Safety Lighting according to DIN EN 50171 Central ... · Safety lighting · Supply systems for safety services RSV Ruhstrat Stromversorgungen GmbH · Heinestraße 12 · D-37120 Bovenden

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es

1RSV Ruhstrat Stromversorgungen GmbH · Heinestraße 12 · D-37120 Bovenden · phone: +49-55 93-9 37 22-0 · fax: +49-55 93-9 37 22-222 · e-mail: [email protected] · web: www.ruhstrat.eu

with free choice for mixed mode operation, individual lamp or circuit monitoring, internal or external circuits and special voltages

Central Emergency Lighting System

Safety Lighting according to

DIN EN 50171DIN EN 50172(VDE 0108 Part 100)E DIN VDE 0108-100DIN EN 50272-2

RUSIC®

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es

2 RSV Ruhstrat Stromversorgungen GmbH · Heinestraße 12 · D-37120 Bovenden · phone: +49-55 93-9 37 22-0 · fax: +49-55 93-9 37 22-222 · e-mail: [email protected] · web: www.ruhstrat.eu

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

esTable of contents

1. Introduction ................................................................................................................................................................................................... 42. Product overview ......................................................................................................................................................................................... 53. DIN VDE 0108-100 Safety lighting ................................................................................................................................................... 4-11 3.1 Power supply systems ................................................................................................................................................................................. 6 3.1.1 Central power supply system (CPS) .............................................................................................................................................. 6 3.1.2 Low power supply system (LPS) .................................................................................................................................................... 6 3.1.3 Self-contained battery unit ............................................................................................................................................................ 6 3.2 Battery ............................................................................................................................................................................................................ 6 3.2.1 Design ................................................................................................................................................................................................... 6 3.2.2 Battery capacity ................................................................................................................................................................................. 6 3.3 Charging .......................................................................................................................................................................................................... 6 3.4 Changeover ..................................................................................................................................................................................................... 6 3.5 Rated operation duration ........................................................................................................................................................................... 6 3.6 Rated luminous flux ..................................................................................................................................................................................... 6 3.7 Operating time ............................................................................................................................................................................................... 6 3.8 Response time ................................................................................................................................................................................................ 6 3.9 Circuits - central power systems for safety lighting .......................................................................................................................... 6 3.10 Cable concepts – centrally feeded safety lighting ............................................................................................................................. 7 3.11 Final circuits - number of luminaires ...................................................................................................................................................... 9 3.12 Installation of system and battery .......................................................................................................................................................... 9 3.13 Functional integrity ....................................................................................................................................................................................10 3.14 Control and bus systems ...........................................................................................................................................................................10 3.15 Inspection ...................................................................................................................................................................................................... 11 3.15.1 Inspection system ........................................................................................................................................................................... 11 3.15.2 Log book ........................................................................................................................................................................................... 11 3.15.3 Inspection procedure – deadlines ............................................................................................................................................. 11 3.15.3.1 Initial inspection ............................................................................................................................................................ 11 3.15.3.2 Periodic inspections ...................................................................................................................................................... 114. RUSIC® central emergency lighting system - Technical informations ..................................................................................12-15 4.1 Benefits of the RUSIC® central emergency lighting system ........................................................................................................... 12 4.2 Monitoring .................................................................................................................................................................................................... 13 4.3 System configuration ................................................................................................................................................................................ 13 4.4 RUSIC® central emergency lighting systems - types ..................................................................................................................14-155. RUSIC® central emergency lighting systems - components .......................................................................................................... 16 5.1 Central unit RUE .......................................................................................................................................................................................... 16 5.2 R-Port ............................................................................................................................................................................................................. 16 5.3 Internal circuit card RESK ........................................................................................................................................................................ 16 5.4 Built-in printer RPD .................................................................................................................................................................................... 16 5.5 External signalling device RMTB ............................................................................................................................................................ 16 5.6 External circuit module RSKM ................................................................................................................................................................ 17 5.7 Monitoring device RÜB for individual luminaire monitoring ......................................................................................................... 17 5.8 Digital input and phase monitor RDN-EA ........................................................................................................................................... 18 5.9 RTLA Stairs light module .......................................................................................................................................................................... 19 5.10 Phase monitor RPW-N and RPW-S ....................................................................................................................................................... 19 5.11 Small distribution with functional integrity E 30 type RAK .......................................................................................................... 19 5.12 Sub-distribution with functional integrity E 30 type RBUV ..........................................................................................................20 5.13 Distribution type SKV* ..............................................................................................................................................................................206. Switch cabinet system SG ........................................................................................................................................................................ 217. Combi cabinet KG .......................................................................................................................................................................................228. Batteries ........................................................................................................................................................................................................229. Battery cabinet system BG ......................................................................................................................................................................23


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Introduction

As a provider of complete solutions, we help you from the planning until the installation. We deliver everything from one source, provide replacements within a very short time and maintain the systems if desired.

Customer requirements and the most difficult technical requirements are fulfilled individually by us.

We can look back on more than 80 years of experience in the area of “safe-ty power supplies”. The first emergency lighting system for places of public assembly was installed by Ruhstrat as early as 1920.

As a competent provider of battery-supported power supplies, we special-ise in additional safety power supplies (BSV – so far ZSV) and uninterruptible power supplies (UPS) as well as modern emergency lighting systems on direct current power supplies. ZSV systems from Ruhstrat are used for OP lighting and life supporting medical equipment in hospitals. Our UPS systems ensure the power supply in industrial systems and computer networks.

Well advised for safety

RSV Ruhstrat Stromversorgungen is a modern medium-sized family-owned company whose successful family tra-dition has been continued by the forth generation now. Since the foundation in 1888, our quality products of the field of electrical engineering and plant construction have been established.

The RSV Ruhstrat Stromversorgungen is a technology provider in the segment electrical engineering. The product fo-cus of the electrical engineering are the emergency power supply with the emergency escape lighting.

