Trox FSL-U-ZAS Installation And Configuration Manual

Marca: Trox

Modello: FSL-U-ZAS

Tipo: Installation And Configuration Manual

Single room control

system

FSL-CONTROL III

Installation and configuration manual

Read the instructions prior to performing any task!

for decentralised ventilation units

GB/en

A00000080125, 1, GB/en

TROX GmbH

Heinrich-Trox-Platz

47504 Neukirchen-Vluyn

Germany

Phone: +49 (0) 2845 2020

Fax: +49 2845 202-265

E-mail: [email protected]

Internet: http://www.troxtechnik.com

04/2020

Single room control system FSL-CONTROL III2

General information

About this manual

This manual enables personnel to correctly install and

configure FSL-CONTROL III for the control of TROX

decentralised ventilation units.

This manual is intended for use by network administra-

tors, instructed persons, and qualified electricians or air

conditioning technicians.

It is essential that these individuals read and fully under-

stand this manual before starting any work. The basic

prerequisite for safe working is to comply with the safety

notes and all instructions in this manual.

The local regulations for health and safety at work and

the general safety regulations for the area of application

of the ventilation unit also apply.

This manual must be given to the system owner when

handing over the system. The system owner must

include the manual with the system documentation. The

manual must be kept in a place that is accessible at all

times.

Illustrations in this manual are mainly for information

and may differ from the actual design.

Other applicable documentation

Operating and installation manual for the decentral-

ised ventilation unit

Project-specific documents (if any)

This document, including all illustrations, is protected by

product.

Any use without our consent may be an infringement of

damage.

This applies in particular to:

Publishing content

Copying content

Translating content

Microcopying content

Saving content to electronic systems and editing it

TROX Technical Service

To ensure that your request is processed as quickly as

possible, please keep the following information ready:

Product name

TROX order number

Delivery date

Brief description of the fault

Online www.troxtechnik.com

Phone +49 2845 202-400

Limitation of liability

The information in this manual has been compiled with

reference to the applicable standards and guidelines,

the state of the art, and our expertise and experience of

many years.

The manufacturer does not accept any liability for dam-

ages resulting from:

Non-compliance with this manual

Incorrect use

Operation or handling by untrained individuals

Unauthorised modifications

Technical changes

Use of non-approved replacement parts

The actual scope of delivery may differ from the infor-

mation in this manual for bespoke constructions, addi-

tional order options or as a result of recent technical

changes.

The obligations agreed in the order, the general terms

and conditions, the manufacturer's terms of delivery,

and the legal regulations in effect at the time the con-

tract is signed shall apply.

We reserve the right to make technical changes.

Defects liability

For details regarding defects liability please refer to sec-

tion "VI. Warranty Claims" of the Delivery Terms of

TROX GmbH.

The General Delivery Terms of TROX GmbH can be

found on the Internet at www.trox.de.

