RX IG - Assa Abloy

Installation guide EN ASSA RX9101

Content 1 IG5591012931B

Content Introduction ____________________________________________________ 1

Terminology____________________________________________________ 2

Function RX9101 ________________________________________________ 3 Casing ____________________________________________________________ 4

ADD-ON board RX9101 ___________________________________________ 5 9101D3 for connection of several doors via DAC _______________________ 5 9101D3A for connection of Aperio doors ______________________________ 5 9101R4850 for connection of Aperio doors ____________________________ 5

Technical specification & power consumption _______________________ 6 RX9101 Control unit _________________________________________________ 6

Specification RX9101 ______________________________________________ 6 DAC ______________________________________________________________ 8 Readers ___________________________________________________________ 9

DAC _________________________________________________________ 10 Terminal block DAC ________________________________________________ 11 Jumper links DAC __________________________________________________ 13 Terminal block Relay board DAC400RC64 ______________________________ 14 Indication on DAC _________________________________________________ 15

Readers ______________________________________________________ 16 Indications _____________________________________________________ 16

Assembly_________________________________________________________ 17 Mounting reader _________________________________________________ 18 Doors __________________________________________________________ 19 Cables, dimensions for cables _____________________________________ 20

Peripheral Equipment ___________________________________________ 22 RX9101 __________________________________________________________ 22 Peripheral Equipment DAC __________________________________________ 24 Peripheral Equipment Readers _______________________________________ 24 Hi-O components to the DAC500 family ________________________________ 25

Master reset, initiation and addressing ____________________________ 26 Master reset and running mode for RX9101_____________________________ 26

Restoring the password ___________________________________________ 26 Initiation and addressing of DAC420/430, PCR, DBL _____________________ 27 Initiation and addressing of DAC500/DAC530 ___________________________ 28 Initiation matrix DAC500, DAC530, DAC564 _____________________________ 31

Addressing Hi-O units ____________________________________________ 31 Installation of Hi-O Components ______________________________________ 32

ASSA RX9101 Installation guide EN

Content 2

Addressing CL reader ______________________________________________ 33

Checklist at start up ____________________________________________ 34 At the door _______________________________________________________ 34

Troubleshooting _______________________________________________ 35 DAC _____________________________________________________________ 35 RX9101 __________________________________________________________ 35 Readers __________________________________________________________ 36

Description of RX9101 __________________________________________ 37 RX9101 connections _____________________________________________ 37 Terminal blocks _________________________________________________ 37

Location of LED indications on the main board _________________________ 38 LEDs on the CPU board ___________________________________________ 39 Jumper link fields RX9101 _________________________________________ 40

DIP settings RX9101 main board ______________________________________ 41 DIP1 Telnet _____________________________________________________ 41 DIP2 Resets password and user ____________________________________ 41 DIP3 Balanced door monitor switch _________________________________ 41 DIP4 Fixed IP 192.168.1.250 ________________________________________ 41 DIP5 https:// or http:// _____________________________________________ 41 DIP6 Master reset and a reset of the password ________________________ 41 Master reset ____________________________________________________ 41 Balanced Door monitor switch _____________________________________ 42

Installation hardware ___________________________________________ 43 Connection of reader to RX9101 ____________________________________ 43 Electric strike with door leaf monitoring and exit button ________________ 44 RX9101 with ADD-ON board 9101D3 and DAC ________________________ 45 Directly connected DBL34, DBL340, DBL342 to RX9101 ________________ 46 VOXIO Reader (9101R4850) or (9101D3 with 9101D3A) _________________ 47 Aperio ComHub (9101D3 with 9101D3A) _____________________________ 48 Connection Aperio 1-8 HUB _______________________________________ 49 Termination of Aperio HUB RS485 buss _____________________________ 50 Terminal block description and connections on the 9101D3 board _______ 52 Trouble shooting guide and indications for Aperio doors _______________ 53 Connection of electric strike, door monitor switch and exit button to DAC _ 54 Connection of exit button and reader to DAC _________________________ 55 Connection of inside and outside reader on the same door _____________ 56 DAC with relay board DAC400RC64 _________________________________ 57 Addressing of Aperio ComHub, DAC and reader ______________________ 59


1

Introduction This guide is aimed to be a support in projecting and installation of the access system ASSA RX9101. This guide is written for project engineers, consultants, installation contractor wireman and others. Readers of this manual should possess a basic knowledge of telecom equipment.

To clarify the terminology we recommend that you read through the chapter Terminology on the next page. You also find the following drawings in the installation guide:

Measure sketches and terminal blocks for each product

Overviews

Wiring Diagrams

See table of contents.

Since we continuously develop and improve all our products, including our installation guides and user guides, we would appreciate feedback concerning this manual and the system itself.

E-mail to [email protected]

ASSA AB

Förmansvägen 11

117 43 Stockholm

Phone: 08-775 16 00

E-mail: [email protected]

We make reservations for mistakes and future alterations in this manual.

mailto:[email protected]

mailto:[email protected]


2

Terminology In the following text door, gate, etc. are called door. The following abbreviations/expressions are used throughout the document:

LCU = RX9101, control unit with possibility for direct connection of one door ABP = Alarm bypass PC = Computer DAC = DAC420, DAC430, DAC500, etc.