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es

5

phot

ocas

e: e

lke

Product overview

n DC Power Supply for stationary battery systems

nBattery-supported Central Power Supply Systems (BSV – so far ZSV) - according to DIN VDE 0100- 710 and VDE 0558-507

n Escape Sign and Emergency lighting luminaires for n Central Power Supply Systems n Self-contained battery units

n Emergency Lighting Systems and Central Power Supply Systems

n Uninterruptible Power Supply (UPS)

RSV Ruhstrat Stromversorgungen GmbHHeinestr.12 37120 Bovenden Germany

phone: +49-55 93-9 37 22-0 fax: +49-55 93-9 37 22-222

e-mail: [email protected] web: www.ruhstrat.eu

RSV Ruhstrat Stromversorgungen GmbH · Heinestraße 12 · D-37120 Bovenden · Tel.: +49-55 93-9 37 22-0 · Fax: +49-55 93-9 37 22-222 · E-Mail: [email protected] · Web: www.ruhstrat.eu

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


3.1 Power supply systemsCentral power supply systems that are used for systems acc. to DIN VDE 0108-100 (DIN EN 50172) have to correspond to DIN EN 50171.

Self-contained battery units have to ful-fill requirements resulting from DIN VDE 0108-100 and DIN EN 60598-2-22. For the monitoring respectively for luminiares with automatic control systems DIN EN 62034 has to be respected.

Please refer to annex A of DIN V VDE V 0108-100 to see which power supply sys-tem can be used in which building premi-ses (see table 1).

3.1.1 Central power supply system (CPS) Central power supply system which sup-plies the required emergency power to essential safety equipment without any limitation in power output. – design life of battery ≥10 years – at an ambient temperature of 20 °C

3.1.2 Low Power supply system (LPS) Central power supply system with a limi-tation of the power output to 500 W for 3 h or 1500 W for 1 h – design life of battery ≥5 years – at an ambient temperature of 20 °C

3.1.3 Self-contained battery unitSelf-contained luminaires consist of bat-tery, lamp, control unit as well as control and monitoring unit (if destined) - they can either be in the lamp’s housing or they can be near to it (that is within a cable length of 1 m).

The batteries normally are maintenance-free NiCd batteries - the complete system has to be designed acc. to EN 60598-2-22 so that the battery should stay in good order at least 4 years within the usual application environments. – design life of battery ≥ 4 years – at an ambient temperature of 20 °C

It is allowed to use other batteries if they conform to the corresponding standards concerning safety and servicability as well as requirements of DIN EN 60598-2-22. The used battery capacities depend on the rated operation duration (1 h, 3 h, 8 h) and on the used lamps.

Note: NiCd batteries are excluded from the interdiction of use in emergency light systems by the European Battery Directive.

3.2 BatteryBatteries used in safety lighting must comply to requirements acc. to DIN EN 50272-2.

3.2.1 Design A battery consists of one or several cells connected to each other. These cells are a group of components consisting of elect-rode and electrolyte.There are: – Closed cells – through the top cover gases can escape

– Sealed cells – gas can escape at a pre-determined pressure value – normally electrolyte can not be refilled

– Gastight cells – do not set gas or liquid free if indicated operating conditions are respected – do not need any addi-tional electrolyte all through their life time

Typical sorts of battery: – NiCd – nickel cadmium – OPzS – stationary closed lead acid battery liner plate low-maintenance

– OGi – stationary closed lead acid battery grid plates low-maintenance

– OGiV – stationary lead acid battery grid plates sealed maintenance-free

3.2.2 Battery capacityThe needed battery capacity has to be calculated acc. to the connected lamps and their electrical power and the needed rated operation duration (see table 2).

The battery manufacturer differ batteries by the rated operation duration, C1, C3, C8 and C10 types. EUROBAT suggests for comparability reasons always the capacity of type C10, plus 25 % reserve in order to allow for aging of battery.

3.3 ChargingBattery charger must comply with DIN EN 60146-1 and DIN EN 50272-2. – within 12 h loading 80 % battery-capacity

– IU charging line – ambient range 20 °C +/-5 °C

3.4 ChangeoverSwitching from normal operation to emergency operation shall start automa-

tically if the supply voltage falls below 0,6 × rated supply voltage. It shall be restored if the supply voltage is greater than 0,85 rated supply voltage.

3.5 Rated operation durationThe time given by the manufacturer du-ring which the dimensioning luminous flux is emitted [DIN EN 60598-2-22]. The ra-ted operation duration is the the nominal operating time acc. to DIN EN 1838.

3.6 Rated luminous fluxLuminous flux that is emitted acc. to manufacturer’s instructions after 60 s (0.5 s at working places with particular hazard) after a dysfunction of the general electric power supply and from this on till the end of the rated operation duration. [DIN EN 60598-2-22]

3.7 Operating timeDIN EN 1838 stipulates an operating time of safety lighting for escape routes of min. 1 h. For high risk task area lighting the rated operating time must be the time during which the potential dangerous si-tuations for people exists (DIN EN 1838). The rated operating time matches the rated operation time acc. DIN V VDE V 0108-100 and DIN EN 60598-2-22.

3.8 Response timeResponse time is the time between the failure of the normal power supply and the auxiliary power supply ernergizing the safety lighting. DIN V VDE V 0108 stipula-tes different response times for the emer-gency power supply depending on the use of the building (0,5 s, 1 s and 15 s, see table 1). DIN EN 1838 specifies “response times” based on lighting applications re-quirements - The “response time” accor-ding to DIN EN 1838 specifies after which time a certain luminous intensity must be achieved (i.e. after 5 s 50 % and after 60 s 100 % of the required luminous intensity).

3.9 Circuits – central power systems for safety lightingBasically, independent cables leading from the central power system to the respective fire area ensure the functional integrity of safety lighting in case of fire. The func-tional integrity of the “supply lines” is required between the central power sys-tem and the first luminaire or distribution in the respective fire area. Each line has

DIN VDE 0108-100 Safety Lighting

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


to be electrically protected by a separate fuse. By this concept of wiring one can assume, that the fire will firstly affect a limited part of the building only and the complete safety lighting in the rest of the building remains still ready for operation.

The complete breakdown of safety ligh-ting in the part of the building affected by the fire is continued to be delayed by the following redundance. If there are more than two emergency luminaires in one room or at one escape route VDE 0108-100 requires that they have to be independently fused in an alternating way. In the “classical” sense this redundancy requires at least 4 lines with functional integrity leading from the battery system to each fire area as every second emer-gency sign luminaire (in maintained mode DS) and every second security luminaire (in non-maintained mode BS) are connec-ted to differentcircuits (see figure 1 on page 8).