General information

Single room control system FSL-CONTROL III 3

1 Safety.................................................................. 5

1.1 Symbols used in this manual....................... 5

1.2 Correct use.................................................. 5

1.3 Safety signs................................................. 5

1.4 Electric shock hazard.................................. 6

1.5 Qualified staff............................................... 6

2 Making electrical connections......................... 7

2.1 Wiring.......................................................... 7

2.1.1 Connection of the supply voltage............. 7

2.1.2 Connection of the control panel................ 7

2.1.3 Connection of room temperature

sensor....................................................... 9

2.1.4 Connection of external inputs and out-

puts......................................................... 10

2.1.5 Communication FSL-CONTROL III........ 11

2.2 Connection to the central building man-

agement system (central BMS)................. 15

2.2.1 Modbus RTU / BACnet MS/TP............... 15

2.2.2 Modbus TCP / BACnet IP....................... 15

3 Control of the ventilation unit........................ 17

3.1 FSL-CONTROL III controller..................... 17

3.1.1 Control components............................... 17

3.1.2 Functional description............................ 17

4 Description of software................................... 25

4.1 Start screen – Diagnostics........................ 26

4.2 Diagnostics menu...................................... 27

4.2.1 ‘Device status è diagnostics’................ 27

4.2.2 ‘Temperature control è diagnostics’..... 28

4.2.3 ‘Fan control è diagnostics’.................... 29

4.2.4 ‘Alarms and filter reset è diagnostics’... 30

4.3 Configuration menu................................... 31

4.3.1 ‘Configuration è device description’...... 31

4.3.2 ‘Configuration è temperature control’... 31

4.3.3 ‘Configuration of è time programme’.... 32

4.3.4 ‘Configuration of è fan control’.............. 33

4.3.5 ‘Configuration of è interfaces’............... 34

4.4 Manual control menu................................. 36

4.4.1 ‘Manual control è commands’............... 36

4.5 Menu for connection to central BMS......... 37

4.5.1 Connection to the central BMS via

Modbus................................................... 37

4.5.2 ‘Connection to central BMS

è device => central BMS’...................... 38

4.5.3 ‘Connection to central BMS

è central BMS => device’...................... 42

4.5.4 Connection to central BMS via BACnet.. 44

5 Control panel................................................... 55

5.1 Overview of control panels........................ 55

5.2 Control panel settings................................ 57

6 Index................................................................. 58

Table of contents

Single room control system FSL-CONTROL III4

1 Safety

1.1 Symbols used in this manual

Safety notes

Symbols are used in this manual to alert readers to

areas of potential hazard. Signal words express the

degree of the hazard.

Comply with all safety instructions and proceed carefully

to avoid accidents, injuries and damage to property.

DANGER!

Imminently hazardous situation which, if not avoided,

will result in death or serious injury.

WARNING!

Potentially hazardous situation which, if not avoided,

may result in death or serious injury.

CAUTION!

Potentially hazardous situation which, if not avoided,

may result in minor or moderate injury.

NOTICE!

Potentially hazardous situation which, if not avoided,

may result in property damage.

ENVIRONMENT!

Environmental pollution hazard.

Safety notes as part of instructions

Safety notes may refer to individual instructions. In this

case, safety notes will be included in the instructions

and hence facilitate following the instructions. The

above listed signal words will be used.

Example:

1. Loosen the screw.

CAUTION!

Danger of finger entrapment when closing

the lid.

Be careful when closing the lid.

3. Tighten the screw.

Tips and recommendations

Useful tips and recommendations as well as informa-

tion for efficient and fault-free operation.

Additional markers

In order to highlight instructions, results, lists, refer-

ences and other elements, the following markers are

used in this manual:

Marker Explanation

1., 2., 3. ...

Step-by-step instructions

ðResults of actions

References to sections in this

manual and to other applicable

documents

Lists without a defined sequence

[Switch] Operating elements (e.g. push but-

tons, switches), display elements

(e.g. LEDs)

‘Display’ Screen elements (e.g. buttons or

menus)

1.2 Correct use

The FSL-CONTROL III controller is designed exclu-

sively for the control of TROX decentralised ventilation

units.

Correct use also involves complying with all the informa-

tion provided in this manual.

Any use that goes beyond the correct use or any dif-

ferent use of the unit is regarded as incorrect use.

1.3 Safety signs

The following symbols and signs are found on the unit.

They apply to the very location where they are found.

Electrical voltage

Safety

Symbols used in this manual

Single room control system FSL-CONTROL III 5

Hazardous electrical voltage that is present in the venti-

lation unit. Only skilled qualified electricians are allowed

to work on parts of the ventilation unit marked with this

symbol. Such work must be carried out only by skilled

qualified electricians or the technical service.

Controls access panel

Only skilled qualified electricians are allowed to open

the controls access panel. Ensure that no voltage is

present on any mains circuit before you open the cover

to access the terminal connections.

1.4 Electric shock hazard

Electric current

DANGER!

Danger of death due to electric current!

Danger of electric shock! Do not touch any live com-

ponents! Damaged insulation or damaged parts are

a life threatening hazard.

– Only a skilled qualified electrician must work on

the electrical systems.

– If the insulation is damaged, disconnect the

power supply immediately and have the insula-

tion repaired.

– Switch off the power supply before you carry out

maintenance or cleaning.

– Ensure that live parts do not come into contact

with moisture. Moisture can cause a short circuit.

1.5 Qualified staff

Qualification

The work described in this manual has to be carried out

by individuals with the qualification, training, knowledge

and experience described below:

Network administrator

Network administrators design, install, configure and

maintain the IT infrastructure in companies or organisa-

tions.

