 and 13), make sure power to the
damper or alarm circuit is off and install a jumper between
terminals (12 and 13) (FIG. 38). When the circuit is powered
up, the combustion air damper should open or the alarm
should activate. If the damper or the alarm fails to operate,
check the wiring between the terminals and the damper or
the alarm and refer to any installation or troubleshooting
information supplied with these devices. If the damper or
the alarm operates properly, disconnect the power and
remove the jumper.
If a DHW pump or DHW valve is connected to the Relay 9 /
DHW contact (30 and 31) (FIG. 40), make sure the power to
the pump or valve circuit is off and install a jumper between
those terminals. When the DHW circuit is powered up, the
DHW pump should turn on or the DHW valve should open
completely. If the DHW pump or valve fails to operate, check
the wiring between the terminals and the pump or valve and
refer to any installation or troubleshooting information sup-
plied with these devices. If the DHW pump or valve oper-
ates correctly, disconnect the power and remove the
jumper.
C.A./
Alarm
FIG. 38
Relay 1 to Relay 9
FIG. 40
If a boiler stage is connected to the Relay 1 terminals (14
and 15) (FIG. 39), make sure power to the boiler circuit is
off, and install a jumper between the terminals. When the
boiler circuit is powered up, the boiler should fire. If the
boiler does not turn on, refer to any installation or trou-
21
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ƽ CONNECTING THE CONTROL
Make sure all power to the devices and terminal blocks is
off, and remove any remaining jumpers from the terminals.
Reconnect the terminal blocks to the control by carefully
aligning them with their respective headers on the control,
and then pushing the terminal blocks into the headers. The
terminal blocks should snap firmly into place, see Figure 41.
TM
Install the supplied safety dividers between the unpowered
sensor inputs and the powered or 115 V (ac) wiring cham-
bers.
Apply power to the control. The operation of the control on
power up is described in the Sequence of Operation section
of this instruction manual.
FIG. 42
EXTERNAL INPUT / STAND ALONE
The External Input / Stand Alone DIP switch selects whether
a Lochinvar Outdoor Sensor TST2311 or an external 0 - 10
V (dc) input signal is to be connected to the Com - and the
Out + terminals (1 and 4) (FIG. 43).
FIG. 41
CLEANING THE CONTROL
The control’s exterior can be cleaned using a damp cloth.
Moisten the cloth with water and wring out prior to wiping
the control. Do not use solvents or cleaning solutions.
DIP SWITCH SETTINGS
FIG. 43
GENERAL
ADVANCED / INSTALLER
The DIP switch settings on the control are very important
and should be set to the appropriate settings prior to mak-
ing any adjustments to the control through the User
Interface. The DIP switch settings change the items that are
available to be viewed and / or adjusted in the User
Interface.
The Adv / Installer DIP switch selects the access level of the
control (FIG. 44). In the Installer access level, a limited
number of items may be viewed and / or adjusted. In the
Advanced access level, all items may be viewed and / or
adjusted.
If a DIP switch is changed while the control is powered up,
the control responds to the change in setting by returning
the display to the VIEW menu, see Figure 42.
ALARM / COMBUSTION AIR
FIG. 44
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The Alarm / C.A. DIP switch selects whether a combustion The Fixed Lead / Off DIP switch selects whether or not the
air damper or alarm device is to be connected to the C.A. / first boiler is to be included in the rotation sequence. If the
Alarm terminals (12 and 13) (FIG. 45).
DIP switch is set to Fixed Lead, the first boiler is always the
first to fire (FIG. 48). This DIP switch is only active when the
Rotate / Off DIP switch is set to Rotate.
ROTATE / OFF
FIRST ON / LAST OFF OR FIRST ON / FIRST OFF
FIG. 45
FIG. 48
The Rotate / Off DIP switch selects whether or not the con-
trol is to provide Equal Run Time Rotation of the boiler
stages. If the switch is set to Rotate, the stages will be rotat-
ed accordingly. If the switch is set to Off, the firing
sequence is fixed starting with the lowest stage to the
highest stage (FIG. 46).
The First On / Last Off or First On / First Off DIP switch
selects whether the first boiler is the first to stage on and the
last to stage off or the first to stage on and the first to stage
off. This DIP switch is only active when the Rotate / Off DIP
switch is set to Rotate and the Fixed Lead / Off DIP switch
is set to Fixed Lead (FIG. 49).
FIXED LAST / OFF
OFF / EXERCISE
FIG. 46
FIG. 49
The Fixed Last / Off DIP switch selects whether or not the
last boiler is to be included in the rotation sequence. If the
DIP switch is set to Fixed Last, the last boiler is always the
last to fire (FIG. 47). This DIP switch is only active when the
Rotate / Off DIP switch is set to Rotate.