It is possible to achieve the same level of safety by the so called “mixed mode ope-ration” (see figure 2). Here, every second luminaire in maintained mode and in non-maintained mode can be connected to the

same final circuit – so the required mini-mum number of circuits for one fire area is two . If one final circuit breaks down every second safety and every second escape sign luminaire stays active.

3.10 Cable concepts – centrally fee-ded safety lightingBasically, independent cables leading from the central battery to the respective fire compartment ensure the functional relia-bility of an safety lighting in case of fire. These supply lines have to maintain their performance up to the first lamp or the first distributor in the fire compartment and have to be electrically protected. By this way of wiring one can assume, in case of fire in the building, that the fire will firstly affect a limited part of the building and the safety lighting in the rest of the building remains still ready for operation.

The complete drop-out of safety lighting in the part of the building affected by the fire is continued to be delayed by the following redundance. If there are more than two emergency lamps in one room or at one escape route E VDE 0108-100 says that they have to be connected to two independent protection devices in an

alternating way. In the “classical” sense this redundancy requires at least 4 lines with functional integrity leading from the battery system to each fire compartment as the emergency sign lamps (in con-tinuous circuit CC) and the emergency lamps (in stand-by switch SS) are in se-parated current circuits (see figure 1) and each second lamp of each type is to be connected to an output current circuit in an alternating way.

It is possible to achieve the same emer-gency through the so called undulating current electrical circuit (see figure 2). Here, the lamps in continuous circuit and in stand-by switch are on one final circuit. Furthermore the lamps must be switched on in an alternating way. If one output current circuit drops out every second emergency and every second emergency sign luminaire stays active.

The dislocation of the circuit modules to switch-over from mains operation to emergency power (battery) into the res-pective fire compartments makes it pos-sible to reduce once again the lines with functional integrity (see figure 3). Depen-ding on design all fire compartments can

Table 2: Example of calculation of the required battery capacity

1) In this example a system is chosen with separate maintained (DS) and non-maintained (BS) final circuits, that is min. 4 final circuits per fire area2) Depending on the battery manufacturer, the appropriate type of battery C10 must be selected3) This reserve is calculated as an option in order to connect some additional lamps later on4) This reserve has to be calculated in order to meet concerns about battery aging


Lamps

10-storey office building final circuitsDS + BS1)

DS BS

Corridors 1 corridor per floor which is identified as escape route 10 × 4 = 40 10 × 4 à 6 W 10 × 6 à 58 W

Stairwells 2 necessary stairwells 2 × 4 = 8 2 × 11 à 6 W 2 × 22 à 58 W

Basement 1 corridor identified as escape route 1 × 4 = 4 1 × 4 à 6 W 1 × 5 à 8 W

Equipment room Main distribution, equipment room 1 × 3 = 3 1 × 1 à 6 W 1 × 2 à 8 W

55 402 W 6088 W

Capacity evalutation

Battery capacity 402 W + 6088 W = 6490 W + 10 % reserve (3

~7150 W

Battery discharge current 7150 W / 216 V ~ 33,1 A

3 h rated operation duration ~ 99,3 Ah

+ 25 % reserve 4 99,3 Ah × 1,25 124,13 Ah2

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Figure 3:Mixed mode operation with external circuit modules RSKM – RUSIC® Universe

Figure 2: Mixed mode operation – RUSIC® Universe

Escape sign lamp in maintained mode DS

Emergency lighting luminaire in non- maintained mode BS

Emergency lighting luminaire in “switchable maintained mode”

Functional integrity line

Circuit modul SKM

Small distribution RAK in functional integrity with output fuse

Figure 1: separate DS + BS circuits RUSIC® Base + Control*) ESK only with Control necessary

RESKRSKM RÜBRAK-1

*) RESK necessary for RUSIC® Control only


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


be supplied by one E30 line. A mixture of dislocated and not dislocated final circuit modules is not possible. An advantage of the dislocated final circuits is the small number of lines and cable trays with func-tional integrity.

3.11 Final circuits – number of lumi-naires Max. 20 luminaires can be connected per final circuit. Another limitation of the number of luminaires per final circuit is the dimensioning of the overcurrent protection device that protects the final circuit. A final circuit may only be loaded to 60% of the rated current of the protec-tion device (DIN V VDE V 0108-100). The previous limitation of the rated current of the protection device of the final circuit to 10 A does not exist any more.

3.12 Installation of system and batteryFor emergency lighting systems and bat-teries EltBauVo stipulates that there have to be suitable electrical service rooms and corresponding battery rooms. This means that provisions have to be taken concer-ning fire protection and further construc-tional conditions – examples see figure 4. Depending on the capacity and the type of battery the “battery rooms” should be ventilated sufficiently. Dimensioning acc. to DIN EN 50272-2. Prefer natural ventila-tion to mechanical.

Calculation of air volume flow QQ = 0,05 × n × Igas × Cn × 10-3

With – Q: air volume flow in m3/h – n: number of cells – CN: rated capacity in Ah – Igas: current that causes the gas deve-lopment in mA per Ah

– Igas = 8 mA/Ah for sealed lead acid bat-tery (OGIV)

– Igas = 20 mA/Ah for closed lead acid battery (OGIV)

– Igas = 50 mA/Ah for closed NiCd batte-ries

Note: In contrast to OGIV batteries OPZS batteries have a 2,5 bigger volume flow and NiCd batteries a 6,25 bigger volume flow.