Skilled qualified electrician

Skilled qualified electricians are individuals who have

sufficient professional or technical training, knowledge

and actual experience to enable them to work on elec-

trical systems, understand any potential hazards related

to the work under consideration, and recognise and

avoid any risks involved.

Any work has to be carried out by individuals who can

be expected to carry out their assigned duties reliably.

Individuals whose reaction time is delayed due to

alcohol, drugs or other medication must not carry out

any work.

Safety

Electric shock hazard

Single room control system FSL-CONTROL III6

2 Making electrical connections

DANGER!

Electric shock hazard! Electrical equipment car-

ries a dangerous electrical voltage!

– Only skilled qualified electricians are allowed to

work on the electrical system and to connect the

unit to the mains.

– Disconnect the cable from the mains (all phases)

and secure the unit against being switched on

accidentally.

– Ensure that no voltage is present.

– Carry out assembly or connection jobs only as

long as no voltage is present.

Notes on the electrical installation

Use only cables that are designed for the supply voltage

for which they will be used. The length and cross sec-

tion as well as any contact resistance may increase

voltage losses. The power rating of each unit must also

be considered. A skilled qualified electrician has to

select the correct cable types and sizes. This job must

only be carried out by specialist electrical companies.

For the electrical connection comply with any appli-

cable regulations and follow the code of good prac-

tice. Be sure to comply with the applicable guide-

lines for working on electrical and electronic

equipment as well as with any applicabe local regu-

lations.

The connection data can be found on the rating

plate or in the wiring diagrams.

Protect any connections from physical damage.

Feed cables through the cable glands on the ventila-

tion unit.

Ensure that the unit can be de-energised (all

phases) for maintenance such that no voltage is

present. This requires separators (e.g. fuses or

RCBOs); the distance between contacts should be

at least 3 mm.

For units without integral controls from TROX follow

the instructions of the controls provider.

2.1 Wiring

Personnel:

Skilled qualified electrician

Connect the ventilation unit according to the wiring

diagrams. The position of the electrical connec-

tions (terminal box) can be found in the device-

specific documentation.

2.1.1 Connection of the supply voltage

230 VAC / 50 Hz

Fig. 1: Connection of the supply voltage

1 Connecting cable Ölflex Classic 100 3G 1.5 mm² ca.

1.0 m (supply package TROX)

2 Fuse 3.15 A

3 SCHOOLAIR-V-HV-EH only: fuse 9.0 A

DANGER!

Risk to life from electrical voltage!

The control box may not be opened, it is used for the

internal electrical wiring and may only be opened by

TROX Service personnel.

The electrical connection is made with the con-

necting cable leading from the control box.

2.1.2 Connection of the control panel

Notes on control panels

Select an installation location where the control panel is

not affected by disturbances. Avoid solar gain and

draughts.

Seal the end of the conduit in the junction box as other-

wise a draught could occur in the conduit and affect the

measurement results.

Making electrical connections

Wiring > Connection of the control panel

Single room control system FSL-CONTROL III 7

Honeywell, 5-stage (0, 1, 2, 3, AUTO)

BYP / RTN 6

LED 5

BYP / FAN 4

SET PT 3

SENSOR 2

COM 1

LED / RTN 7

Fig. 2: Wiring of Honeywell control panel, 5

‑

stage to ter-

minal X9

1 Control panel with selector switch, for surface

mounting, type: T7460F1000, TROX order no.

