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5

Available programs 

OPTIMISER

®

digital regulator code 152200 can be used in accordance with 6 different system configurations (programs), comprising a basic

factory-set configuration and 5 optional configurations selectable by means of the table shown below and activatable by means of the dipswitches

on the regulator. To access the dipswitches open the cover under the display. The regulator is supplied with the factory settings and probes

required to perform basic program 4.

Location of cable glands

When making the electrical connections, observe the following sequence for wiring the terminal board.

- If the regulator is to be wall mounted with the consequent use of the supplied cable glands and downward cable outlet, regulations require that just

one cable can transit through each hole of the cable gland, therefore a maximum of 6 high voltage cables and 6 low voltage cables can be utilised.

It is therefore recommended to comply with the following table of connections and use two additional junction boxes complete with suitable inlet and

outlet cable glands, in accordance with the diagram given. The earth connection must be made in the junction box.

- If the regulator is installed in an electrical cabinet, the cable outlet must be via the openings at the rear of the unit, always keeping high and

low voltage cables separated. The earth connection must be made in the electrical cabinet.

NOTE The probes are all of the NTC type (grey cable) except for probe Sol1 utilised by solar programs 7, 8 and 9, which
is type Pt1000 with 

red cable.

* refer to operating logic of program “management of inertial water storage in parallel on the heating system” on the next page.

Program

configuration

Description

Probes utilised

Position of

program

selectors 

(dipswitches)

Software

code

Hydraulic

diagram
on page

(basic factory set

program)

H management of

inertial water storage in

parallel on the heating

system*

S1

-

-

S4

S5

PR83

7

5

Heating and domestic hot water

with s management of

inertial water storage in parallel

on the heating system*

S1

S2

-

S4

S5

PR84

8

6

Heating and instantaneous

domestic hot water + management

of inertial water storage in parallel

on the heating system*

S1

S3

-

S4

S5

PR85

9

7

Heating with direct inertial

water storage with tank-in-

tank domestic hot water

production, solar system

S1

-

Sol 1

Sol 2

-

PR86

10

8

Heating with direct inertial

water storage, domestic hot

water storage integrated with

solar system 

S1

S2

Sol 1

Sol 2

-

PR87

11

9

Heating with direct inertial water

storage integrated with solar

system, instantaneous domestic

hot water production 

S1

S3

Sol 1

Sol 2

-

PR88

12

ON

1 2 3 4

ON

1 2 3 4

ON

1 2 3 4

ON

1 2 3 4

ON

1 2 3 4

ON

1 2 3 4

Electric connection

Recommended electrical cable:

nr. wires for cross-section

Dedicated

cable gland

HIGH 

VOL

TAGE

Electric supply

2x1,5 mm

2

A

Pump P1

4x1 mm

2

B

Pump P2

Gas generator contact C

4x1 mm

2

C

Solid fuel generator contact K

Diverter valve V1

4x1 mm

2

D

Diverter valve V4 to optional dissipator 

Domestic priority diverter valve V2 or domestic priority

diverter valve V3 

6x1 mm

2

E

SOLARINCAL type diverter valve

Valve V5 for loading the inertial water storage in

parallel or solar circuit pump Psol

2x1 mm

2

F

LOW 

VOL

TAGE

Probe S1

2x0,75 mm

2

G

Probe S5 or solar water storage probe Sol2

2x0,75 mm

2

H

Probe S4 or solar collector probe Sol1

2x0,75 mm

2

I

Room thermostat TA or adjustment thermostat TR contact

2x1 mm

2

L

Domestic water storage probe S2 or probe S3 on

domestic heat exchanger outlet

2x0,75 mm

2

M

Flow switch F

2x0,75 mm

2

N

HIGH VOLTAGE

JUNCTION BOX

LOW VOLTAGE

JUNCTION BOX

HIGH VOLTAGE

LOW VOLTAGE

Programs 1,2 and 3 (not listed in the table but however available) are functionally equivalent to programs 7,8 and 9 respectively but without

thermal solar components. For specific setting (dipswitches and probes to be used) please see instruction sheet 28169 (www.caleffi.com).

Summary of Contents for BIOMASS OPTIMISER 1522 Series

Page 1: ...m according to the heating circuit needs Depending on the type and quantity of installed probes the regulator supports the following system solutions heating production of domestic hot water by means...

Page 2: ...acilitate any system checks to be performed When the solid fuel generator is equipped with an anti condensation valve it is good practice to set the minimum working temperature of the solid fuel gener...

Page 3: ...20 1078 95 1366 25 1097 100 1385 30 1117 105 1404 35 1136 110 1423 40 1155 115 1442 45 1175 120 1461 50 1194 140 1536 55 1213 160 1611 60 1232 170 C 20 18 16 14 12 10 8 6 4 14616 13211 11958 10839 98...

Page 4: ...is equipped with a solid fuel generator overtemperature monitoring function When the user settable emergency temperature is reached on the solid fuel generator the regulator generates an alarm signal...

Page 5: ...eating management of inertial water storage in parallel on the heating system S1 S4 S5 PR83 7 5 Heating and domestic hot water with storage management of inertial water storage in parallel on the heat...

Page 6: ...ed heat energy is thus drawn from the parallel water storage Phase 4 gas boiler activation Only when the solid fuel generator is not operating and the parallel water storage has no energy reserve it i...

Page 7: ...s S1 located on the solid fuel generator flow pipe S5 located on the heat exchanger return line and S4 located on the parallel water storage For probe S5 it is advisable to use the following working s...

Page 8: ...ure readings of probes S1 located on the solid fuel generator flow pipe S5 located on the heat exchanger return line and S4 located on the parallel water storage For probe S5 it is advisable to use th...

Page 9: ...olid fuel generator flow pipe S5 located on the heat exchanger return line and S4 located on the parallel water storage For probe S5 it is advisable to use the following working set points 45 C for ra...

Page 10: ...Sol1 on the solar collector and probe Sol2 on the lower section of the tank in tank water storage if higher than the set value solar circuit pump Psol is started Pump Psol continues to run for a selec...

Page 11: ...rature difference T is checked between probe Sol1 on the solar collector and probe Sol2 on the lower section of the domestic water storage if higher than the set value solar circuit pump Psol is start...

Page 12: ...the solar collector and probe Sol2 on the lower section of the direct inertial water storage if higher than the set value solar circuit pump Psol is started Pump Psol continues to run for a selectabl...

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