The Off / Exercise DIP switch selects whether or not the
control is to exercise the primary pump and boiler pumps
(FIG. 50). If the DIP switch is set to Exercise, the pumps are
operated for 10 seconds after every three days of inactivity.
FIXED LEAD / OFF
FIG. 47
FIG. 50
23
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5
6
24
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A
7
A
A
8
9
1
25
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This item is only available if the External Input /
Stand Alone DIP switch is set to Stand Alone.
The item is only available if the External /
Input Stand Alone DIP switch is set to Stand Alone.
This item is only available if the External Input / Stand
Alone DIP switch is set to Stand Alone.
26
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Boiler Minimum
Boiler Maximum
Fire Delay 1
Fire Delay 2
Combustion Air Damper Delay
Boil Mass
Stage Delay
Boiler Differential
Staging
lohi
DHW Mode
1
2
3
4
DHW Exchange Occupied
DHW Exchange Unoccupied
27
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(This item is only available when DHW
MODE is set to OFF.)
x
m weather
(This item is only available if the External Input/
Stand Alone DIP switch is set to Stand Alone.)
time that the primary pump will continue to operate
after the boiler demand has been removed.
28
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present, the fourth stage is turned on.
• After ten seconds, all stages and the boiler pump
are turned off.
TESTING THE CONTROL
The control has a built-in test routine that is used to test the
main control functions. The control continually monitors the
sensors and displays an error message whenever a fault is
found. See the following pages for a list of the control’s
error messages and possible causes. When the Test but-
ton is pressed, the test light is turned on. The individual out-
puts and relays are tested in the following test sequence.
Step 4 If DHW MODE is set to 1 or 2 and the last boiler in
modes 1, 4, and 5 are set to OFF, the primary pump is shut
off and the DHW contact is closed.
Step 5 If DHW MODE is set to 3 or 4 and the last boiler in
modes 1, 4, and 5 are set to OFF, the primary pump stays
on and the DHW contact is closed.
Step 6 All contacts are turned off.
MAX HEAT
The control has a function called Max Heat, see Figure 52.
In this mode, the control turns on and operates the system
up to the maximum set temperatures as long as there is a
demand for heat. The control continues to operate in this
mode for up to 24 hours or until the Item, Menu or Test but-
ton is pressed. This mode may be used for running all cir-
culators during system start-up in order to purge air from the
piping. To enable the Max Heat feature, use the following
procedure.
FIG. 51
TEST SEQUENCE
1) Press and hold the Test button for more than 3 seconds.
At this point, the control flashes the MAX segment and dis-
plays the word OFF.
Each step in the test sequence lasts 10 seconds.
During the test routine, if a demand from the system is pres-
ent, the test sequence may be paused by pressing the Test
button. If the Test button is not pressed again for 5 minutes
while the test sequence is paused, the control exits the
entire test routine. If the test sequence is paused, the Test
button can be pressed again to advance to the next step.
This can also be used to rapidly advance through the test
sequence. To reach the desired step, repeatedly press and
release the Test button until the appropriate device and seg-
ment in the display turn on.
2) Using the up or down arrow buttons, select the word On.
After 3 seconds, the control turns on all outputs. However,
the max heat mode is still limited by the BOIL MAX setting.
3) To cancel the Max Heat mode, press the Item, Menu, or
Test button.
4) Once the Max Heat mode has either ended or is can-
celled, the control resumes normal operation.
Step 1 The primary pump is turned on and remains on for
the entire test routine.
Step 2 If the Alarm / C.A. DIP switch is set to Alarm, the
Alarm contact is turned on for 10 seconds and then shuts
off. If the Alarm / C.A. DIP switch is set to C.A, the com-
bustion Air Damper contact is turned on and remains on for
the entire test routine.
Step 3 For each boiler that is set to Auto, the following test
sequence is used.
• If the mode indicates that a boiler pump is used,
the boiler pump is turned on and remains on.
• Next, the first stage of the boiler is turned on and
remains on.
• If a second stage is present, the second stage is
turned on and remains on.
• If a third stage is present, the third stage is
turned on and remains on. If a fourth stage is
FIG. 52
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ERROR MESSAGES
FIG. 56
FIG. 53
The control is no longer able to read the boiler supply sen-
sor due to a short circuit (FIG. 56). The control will not oper-
ate the boiler(s) until the sensor is repaired. Locate and
repair the problem as described in INS7141. To clear the
error message from the control after the sensor has been
repaired, press either the Menu or Item button.