M546FB8

2 LiYCY 5 x 0.5 mm² shielded (by others)

Schneider, without selector switch

LED RET 16

LED 5VDC 14

SET PT 13

SNSR/BUTTON/SETPT RT 12

SNSR/BUTTON 11

Fig. 3: Wiring of control panel STR 504 to terminal X9

1 Control panel without selector switch, for surface

mounting, type: STR 504 TROX order no. M536BA4

2 LiYCY 5 x 0.5 mm² shielded (by others)

Titec, without selector switch

CmT 6

P- 5

P 4

P+ 3

RTD 2

RTD 1

T1 7

17 18

Fig. 4: Wiring of control panel Titec RTF3-NTC20k-P5k-

T-L to terminal X9

1 Control panel without selector switch, type RTF3-

NTC20k-P5k-T-L for surface mounting, TROX order

no. A00000059067

2 LiYCY 5 x 0.5 mm² shielded (by others)

Thermokon, without selector switch

Fig. 5: Wiring of Thermokon control panel to terminal X9

1 Control panel without selector switch for surface

mounting, type WRF04 PTD NTC 20k 5k gn, TROX

order no. A00000079777

2 LiYCY 5 x 0.5 mm² shielded (by others)

Making electrical connections

Wiring > Connection of the control panel

Single room control system FSL-CONTROL III8

Titec, without selector switch, Berker S.1

Fig. 6: Wiring of Berker S.1 control panel to terminal X9

1 Control panel without selector switch, flush mounted

for switch programme Berker BS1 type: BS1-

NTC10k-P5-T-L, TROX order no. A00000074476

2 LiYCY 5 x 0.5 mm² shielded (by others)

Thermokon, without selector switch, Berker S.1

Fig. 7: Wiring of Thermokon control panel to terminal X9

1 Control panel without selector switch, for flush

mounting, suitable for switch programme Berker

S.1, type WRF07 PTD NTC 20k BType6 5k gn,

TROX order no. A00000079778

2 LiYCY 5 x 0.5 mm² shielded (by others)

Thermokon, without selector switch, Busch Jäger

Futura

Fig. 8: Wiring of Thermokon control panel to terminal X9

1 Control panel without selector switch, for flush

mounting, suitable for switch programme Busch

Jäger Futura, type WRF07 PTD NTC 20k BType6

5k gn, TROX order no. A00000079779

2 LiYCY 5 x 0.5 mm² shielded (by others)

2.1.3 Connection of room temperature

sensor

Fig. 9: Connection of room temperature sensor

1 Room temperature sensor, type RTF3-NTC10k,

TROX order no. A00000059069

2 LiYCY 5 x 0.5 mm² shielded (by others)

Making electrical connections

Wiring > Connection of room temperature sensor

Single room control system FSL-CONTROL III 9

2.1.4 Connection of external inputs and

outputs

External switch inputs

+ 24 VDC

Fig. 10: Wiring example of window contact

1 Connecting cable LiYCY 2 x 0.5 mm² (by others)

Terminal connections X3

No. Function Switch

Open Closed

1 Fume cupboard

switch

Inactive Active

2Changeover 1Heating Cooling

3 Operating

enable

Off Automatic

4 Fire emergency

stop 1

Off Automatic

5 Window con-

tact 1

Off Automatic

6 PIR sensor Valid oper-

ating mode

Occupied

1 cable break safety device

External switch outputs

GND

Fig. 11: Wiring example B alarm

1 Connecting cable LiYCY 2 x 0.5 mm² (by others)

Terminal connections X5

No. Connection Voltage /

Current consump-

tion

1Requirements of coolant 124 VDC,

max. 250 mA

2 Requirements of heat

transfer fluid 1

3 Operational readiness

4 B alarm

5 A alarm

6 Enable heating ceiling

7 Enable chilled ceiling

1 changeover mode only

Making electrical connections

Wiring > Connection of external inputs and outputs

Single room control system FSL-CONTROL III10

2.1.5 Communication FSL-CONTROL III

2.1.5.1 Several controllers in a control zone

Up to 11 FSL-CONTROL III devices can be connected in one control zone (1 master device and up to 10 slave

devices).

Fig. 12: FSL-CONTROL III communication 2 devices

Fig. 13: FSL-CONTROL III communication 3 devices

The master device must be installed on one of the two ends of the network (as the first or last device).

Making electrical connections

Wiring > Communication FSL-CONTROL III

Single room control system FSL-CONTROL III 11

Terminal resistor

For smooth data exchange between the controllers, a

resistance of 120 Ohm must be set on the first and last

subscriber, remove the resistances in the other devices

(if available).

Installation location of terminal resistor Fig. 12, Fig. 13

Master devices - Terminal block X2, terminals 1 and 2

Slave devices - Terminal block X1, terminals 1 and 2

Information on network connection

Fig. 14: Wiring

All network connections via shielded cables.

Note: For A- and B+, use a twisted pair ①!

Recommended network cable (by others): e.g. Uni-

tronic BUS LD 2 x 2 x 0.25 mm² or equivalent

Making electrical connections

Wiring > Communication FSL-CONTROL III

Single room control system FSL-CONTROL III12

2.1.5.2 Network with several control zones

Building a network

Control zones can be networked using one of four existing network protocols (Modbus RTU, Modbus TCP, BACnet

MS/TP or BACnet IP). This requires a bus interface card to be connected to the FSL-CONTROL III master controller

in the factory.