Evaluation of opening cross section A of supply air and exhaust airA = 28 × Q With – A = opening cross section in cm²

Sample calculation:Sealed lead acid battery OGIV type C10 with 85 Ah battery capacity, power loadQ = 0,05 m3/h × 108 × 8 mA/Ah × 85 Ah × 0,001 = 3,67 m3/hA = 28 × 3,67 = 103 cm2

Rate

d ca

paci

ty t

ype

OG

IV/1

0

Num

ber o

f blo

cks

with

12

V an

d Ah

Calc

ulat

ed a

ir vo

lum

e flo

w

Nec

essa

ry o

peni

ng c

ross

se

ctio

n su

pply

and

exh

aust

air

CN in Ah

Q in m³/h

A in cm²

15 18 OGIV 12-17 0,65 18,2

20 18 OGIV 12-24 0,86 24,2

25 18 OGIV 12-28 1,08 30,2

30 18 OGIV 12-33 1,29 36,1

40 18 OGIV 12-45 1,73 48,4

50 18 OGIV 12-55 2,16 60,5

55 18 OGIV 12-60 2,37 66,4

70 18 OGIV 12-75 3,02 84,6

75 18 OGIV 12-80 3,24 90,7

85 18 OGIV 12-90 3,67 102,8

95 18 OGIV 12-100 4,10 114,8

115 18 OGIV 12-120 4,97 139,2

130 18 OGIV 12-134 5,62 157,4

145 18 OGIV 12-150 6,26 175,3

195 18 OGIV 12-200 8,42 235,8Table 3:Comparison of rated capacity, typical OGIV battery type C10 and necessary supply and exhaust air opening


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


3.13 Functional integrityIn order to ensure the function of the sa-fety lighting in case of fire the sample line systems directive MLAR (11/2005) gives guidelines for the placing of the distri-bution resp. of their housings and for the design of the circuit system.

Depending on the location of the electri-cal service room of the system and of the location of the sub-distributions of the safety lighting in the fire areas, functional integrity of E30 is required for the housing of the distributions and the corresponding supply lines.

Functional integrity of the distribution and the circuit system is not needed if the

emergency lighting system resp. a distri-bution of the emergency lighting system serves only to supply one fire area and if the system resp. the distribution is in this fire area.

If fire areas are bigger than 1600 m² MLAR allows to split them into “virtual fire areas”.

3.14 Control and bus systemsControl and bus systems for safety ligh-ting shall be independent of the control and bus systems for the general lighting. Coupling of both systems is permitted only with interfaces that ensure a de-coupling/isolation of both busses from each other. A failure in the control and

bus system of the general lighting leads to a breakdown of the general lighting on a room or an escape route, this control must be monitored. In case of a fault the security lighting in the operation mode “stand-by mode” must be switched on [E DIN VDE 0108-100].

Figure 4: Electrical service room(design acc. to EltbauVo)

1) Door in T302) Walls and ceilings in F90, if in adjacent rooms there is an increased fire danger (EltBauVo §7)3) Ventilation system if possible at opposite walls for better ventilation – if not possible, distance of at least 2 m4) Undisguised escape route width > 0,6 m5) Lines to and through fire compartments with functional integrity E30RUSIC® Central Power SystemHVSV Main distributor emergency power supply – HVSV and battery can also be in a combined cabinetHVAV Main distributor general power supply


Battery

Battery

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


3.15 Inspection

3.15.1 Inspection systemLuminaires of safety lighting according to DIN EN 60598-2-22 shall be monitored and tested manually or automatically. Au-tomatic test systems (ATS) must comply to DIN EN 62034. Depending on system type, single battery lamps or centrally supplied lamps, different tests in different intervals must be done. These checks, depending on type of plant layout, can be made and re-corded automatically by the test system (acc. to DIN EN 62034) or manually.

DIN EN 62034 separates these test sys-tems into four groups:

– Type S: Automatic test system in the lamp with display at the lamp - local inspection of lamp for manual recor-ding of test results necessary.

– Type P: Supervision and display of test results of several lamps at central test system – manual recording of test re-sults necessary.

– Type ER: As type P and additonal au-tomatic recording of test results of connected lamps.

– Type PRN: As type P or ER but with collective fault display that gives auto-matically a remote display with infor-mation about the failure of one of the checked lamps.

3.15.2 Log bookTests and maintenance are to be noted in a log book or with a print out of the auto-matic test system. DIN V VDE V 0108-100 stipulates that the log book must be kept by a “designated responsible person”.

At least the following must be noted:a. date of commissioning including do-

cumentation of subsequent changesb. date of regular testsc. d ate and short description resp. notes

of the maintenance and tests done d. date and short description of each

fault and every maintenancee. date short description of each

change within the emergency ligh-ting system

f. if an automatic test system is used documentation of functions and process

3.15.3 Inspection procedure – dead-linesThe tests described here have been taken from E DIN VDE 0108-100. Possible gui-delines of national authorities must be respected in parallel. If tests are made that reduce the battery capacity , e.g. the rated operation duration test, one has to make sure that these tests are only done in time of “low risk”. If this is not possible “appropriate measure for this period must be taken until the batteries are recharged.”

3.15.3.1 Initial inspectionThe initial inspection comprises the ligh-ting verification of given values of safety lighting. The measurements shall be done as described in DIN 5035-6.

3.15.3.2 Periodic inspections – Daily: Check display for correct func-tioning. Visual inspection if system ready-to-operate – no functional test

– Weekly: Function of safety lighting: at least once per week. “Connection of the power source for safety pur-poses is needed if it is a battery-buf-fered system. Thereby the function of the luminaires for the safety lighting including those for escape sign lumi-naires must be checked.”

– Monthly: Functional test without ra-ted operation duration, that is “Swit-ching of each luminaire to emergency operation through simulation of a breakdown of the general supply for a duration that is sufficiently long to ensure that every lamp is on” – the switching back to the general pow-er supply of all luminaires must be checked.

– Yearly: Functional test combined with rated operation duration test, that is switching of each luminaire to emergency operation through simu-lation of a breakdown of the general power supply for the full operation duration given by manufacturer.

– Attention: release this test manually – it must not be released automatically. It has to be respected that this test of the rated operation duration test is done during periods of “low risk”. If this is not possible “appropriate measure must be taken for this peri-od until the batteries are recharged.”

The switching back to the general po-wer supply of all luminaires must be checked. Check function of charging device. Also check if all lamps are clean.

– Every 3 years: Measuring the illumi-nance acc. to DIN 5035-6.


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


RUSIC® central emergency lighting systemTechnical information

RUSIC® central emergency lighting sys-tems are built to the relevant standards and guidelines. They are a response to the increased public safety conscious-ness. RUSIC® Systems offer variable central power supply solutions in cor-respondance to the current national building regulations, the Directive for Line Systems (MLAR) and EN 50171 (Central power supply systems), DIN EN 50172 ( Emergency Escape lighting systems - DIN VDE 0108-100). RUSIC® emergency lighting systems allow to realize solutions that are tailored espe-cially to the respective building appli-cations. These solutions ensure a simple installation, a safe operation and a re-duction of the fire load as a first prior-ity. RUSIC® central emergency lighting systems provide with the mixed mode operation of final circuits technology and with the internal and external de-vices solutions that fulfil exactly these requirements and expectations.