The control was unable to read a piece of information stored
in its memory (FIG. 53). Because of this, the control was
required to reload the factory settings into all of the items in
the ADJUST menu. The control will stop operation until all
of the items in the ADJUST menu of the control have been
checked by the user or installer.
Note: The Installer / Adv DIP Switch must be set to Adv in
order to clear the error.
FIG. 57
The control is no longer able to read the boiler supply sen-
sor due to an open circuit (FIG. 57). The control will not
operate the boiler(s) until the sensor is repaired. Locate
and repair the problem as described in INS7141. To clear
the error message from the control after the sensor has
been repaired, press either the Menu or Item button.
FIG. 54
The control is no longer able to read the outdoor sensor due
to a short circuit (FIG. 54). In this case the controlassumes
an outdoor temperature of 32°F (0°C) and continues opera-
tion. Locate and repair the problem as described in
INS7141. To clear the error message from the control after
the sensor has been repaired, press either the Menu or Item
button. This error message only occurs if the External Input
/ Stand Alone DIP switch is set to Stand Alone.
FIG. 58
The control is no longer able to read the boiler return sen-
sor due to a short circuit (FIG. 58). The control will continue
to operate normally. Locate and repair the problem as
FIG. 55
The control is no longer able to read the outdoor sensor due described in INS7141. To clear the error message from the
to an open circuit (FIG. 55). In this case the control control after the sensor has been repaired, press either the
assumes an outdoor temperature of 32°F (0°C) and contin- Menu or Item button.
ues operation. Locate and repair the problem as described
in INS7141. To clear the error message from the control
after the sensor has been repaired, press either the Menu
or Item button. This error message only occurs if the
External Input / Stand Alone DIP switch is set to Stand
Alone.
30
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Power Supply
Relay Capacity
- 115 V (ac) + 10% 50/60 Hz
600 Va
- 230 V (ac) 5 A 1/3 hp pilot duty
230 VA
Demands
- 20 to 260 V (ac) 2 VA
FIG. 59
Sensors Included
- NTC thermistor, 10 k @ 77°F
(25°C + 0.2°C) B=3892
The control is no longer able to read the boiler return sen-
sor due to an open circuit (FIG. 59). The control will contin-
ue to operate normally. Locate and repair the problem as
described in INS7141. To clear the error message from the
control after the sensor has been repaired, press either the
Menu or Item button.
If the boiler return sensor was deliberately removed from
the control, remove power from the control and repower the
control to clear the error message.
Nine StagoeilBer & DHW /oiSnettp
Donot apploywepr
Signal wiinrg mustebarted at least
1 2
3
4 5
6
7
8
9
N
1011 1213141516171819202122232425262728293031
Prmi
Com BoilBoilOutUnO
SupRet + Sw
BoilComSetp
DemDem DH
–
L
P1
1
1
2
2
3
3
4
4
5
5
6
6
7
7
8
8
DHW
FIG. 61
FIG. 60
The installer must ensure that this control and its wiring are
isolated and/or shielded from strong sources of electromag-
netic noise. Conversely, this Class B digital apparatus com-
plies with Part 15 of the FCC Rules and meets all require-
ments of the Canadian Interference - Causing Equipment
Regulations. However, if this control does cause harmful
interference to radio or television reception, which is deter-
mined by turning the control off and on, the user is encour-
aged to try to correct the interference by re-orientating or
relocating the receiving antenna, relocating the receiver
with respect to this control, and/or connecting the control to
a different circuit from that to which the receiver is connect-
ed.
The control has detected no increase in the supply water
temperature within the BOIL Alarm time setting. Check to
see if the boilers are operating properly using the Test but-
ton. To reset the alarm, press and hold the up and down
arrow buttons for 5 seconds while in the VIEW menu.
TECHNICAL DATA
MP2 NINE STAGE BOILER & DHW / SET POINT
Control
- Microprocessor PID control; This
is not a safety (limit) control.
ƽ
CAUTION
The nonmetallic enclosure does not provide grounding
between conduit connections. Use grounding type bush-
ings and jumper wires.
Packaged Weight -
Dimensions
- 3.3 lb. (1500 g), Enclosure A, blue
modified PPO plastic
- 6-5/8" H x 7-9/16" W x 2-13/16" D
(170 x 193 x 72 mm)
Approvals
- CSA C US, meets ICES & FCC
regulations for EMI/RFI
Ambient Conditions
- Indoor use only, 30 to 120°F (0 to
50°C), <95% RH non-condensing
31
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TYPICAL BOILER INSTALLATION
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TYPICAL BOILER INSTALLATION (CONTINUED)
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TYPICAL DWH PRIORITY HEATING PACKAGE SYSTEM
MP2
Tekmar 150 Controller
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NOTES
35
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9/04 - Printed in U.S.A.
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