Fig. 15: FSL-CONTROL III network configuration, example Modbus RTU; BACnet MS/TP

If the master controller is integrated in a central BMS (by others), it acts as a slave within the bus network, but as

a master within the FSL-CONTROL III system.

Making electrical connections

Wiring > Communication FSL-CONTROL III

Single room control system FSL-CONTROL III 13

Fig. 16: FSL-CONTROL III network configuration, Modbus TCP; BACnet IP

Making electrical connections

Wiring > Communication FSL-CONTROL III

Single room control system FSL-CONTROL III14

2.2 Connection to the central building

management system (central BMS)

2.2.1 Modbus RTU / BACnet MS/TP

Connection of data cables

RS 485

4 (SH)

3 (GS)

2 (B +)

1 (A -)

B +

A -

B +

A -

Fig. 17: Connection of central BMS to the master device

with Modbus RTU / BACnet MS/TP interface

1 Network cable Unitronic BUS LD 2 x 2 x 0.22 (or

equivalent, by others)

2 (coming) from the central building management

system

3 (going) to the next BUS subscriber of the central

BMS

Count up the terminal position from the grey end

plate (direction of the arrow)

The Modbus RTU / BACnet MS/TP interface has termi-

nals for max. two cables of an EIA-485 network. A max-

imum of 32 devices can be operated on one network

segment.

Personnel:

Network administrator

Materials:

Software for bus communication

Browser

1. Strip the insulation from the cable (at least three

wires), insert the bare wires into the terminals and

tighten the screws by hand (only use twisted pair

for B+ and A-).

Make sure that the polarity of the conductor pairs

is correct. Incorrect polarity will result in inverted

data signals and hence communication errors.

2. Fix the data cables to the casing using the wire

clamping bracket.

3. Connect the shield to the SH terminals.

Note: Within a chain (channel) connect the shield

only at one point to the earth. Earthing the shield

at every controller will lead to voltage distur-

bances.

4. To avoid cable reflections, network segments must

be terminated at both ends with 120 Ω bus ter-

minal resistors. Alternatively, the terminal resistors

can be enabled or disabled on the PCB.

Recommended bus cables

Unitronic BUS LD 2 x 2 x 0.22 (or equivalent)

2.2.2 Modbus TCP / BACnet IP

Connection of data cables

Fig. 18: Connection of central BMS to the master device

with Modbus TCP / BACnet IP interface

1 Network cable (coming) from the central building

management system

Network cable min. Cat 5e RJ45 (or equivalent, by

others)

2 Terminal block X7 RJ45 interface

The devices have an RJ45 interface for star-shaped

connection of devices to a Modbus TCP / BACnet IP

network.

Personnel:

Network administrator

Materials:

Software for bus communication

Browser

Insert the RJ45 connector for the cable into the

intended bush (X7).

Each master must be connected with a separate

cable.

Special feature of external control box

e. g. FSL-U-ZAS, FSL-U-SEK)

To simplify maintenance, the connection X7 is

placed in the ventilation unit and is already

connected to the control box with a network

cable. The devices can be connected to the

central BMS with the aid of the network cable.

If the network cable is too short, this can be

extended.

Making electrical connections

Connection to the central building management system (central BMS) > Modbus TCP / BACnet IP

Single room control system FSL-CONTROL III 15

Recommended bus cables

Network cable min. Cat. 5e RJ45

2.2.2.1 Setting the network address

Personnel:

Network administrator

Fig. 19: Connect laptop to the ventilation unit

1 Mobile computer with Ethernet interface

2 Network cable min. Cat 5e RJ45

3 Junction box for network cable

Before operation, the interface for the devices must be

adapted to the existing network structure. The configu-

ration is carries out via the browser,

Chapter

4.3.5 ‘‘Configuration of è interfaces’’ on page 34.

Factory settings SL1 connection X1 serial bus

Address Name Value

16124 Address 1

16129 Baud rate X1 2

16126 Data bits X1 8

16127 Stop bits X1 1

16128 Parity X1 2

Master device configuration of the serial connection

to the central BMS (Modbus RTU, BACnet MS/TP)

Address of terminal X1

This is used for the addressing of all master devices in

the network. Each device is given a unique address. In

a network segment, a maximum of 32 network

addresses (devices) can be used. The permitted

address range is 1 – 128.