RUSIC® central emergency lighting sys-tems are acc. to DIN EN 50172 and DIN V VDE V 0108-100 for all building ap-plications. Battery and charging tech-nology, processing unit and monitoring modules are the basis of RUSIC® emer-gency lighting system.

Independent satellite stations can be flexibly installed as needed. These

stations with external circuits modules react individually to mains power fail-ure without influencing others.

In order to meet the technical require-ments, the satellite stations are indi-vidually electrically protected and are available if required with E30 func-tional integrity. This saves costs and increases safety.

4.1 Benefits of the RUSIC® central emergency lighting systemDepending on priority of the specific planning parameters of emergency lighting system RUSIC® can manage to realize project-specific planned safety lighting (see table 4).

From the simple system RUSIC® Base without monitoring for replacing old existing systems there are a lot of other solutions. Systems with special voltage (RUSIC® Base xV) for example or with electrical circuit monitoring (RUSIC® Control), upto all-integrating system RUSIC® Universe with mixed mode operation technology, internal and external circuits and individual lamp monitoring.

n RUSIC® Universe Mixed mode operation technology

with individual lamp monitoring with directly outgoing and external circuits for reduction of E30 lines

n RUSIC® Base EL DS and BS* separated with directly

outgoing and external circuits and with individual lamp monitoring

n RUSIC® Control DS and BS separated with directly

outgoing and external circuits and with electrical circuit monitoring

n RUSIC® Base DS and BS separated without

monitoringn RUSIC® Base xV DS and BS separated, without

monitoring with special voltage (24 V, 48 V, 60 V, 110 V)

All solutions with monitoring function – electrical circuit or individual lamp monitoring – can be established with circuits coming directly from the cen-tral station (with internally mounted electrical circuit cards RESK) or with

external circuits (with electrical circuits RSKM modules externally grouped in sub-distributions).

This means:

n Easy configuration of the equip-ment concept and the line concept for supply of the fire area

n Combination of ‘internal’ and ‘ex-ternal’ final circuits with separate circuit modules and/or power cir-cuit distributions

n Mixed mode technology: escape sign luminaires in maintained and emergency lighting luminaires in non-maintained mode in one final circuit – mode (maintained/non-maintained mode can be assigned centrally at the system

n The connection of the final circuits directly in the system’s cabinet can be easily and comfortably done as the Ruhstrat cabinet size is desig-ned generously

n Display and evaluation of all mes-sages at a central point directly shown on LCD display or via R-Port and own IP address connection to every network (LAN)

n CPU with backlit four line text dis-play for good readability combined with a clearly arranged control panel

n 19’’ rack system for easy assembly and disassembly of system slots

n Compact type of construction of equipment

n Monitoring and control systems independent from each other and coordinated by stable RS485 bus

n Availability of components and electronic ballasts with energy sa-ving power reduction during bat-tery operation and implemented address decoder

n Sub-stations completely available in F30

n Simple to install and easy to maintain

* DS: Maintained mode

BS: non-maintained mode

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es

13


phot

ocas

e: e

lke

4.2 MonitoringAcc. to DIN VDE 0108-100 the opera-tor of emergency lighting systems is obliged to check the functions of a central battery system as well as the connected luminaires perodically as stipulated and to make corresponding reports in the so-called log book. Au-tomatic test equipment helps to reduce these staff costs and this expenditure of time. RUSIC® central emergency light-ing systems permit an enormous reduc-tion of these efforts and costs through an automatic system, line, battery and lamp monitoring. System bound EVGs with corresponding monitoring and ad-dress devices or separate monitoring components in the luminaires are used for the individual luminaire monitoring.

Up to 128 electrical circuits with up to 2560 luminaires can be steadily moni-tored and administrated by one sys-tem. For these monitoring functions no additonal data lines to the lamps are necessary. The complete monitoring is done via the existing supply lines to the fire areas and luminaires – if external circuit modules RSKM and digital in-puts RDN-EA in the fire areas are used, they are connected via RS485 bus to the RUSIC® central emergency lighting system – length of BUS up to 1000 m, type of line LIYCY min. 4 × 2× 0,5, CAT 5 recommended – components in se-quence with RUE as 1st component.

Status information of the RUSIC® emergency lighting system are saved automatically and recorded for the inspection log book (up to 65,000 en-tries). They are immediately available for the user over years.

By using LED luminaires of series R-Led it is ensured that “real” LED monitor-ing is implemented – by measuring of

current and flux-voltage. By using this method the detection of faulty LED, which are still consuming current but are not shining anymore, is safe.

4.3 System ConfigurationRUSIC® emergency lighting systems meet all requirements of VDE 0108, EN 50171 and EN 50171 as well as ÖVE/Önorm E8002.

The following components are integral part of the system:

n USB interfacen Mains power monitoring and insu-

lation monitoringn Power supply unit for internal sys-

tem voltage and for external sig-nalling device

n Main switch for switching off the consumer circuits

n Push-button for simulation of mains breakdown

n IU-charging device acc. to DIN EN 50272-2 for sealed, maintenance-free and also open battery systems Pb and NiCd. Automatic Switching from power charging to trickle charging

n Control contact for battery room fan and control loop for phase monitor

n Digital group of components IO-Interface with 8 digital inputs for potentialfree contacts and 8 relays with changer output. Three of these relays are initialized as DIN signal-ling relay. The inputs can be used for e.g. mains monitor function

n Possibility to connect an optional alarm unit for remote indication of system status acc. to. VDE 0108

n SD card reader

RUSIC® emergency lighting systems are built in modular technique into a pre-mium steel sheet enclosure. The steel sheet enclosure is powder-coated and coloured in RAL 7035 as standard.

n Type of protection IP21n Floor or wall cabinet and suitable

battery enclosuren Natural ventilation

Please find detailed information for the enclosures and battery enclosures on pages 21 to 23.