For setting information, see

‘Settings SL1 connection

X1 serial bus’ on page 34

Slave device configuration for connection to the

master device

Address of terminal X1

This is used for the addressing of the slave devices in

the master / slave network. If only one slave is con-

nected to a master device, no settings are needed. If

several slave devices (max. 10 units) are connected to

a master device, each slave device must be given a

unique address.

Addressing example:

Slave 1 - Value 2 Modbus address 2

Slave 2 - Value 3 Modbus address 3

Slave n - Value n+1 Modbus address n+1

Slave 10 - Value 11 Modbus address 11

Settings X1

‘Settings SL1 connection X1 serial

bus’ on page 34

Address Name Value

16129 Baud rate

Þ 38400 Baud

Note: No settings are needed, for

communication between the master

and slave, only 38400 baud is sup-

ported.

16126 Data bits

The FSL-CONTROL III controller

only supports 8 data bits.

16127 Stop bits

The FSL-CONTROL III controller

only supports 1 stop bit.

16128 Parity

Þ Even

Note: No settings required. Only

Even is used for communication

between master and slave.

Modbus address terminal X2

The following settings are factory set and do not need to

be changed.

Address Name Value

15774 Modbus address terminal X2 1

Making electrical connections

Connection to the central building management system (central BMS) > Modbus TCP / BACnet IP

Single room control system FSL-CONTROL III16

3 Control of the ventilation

unit

3.1 FSL-CONTROL III controller

System overview

FSL-CONTROL III is a dedicated single room control

system for decentralised TROX ventilation systems.

The FSL-CONTROL III controller can be used to com-

bine the following concepts:

Room temperature control using the room or extract

air temperature

Control of the supply air temperature (isothermal)

Room air quality control (optional)

3.1.1 Control components

The modular design of the hardware allows for adding

optional equipment to the range of functions of the FSL-

CONTROL III controller.

Fig. 20: Controller, valve with thermoelectric actuator

Basic equipment

Controller for master or slave operation

Heating and/or cooling valves including thermo-

electic actuators and lockshields

Supply air temperature sensor

Optional equipment

Control panel including setpoint value adjuster and

room temperature sensor

Outdoor air temperature sensor

Air quality sensor (CO2 / VOC)

Time programme

Valve actuators

Pressure-independent control valve

Interfaces to the central building management

system

– Modbus RTU interface

– Modbus TCP interface

– BACnet MS/TP interface card

– BACnet IP interface

– Digital switch contacts (inputs and outputs)

3.1.2 Functional description

3.1.2.1 General

The FSL-CONTROL III controller is used to control var-

ious parameters for individual rooms.

It is primarily used to control the room temperature, i.e.

to maintain the set parameters and a comfortable room

climate. Alternatively, the supply air can be provided to

the room with a constant temperature. With an air

quality sensor (optional) it is possible to control the fresh

air flow rate based on the air quality.

Configuration in the web browser

The devices are configured using the IP interface

and web browser.

3.1.2.2 Room temperature control

The FSL-CONTROL III controller ensures that the com-

fort temperature range for each operating mode is main-

tained. Cascade control ensures that the comfort tem-

perature range is quickly achieved. The supply air

temperature is controlled within the set range and with

internal and external loads being accounted for. This is

how the comfort requirements are met.

Room temperature control requires that the following

values are measured:

Room temperature, e.g. from an optional control

panel or from the central BMS

Outdoor air temperature, e.g. from the central BMS

or from an optional temperature sensor in the out-

door air intake of the master unit

Supply air temperature

Room temperature control works best when the

room temperature is measured at a carefully

selected point. The control panel is ideally installed

about 1.5 m above the floor. Select an installation

location where the control equipment is not affected

by disturbances (e.g. solar gain or draughts). We

recommend adjusting the flow temperature based on

the outdoor temperature in heating and in cooling

mode.

Control of the ventilation unit

FSL-CONTROL III controller > Functional description

Single room control system FSL-CONTROL III 17

Sample standard factory settings for room tempera-

ture control

Settings Operating mode

Occupied Unoccu-

pied

Room temperature set-

point value, heating

21.8 °C 18.0 °C

Room temperature set-

point value, cooling

22.2 °C 28.0 °C

Comfort temperature

range

21.8 °C –

22.2 °C

18.0 °C –

28.0 °C

Upper limit of supply air

temperature (heating)

42.0 °C 42.0 °C

Lower limit of supply air

temperature (cooling)

18.0 °C 13.0 °C

Demand-based settings

These factory settings have been selected for their

energy efficiency but can be changed in the web

browser.

For a comfortable room climate the supply air tem-

perature in 'Occupied' mode should be at least

18 °C. In heating mode a comfortable room climate

can be achieved with supply air temperatures of up

to 42 °C.

The minimum permitted supply air temperature for

night ventilation is 2K under the supply air tempera-

ture threshold for unoccupied mode.

To prevent the system from constantly changing

between heating and cooling mode, the room tempera-

ture is not controlled to a fixed value, but within a com-

fort temperature range.

When cooling, the room temperature setpoint value

depends on:

Room temperature

Operating mode

Temperature offset (central BMS & control panel)

Outdoor air temperature

When heating, the room temperature setpoint value

depends on:

Room temperature

Operating mode

Temperature offset (central BMS & control panel)

Outdoor air temperature

Winter compensation

Fig. 21: Room temperature control

Control response for room temperature outside the

comfort temperature range:

Room temperature Control response

Below

comfort temperature

range

Heating active,

the room temperature setpoint

value for heating is set.

Above

comfort temperature

range

Cooling active,

the room temperature setpoint

value for cooling is set.

If the room temperature is within the comfort tempera-

ture range, the room temperature setpoint value is set

depending on the outside air temperature.

Control response for room temperature within the

comfort temperature range:

Outdoor air temper-

ature

Control response

Below

comfort temperature

range

Heating active,

the room temperature setpoint

value for heating is set.

Above

comfort temperature

range

Cooling active,

the room temperature setpoint

value for cooling is set.

If the outdoor air temperature is also within the comfort

temperature range, the room temperature setpoint value

is based on the cooling and heating sequence.

If the room temperature setpoint value is changed on a

room control panel (e.g. by entering +2 K), both room

temperature limits and hence the comfort temperature

range are also changed (e.g. by +2 K) as a conse-

quence.

Control of the ventilation unit

FSL-CONTROL III controller > Functional description

Single room control system FSL-CONTROL III18

If the operating mode is set to 'Occupied', the tempera-

ture control is suspended as soon as the room tempera-

ture is within the comfort temperature range.

3.1.2.3 Constant bypass on heat recovery unit

The ventilation units that are equipped with a cross flow

or cross counter flow heat recovery unit have a constant

bypass (0…100%). The bypass is controlled automati-

cally.

The bypass is used to reach the supply air temperature

setpoint value in heating and cooling mode and for the

"Night purge" function. The volume flow rate to be

heated by the heat recovery unit is controlled by the

bypass.

If, for example, the outdoor temperature is low, but an

internal space has to be cooled anyway, use of the

cooling coil can be reduced to a minimum as only a

small portion or even no portion of the air has to pass

the heat recovery unit.

3.1.2.4 Rotary heat recovery unit

In ventilation units with a rotary heat recovery unit, the

rotor speed is automatically adjusted so that the supply

air temperature setpoint value can be reached. During

"Night purge", the rotary motion of the rotor is switched

off.

Due to variable control, use of the cooling coil can be

reduced to a minimum in transition times, i.e. if the out-

door temperature is low but the internal space has to be

cooled anyway.

3.1.2.5 Fan stages

The FSL-CONTROL III controller automatically selects

the correct fan stage based on temperature control or

indoor air quality (optional). The fan stage can also be

pre-set by the central BMS (by others) or from a control

panel.

Fig. 22: Fan stages – priority

3.1.2.6 Air quality control (optional)

Air quality control means that the outdoor air flow rate is

controlled based on the room air quality.

This type of control is only possible with an air quality

sensor (optional equipment or by others). The internal

sensor optionally detects the CO2 concentration or the

VOC content of the extract air. Air quality control is

always active in the ‘Occupied’ operating mode. In the

‘Unoccupied’ operating mode, air quality control is inac-

tive.