Accessories (optional):

n External signalling device RMTBn Built-in printer RPDn 230 V inputs and free usable relay

outputs including mains monitor function RDN-EA

n Stairs light automat RTLAn Power circuit module RSKMn Power circuit card RESKn Address and monitoring module

RÜBn Power circuit distributor RSKVn E30 small distributor RAKn E30 sub-distribution RBUVn Battery symmetry controln R-Port for connecting RUSIC®

emergency lighting system to LAN network


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


4.4 RUSIC® central emergency lighting systems - types

Table 4: Types of RUSIC® central emergency lighting system1) 4 line system – min. 2 maintained (DS) each and 2 non-maintained (BS) circuits per fire area

2) Maintained mode (DS), non-maintained mode (BS) and switchable maintained mode (gDS) in one power circuit – that is, min. 2 circuits per fire area are

sufficient

3) Free combination of internal (directly from system coming power circuits) and external circuits (via a main line supplied fire external circuit modules in the

fire area resp. in the fire protected sub-distribution RBUV)

4) Combination of circuit monitoring (EK) and individual luminaire monitoring (EL) in one RUSIC® security lighting system is possible

5) Designate selected voltage

System Function Components

RUSIC® Voltage DS + BS separated 1)

Mixed mode operation

Monitoring Internal circuits 3)

External circuits 3)

RUE central unit

RESK external circuit card (4 × 5 A)

RSKM external circuit module (4 × 5 A)

RÜB address and mo-nitoring device

RDN-EA phase monitor and switching inputs

EK circuit monito-ring4)

EL individual luminaire monito-ring4)

Base 216 V X X (X)

Base xV 5) 24 V/48 V60 V/110 V

X X (X)

Base EL 216 V X X X X X X X

Control 216 V X X X X X X X X

Universe 216 V X X X X X X X X X

RÜB

RUE

RUE

RUE

RESK

RESK

Figure 5: RUSIC® Base/Base xV

Figure 6:RUSIC® Base EL

Figure 7: RUSIC® Control

RSKM


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


RAK-1

RSKM

RDN-EA

RÜB

RESK

RUE

Escape sign luminaire in maintained mode

Emergency luminaire in non-maintainded mode

Emergency luminaire in switchable maintained mode

E 30 functional integrity

RS 485 bus – 4 × 2 × 0,5, CAT 5 recommended

Control line LSSA or monitoring UVALSSA: Light switch position query

ME-US: tenant feed-in – change-over relayME-US

Figure 8: RUSIC® Universe

RUSIC® central emergency lighting systemLine systems

Basement / Technology < 1600 m2

Underground parking / Warehouse < 1600 m2

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


The RUE central processing unit con-tains all display and control elements.

The control panel of the RUE allows the easy change of system configuration by using the display and the menu but-tons. Technical parameters of the sys-tem and error messages, actions and statistics are shown in plain text on the illuminated 4-line LCD display. n Data transfer Two interfaces are standard. Com-

mercially available printers can be externally connected to the parallel port for direct print out of error mes-sages, etc.. Connection of a PC to the serial USB port allows to configurate the system or to read-out data. This can also be done via the SD card slot.

n RS485 busCommunication between system and separate components via stable RS485 bus- length of RS485 bus line up to

1,000 m- type of line LIYCY (TP) 4×2×0.5,

CAT 5 recommended in sequence with RUE as first component

n 3-phase (HV) mains power monitoring The system is designed for single-

phase and three-phase mains supply. In the case of voltage drop or break-down, the RUSIC® central emergency lighting system changes the supply of the connected luminaire to battery supply.

n ISO monitor The insulation monitor signals errors

between battery potential and PE. With the ISO-test (+) and (-) buttons the insulation monitoring of the bat-tery circuit can be run.

5.2 R-Port

Connection of the RUSIC® emergency lighting system via own IP address to any LAN network. Status display and remote release of single function and system tests with corresponding feed-back signal.

Order reference: R-Port

5.1 Central unit RUE

The built-in printer can be installed in the 19” rack or connected externally. The printer gives test results, messages and system status sorted by date and log number.

Order reference: RPD

5.4 Built-in printer RPD

Status of the central battery system can be displayed on the external sig-nalling device where also switching on and off is possible.

Display:n General fault indicatorn ON/OFFn Ready for operationn Battery operationn Mains power operation

Dimensions (w × h × d) in mm: 166 × 161 × 71

Order reference: RMTB

5.5 External signalling device RMTB

RUSIC® central emergency lighting systems can manage up to 128 final circuits, that is 32 final circuit cards ESK8 in 19’’ technology. A combination of the external circuit modules RSKM is possible. Each circuit card supplies 4 with 5 A fused freely programmable fi-nal circuits for mixed mode operation - maintained mode (DS), non-maintained mode (BS) and switchable maintained mode (gDS) in one final circuit. Digital inputs used for signalling switching or phase failure can be allo-cated to each final circuit or luminaire separately. For monitoring and switch-ing of luminaires the address device RÜB is needed in the luminaires.

Order reference: RESK

5.3 Internal circuit card RESK

RUSIC® central emergency lighting systemComponents

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


5.6 External circuit module RSKM

RUSIC® central emergency lighting systems can manage up to 128 final circuits mixed mode operation - main-tained mode (DS), non-maintained mode (BS) and switchable maintained mode (gDS) in one final circuit. This means up to 32 circuit modules RSKM with 4 final circuits each, fused with 5 A each, can be relocated to single fire areas. Depending on functional integri-ty needs they are to be placed either in “simple” power circuit distributions (type RSKV) or in fire protection

distribution (type RBUV). A combina-tion of internal power circuit cards RESK and external circuit modules RSKM is possible.

Digital inputs used for signalling switching or phase failure can be allo-cated to each final circuit or luminaire separately. For monitoring and switch-ing of luminaires the address device RÜB is needed in the luminaires. Com-munication with the RUSIC® system via RS 485 bus line.