Air quality control – factory settings

CO2 value

[ppm]

Fan stage

Outdoor air Secondary air

< 500 1-3

500 – 750 1

750 – 900 2

> 900 3

The system owner can adjust the air quality values.

Secondary air and outdoor air modes

If the current measured value of the indoor air quality

is under the first limit while the bypass is inactive,

this means that secondary air operation is active. As

soon as the configured limit of air quality for fan

stage 1 is exceeded, the unit automatically switches

to outdoor air mode. Preset minimum periods of time

ensure that not too many quick changes between the

fan stages occur.

3.1.2.7 Operating modes / operating mode over-

ride

Automatic operating modes:

Standby

Occupied

Unoccupied

Operating mode override:

Boost

Exercise

Night purge

Fan force

With an operating mode override, the current auto-

matic operating mode is overridden.

Once this override has been completed, the device

returns to automatic mode.

Control of the ventilation unit

FSL-CONTROL III controller > Functional description

Single room control system FSL-CONTROL III 19

The specified operating modes and overrides can be set

using the optional real-time clock and the central BMS.

In addition, the Occupied and Unoccupied operating

modes as well as the Boost and Exercise overrides can

be activated from the control panel.

Various comfort temperature ranges can be defined for

the operating modes Occupied and Unoccupied. You

can define daily schedules and enter a start time for

each operating mode. Using the optional real time clock

(RTC) allows for defining 10 switching points per day. If

no RTC is used, operating modes must be changed by

the central BMS or on the control panel. The comfort

temperature range for the Occupied mode can be modi-

fied on the control panel and by the central BMS.

Standby operating mode

Standby is selected if the room is not occupied and the

ventilation units are not used to maintain the tempera-

ture, e.g. at night.

Recommended:

Standby is used exclusively to protect the device. It

should be selected for periods of prolonged down-

time, e.g. vacation periods, as long as the building

protection is ensured by other heat sources.

Occupied operating mode

The Occupied mode is used for occupied rooms.

The following parameters can be set:

Comfort temperature range for the Occupied mode

Supply air temperature limits for heating/cooling

Recommended

All-day use (e.g. 7am to 5 pm)

Unoccupied operating mode

The Unoccupied mode is used for unoccupied rooms.

The following parameters can be set:

Comfort temperature range for Unoccupied mode

Supply air temperature limits for heating/cooling

Unoccupied

–This operating mode is used to protect the

building; it is required for night purge.

–Air quality control is not possible with this oper-

ating mode.

Boost operating mode override

Boost can be selected to quickly ventilate a room, e.g.

during break times. The device ensures supply air/

extract air operation to improve the indoor air quality.

Afterwards, the device returns to the Occupied oper-

ating mode.

The following parameters can be set:

Fan setting (default: stage 4)

Duration (default: 15 mins)

Boost

Boost mode can be enabled using the control panel

or central BMS. The same setpoint values that are

used for Occupied mode are used for the comfort

temperature range and supply air temperature limits.

Exercise operating mode override

Exercise can be selected if acoustically optimised oper-

ation is required. The device conveys a slightly reduced

volume flow rate in supply air/extract air operation to

improve the indoor air quality. Afterwards, the device

returns to the Occupied operating mode.

The following parameters can be set:

Fan setting (default: stage 2)

Duration (default: 60 mins)

Exercise

Exercise mode can be enabled using the room con-

trol panel or the central BMS The same setpoint

values that are used for Occupied mode are used for

the comfort temperature range and supply air tem-

perature limits.

Nigh purge operating mode override

With the Night purge function, the room is passively

cooled with outdoor air. The minimum supply air temper-

ature corresponds to the supply air temperature limit for

heating in Unoccupied mode of -2K. The fans are con-

trolled in the configured stage for night ventilation. The

max. fan stage for Unoccupied operating mode is

ignored for the duration of night ventilation.

The following conditions must be simultaneously ful-

filled:

Night purge is activated

The current month is in the range Start – End –

Month (default: May – September)

Activated by RTC, central BMS or DI

Outdoor air temperature > minimum outdoor air tem-

perature for Night purge (default = 12 °C)

Outdoor air temperature < as a setpoint value for

cooling in the Occupied operating mode

Control of the ventilation unit

FSL-CONTROL III controller > Functional description

Single room control system FSL-CONTROL III20

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