Dimensions (w × h × d) in mm:157 × 86 × 58

Order reference: RSKM

5.7 Monitoring device RÜB for indivi-dual luminaire monitoring

The monitoring device RÜB manages a) Addressing of the lamps – per

circuit the address 1 to 20 can be assigned

b) Lamp monitoring per current indication

c) Software bound assignation of lamp function (maintained or non-main-tained mode)

d) Furthermore, the function “swit-chable maintained mode” can be realized through direct switch con-nection if not done by the software handled allocation of a specific digital input (switch connection contacts are not shown on photo)

Figure 9:Combination of switched luminaires of general lighting directly with the emergency lighting system by means of the direct switch connec-tion of the monitoring device RÜB.RUSIC® power supply

Picture 9:general lighting network

Adresses: 1 to 20

Rated voltage: 230 V AC / 183 V-253 V DC

Max. load current:0,6 A (maximal 130 W)


Connections:4 × 0,75 mm², approx. 30 cm connecting length

Order reference: RÜB

RUSIC® central emergency lighting systemLine systems

Error

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Module RDN-EA has 7 digital inputs for 230 V and 3 freely usable relays with change-over contact. May be used in-ternally or in sub-distributions to sig-nalling switching status, e.g. of a light switch, monitoring mains supply and for signal forwarding to display and log book.

RDN-EA is suitable for snapping on to DIN rail and for insertion into all common industrial and installation distributions Communication with the RUSIC® system via RS 485 bus line.


Order reference: RDN-EA

5.8 Digital input and phase monitor RDN-EA

Figure 8:Example of installation with RSKM used for external circuits and RDN-EA for monitoring of 3-phase mains supply and for switching of luminaires via central programming with RUSIC® system.


RS 485 BusStromversorgung

allgemeines Netz allgemeines Netz

1) Lichtschalter über Bus zur Zentrale

2) Lichtschalter direkt vor Ort an RÜB

common grid

Power supply

1) Light switch via Bus to CPS

2) Light switch directly on site via RÜB

common grid

Error

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


The stairs light module RTLA serves as realization of the “stairs light function” of emergency lights of a RUSIC® emer-gency lighting system. The luminaires of a final circuit connected to RTLA stairs light module are switched off after a certain time preselected at the RUSIC® emergency lighting system. Via the connected press-button the lumi-naires can be re-activated every time for the foreseen time. A RUSIC® emer-gency lighting system can handle up to 10 RTLA. Pre-selectable time between 1 min to 39 min (steps of 10 s).

5.9 RTLA Stairs light module

Wall mounted small distribution E30 for looping through of the E30 line from central battery system and junction to the separate power circuit distribution resp. fire area with RSKM modules. The wall-mounted small distribution RAK complies to MLAR. It has cable entries on each side and optionally the neces-sary output fuse.

Dimensions (l × w × h) in mm: RAK 0.1 for Ø 6 mm2: 125 × 125 × 60RAK 0.2 for Ø 10 mm2: 170 × 145 × 70RAK 0.3 for Ø 16 mm2: 243 × 168 × 83

Colour: RAL 2003Type of protection: IP65Functional integrity: 30 min. - tested by MPA Stuttgart

Order reference: RAK 0.1, RAK 0.2, RAK 0.3

Dimensions (l × w × h) in mm: 200 × 200 × 90

Colour: RAL 3000Type of protection: IP 54Functional integrity: 30 min. - tested by MPA Stuttgart

Order reference: RAK-1

5.11 Small distribution with functio-nal integrity E 30 type RAK

5.10 Phase monitor RPW-N and RPW-S

Phase monitor for installation in the sub-distribution of the general lighting. For snapping on to DIN rail, fitting the cut-outs of all common industrial and installation distributions. Design acc. to IEC/EN 60255, DIN VDE 0435-303 and VDE 0108. For the detection of phase failure in alternating current networks 400/230 V 50 Hz.

Change-over point at 0,85 x U rated, phase sequency user-defined, phase se-quency type. Wide design RPW-N with two change-over contacts (width 36 mm). Slim design type RPW-S with one change-over contact (width 17,5 mm).

Order reference: RPW-N bzw. RPW-S

RPW-N RPW-S

RAK 0.1/0.2/0.3without fuse

RAK-1with fuse

Note:RTLA can be used acc. to DIN VDE 0108-100 for re-duced rated opera-tion duration of 3 h instead of 8 h in hotels/guest hous-es, residential care homes and high-rise buildings.


Order reference: RTLA


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Intended for the installation of Ruhstrat external circuit modules RSKM or final circuits with neozed fuse protection.

Fire resistant plates acc. to DIN 4102 and cable penetration seal acc. to DIN 4102 Part 9 with integrated ventilation system, wall mounting kit, door hinged on the right with covered steel hinges, opening using operation lever.

Colour: RAL 7035Type of protection: IP 54Protection class: IIFunctional integrity: 30 min. - tested by MPA Stuttgart

1) MS: modular spacing

Intended for installation in the respective fire areas.

Design optionally as on-wall or in-wall distributor with face door.

The feed-in is done by a three-wire line from the on-wall distributor E 30 type RAK.

* Illustration without built-in components and without face door

1) MS: modular spacing

5.12 Sub-distribution with functional integrity E 30 type RBUV

5.13 Distribution type SKV*

Fire resistant sub-distribution are available for following sizes:

Order reference Dimensions in mm Optional equipment Max. number of final circuits

RBUV-LW3.1-30S 600 × 400 × 241(3 lines à 12 MS1)

for max. 2 modules RSKM + 1 RDN-EA

8



12



16



20



24



32



40

Note: If tenant feed-in is required (ME-US: mains supply and switch-over at site) the next bigger distributor has to be chosen

Power circuits distributor RSKV are available with following designs:

Order reference Dimensions in mm Optional equipment Max. number of final circuits

RRSKV-24-AP 370 × 305 × 96,5(2 lines à 12 MS1)


4



8



12

RRSKV-24-UP 442 × 330 × 90(2 lines à 12 MS1)


4



8



12

Note: If tenant feed-in is required (ME-US: mains supply and switch-over at site) the next bigger distribu-

tor has to be chosen


Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


6 Switch cabinet system SG n Steel sheet cabinet with parts sec-

tioned off from each other for output fuses, load/switch element and bat-tery compartment

n Standard colour RAL 7035; other colours on enquiry

n door hinge left or right, as desired n cable insertion from the topn cable guarding rail standardn base (80 mm) optionally

BG 6 / 6 - 45 BG 9 / 6 - 45 BG 18 / 8 - 55

Gehäusetiefe 465 Gehäusetiefe 465 Gehäusetiefe 565

SG 12 / 6 - 45 SG 18 / 6 - 45 SG 18 / 8 - 55

Gehäusetiefe 565

BG 9 / 8 - 55

SG 12 / 8 - 55

262

262

1800

331

331

331

331

331

1800

825

900

267

267

267

1200

600

1800

600 600 600

1200

825 825

1650

1200

900

2100

All switching and battery cabinets are also available with a base (height 80 mm).

*Battery cabinet system BG see page 25

* * * *

Recommendation for cabinet assignment with respect to number of circuits, i.e. the max number of circuits per cabinet. If more circuits are required another cabinet will become necessary.

1) 2-pole (ceramic) fused circuits (10 A) 2) Circuit card RESK

Cabinet type Heigth [mm] Width [mm] Depth [mm]

SG 12/6 - 45 1200 600 465 SG 18/6 - 45 1800 600 465 SG 12/8 - 55 1200 825 565 SG 18/8 - 55 1800 825 565

Cabinet type RUSIC Base 1) RUSIC Control/Universe 2)

SG 12/6 - 45 40 circuits 24 circuits




RUSIC® central emergency lighting systemSwitch cabinet system SG

Housing depth 465 Housing depth 465 Housing depth 565 Housing depth 565

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Batteries

Lead acid batteriesfor emergency lighting systems with central battery. Rated voltage per cell 2,0 V. According to VDE 0108 for emergency lighting systems with central batteries as lead acid batteries, those with positive large area plates and positive armour plates or grid plates must be used. Vehicle starter batteries are not permitted. Exceptions are only allowed in special cases according to VDE 0108.

NiCd batteriesfor emergency lighting systems with central battery. Rated voltage per cell 1,2 V. According to DIN EN 50272-2 there are no limiting regulations with respect to design and electrode design.

Closed batteries (OPZS /OGI)for emergency lighting systems. These batteries must be maintained regu-larly; among other things this means

checking the electrolyte level and re-filling with distilled water as needed. As gassing occurs during the charging of these batteries, the batteries must be installed with ventilation of the installation area taking into account of EN 50272-2.

Sealed batteries (OGIV)according to VDE 0108, these batteries must be designed so that refilling with liquids is ruled out, they are suitable for trickle charging and that no electrolyte escapes in the case of proper opera-tion irrespective of the usage position. These battery systems are designated as maintenance-free by the manufacturer.

Note:The temperature at the installation lo-cations must be taken into account. If batteries are used which can produce gas during proper operation, a safe gas outlet must be provided.

Basically, two types of batteries are used:

n gastight nickel cadmium batteries with sintered design and preferably cylindrical design in lampsn sealed lead acid batteries preferably with prismatic design with the specified electrolyte in central systems

NiCd batteries for central systems do in fact have longer service lifes but are also significantly more expensive to purchase and for the later disposal. For this reason, Ruhstrat recommends sealed lead acid batteries. The specified expected service life of ten years is op-timised using temperature compensat-ed charging adjustment. Temperature fluctuations at the battery location are compensated. The sealed battery systems also show the benefit of less complex ventilation.

Gehäusetiefe 465

KG 18 / 6 - 45

Gehäusetiefe 565

Bat

terie

Bat

terie

KG 18 / 8 - 55

1800

600

1800

825

All switching and battery cases are also available with a base (height 80 mm).

Combi cabinet Height [mm] Width [mm] Depth [mm]

KG 18/6 - 45 1800 600 465 KG 18/8 - 55 1800 825 565

n Steel sheet cabinet with parts sectioned off from each other for output fuses, load/switch element and battery compartment

n Standard colour RAL 7035; special painting possiblen Door hinge left or right, as desiredn Cable inlet from the topn Cable guarding rail as standardn Base (80 mm height) optionally

Combi cabinet KG

Housing depth 565Housing depth 465

Batt

ery

Batt

ery

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


Table 5: Allocation of RUX-batteries in Battery cabinet system BG

* Battery capacity = connected load + 25 % energy reserve

nVery robust cabinet designnStandard RAL colour 7035, supply in other colours possiblenDelivery and installation in very short timenGrid floornBase (80 mm) optionallynBattery frames acc. to customer’s requirements and acid tank optionally

max. battery switch area

Battery cabinet Height Width Depth Number Height Width Depth [mm] [mm] [mm] Levels [mm] [mm] [mm]

BG 6/6 -45 600 600 465 2 245 595 390 BG 9/6 -45 900 600 465 3 243 595 390 BG 18/6 -45 1800 600 465 5 302 595 390 BG 6/8 -55 600 825 565 2 245 820 490 BG 9/8 -55 900 825 565 3 243 820 490 BG 18/8 -55 1800 825 565 5 302 820 490 BG 18/8 -65 1800 825 665 3 543 820 590

Battery cabinet Battery type OGIV Connected load for 1 h incl. 25 % reserve

Connected load for 3 h incl. 25 % reserve

BG 6/6 -45 BATTERY RUX 1217 2.3 KW 0.9 KW

(KG 18/6 - 45) BATTERY RUX 1228 3.6 KW 1.5 KW

BATTERY RUX 1233 4.3 KW 1.8 KW







(KG 18/8 - 55) BATTERY RUX 1224 3.0 KW 1.3 KW








BATTERY RUX 1280 LS 11.6 KW 4.6 KW





2 × BG 18/8 -552 × BG 18/8 -65



Battery cabinet system BGBattery cabinets for emergency lighting,

UPS and BSV/ZSV systems

Saf

ety

light

ing

· Sup

ply

syst

ems

for s

afet

y se

rvic

es


RSV Ruhstrat Stromversorgungen GmbHHeinestr.12 37120 Bovenden Germany

phone: +49-55 93-9 37 22-0 fax: +49-55 93-9 37 22-222

e-mail: [email protected] web: www.ruhstrat.eu

Technical details subject to change. All information provided is subject to change without notice.

As of 09/2013

Safety Lighting / Emergency Power Supply

Power Supply

Battery-supported Central Power Supply Systems

Connection Technology

Documents

Safety Lighting according to DIN EN 50171 Central ... · Safety lighting · Supply systems for safety services RSV Ruhstrat Stromversorgungen GmbH · Heinestraße 12 · D-37120 Bovenden