Activities

All activities performed by the control unit are made together with the RX program. For more information we refer to the user guide.

The main area of use for an access system is to control and facilitate movements in a pre-defined area or in a building. A certain group of people will have access to all areas, others can have a limited access to certain parts.

It is important to determine users and access levels before starting to program the system.

RX9101 can handle 1 to 4 wire connected doors and 12 wireless Aperio door environments. RX9101 is easily administrated with an easy-to-use web interface.

The system is built around a control unit which directly can handle one wire connected door environment, the doors 2 – 4 through an intelligent DAC, PCR or DBL installed at each door, and 12 wireless Aperio door environments.

PCR and DBL are readers with built-in DAC function, all other reader types are connected to a DAC or via a ComHub for wireless door environments. Only DAC and readers with built-in DAC function are to be connected directly to the add-on boards in the control unit.


3

Function RX9101

The default configuration for RX contains a main board, a CPU board with possibility for connection of one door with inside and outside reader, one exit button, one electric lock and one temporary alarm bypass.

The control unit can be fitted with a board for connection of 3 doors further, board 9101D3, these three doors are then connected to the 9101D3 board via DAC, PCR or DBL units.

RX9101 also allows connection of up to 12 Aperio door environments with the door unit E100S or C100S. You do this by adding an Aperio communication board 9101D3A to the 9101D3 board.

You can also select to connect an add-on board that only permits communication to Aperio ComHub units via add-on board 9101R4850. In addition to the basal function of the main board, which always is a wire connected online door, you can connect up to 12 Aperio door environments and the wire connected door to the main board, for example the main entrance.

RX9101 does support the ADD-ON board 400RC64 when you only want to use one door in the control unit. 400RC64 is a board with several programmable relays. When the ADD-ON board 400RC64 is connected you can’t connect more doors to the control unit.

The validity check of code carriers and PIN codes are made in the control unit and validation for each door is sent to the current DAC, PCR, DBL or Aperio door. The control unit is programmed with valid cards and a number of schedules based on a calendar with different day types.

The RX9101 and DAC unit should be placed indoors in a warm and dry area (+5° – +40°).

To guarantee operation at power failure the control unit, with DAC units, should be equipped with its own power supply and battery backup. A suitable power supply is 2450PS or equivalent.


4

Casing The casing is made from polycarbonate and ABS with snap closing and the possibility to secure the lid with screws. The bottom part has 14 plus 4 possible cable inlets.

The casing, with the measurement 156x128x41 mm has room for the primary CPU board and possibility to connect an expansion board for 3 further doors via DAC, PCR or DBL and/or 12 Aperio door environments.

Here you also find a micro processor with memory, real time clock and built-in internal backup. All information for the control of the system is stored here, including data from card and schedule times.

00

06

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The DIP switches

A running system normally has all DIP switches in OFF mode, except DIP3 which determines if the door monitor switch should be double balanced or not.

DIP1 – Telnet ON/OFF DIP2 – ON resets the password. DIP3 – Balanced door monitor contact in ON mode DIP4 – Fixed IP 192.168.1.250 DIP5 – ON = http:, OFF = https: (RX9101) Recommended mode is https: = OFF DIP6 – Master reset and test mode


5

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ADD-ON board RX9101

9101D3 for connection of several doors via DAC

The connections for door 2 – 4 via DAC, PCR or DBL for each door are made on the 9101D3 board. The power supply for the door units (DAC, PCR, DBL) are connected to the board. If Aperio door environments also should be connected the board is supplemented with a 9101D3A communication board.

9101D3A for connection of Aperio doors

The 9101D3 board can be supplemented with a communication board 9101D3A for communication with Aperio doors via ComHub and door unit E100S or C100S. 1 – 12 Aperio ComHub can be connected. The 9101D3A board is placed on 9101D3.

9101R4850 for connection of Aperio doors

The 9101R4850 board is used when you only want to communicate with Aperio door environments. 1 – 12 Aperio ComHub/door environments can be connected to the main board together with the wire connected door.

9101D3 9101D3A 9101R4850

The 9101D3 board has two inputs and two programmable relays via RX.

IN3 is the blocking input and it should be jumper linked in order for the doors to be unblocked.

IN4 is Alarm on or Alarm on/off depending on the selection in RX.


6

Technical specification & power consumption

RX9101 Control unit In the basic configuration the system can handle one door (with inside and outside reader).

See further in the user guide under the heading Configuration.

Memory for cards, schedules, log memory Permanently

Number of cards Recommended Max * Max

1 000 20 000

Number of events 20 000

Number of schedules 15 (x 2 periods)

* The recommended maximum number of cards is the number of cards that can be handled via the browser.

Specification RX9101

Feeding voltage on KP1:14&15 Power supply, external: 17 – 35V AC or 24 – 50V DC

Power supply, internal: 1.8V DC, 3.3V DC and 13.8V DC

Operating temperature to avoid condensing: +5℃ – +40°C

Own consumption RX9101 24V DC Max 100mA

Flash memory 32 Mbyte

RAM memory: 32 Mbyte SDRAM

Operating system Linux

Ethernet 10BASE-T, 100BASE-TX

Configuration port USB B-mini

Relay current limitation 1A (24V)

Total 12V load, in other words 12V electric strike, reader and 12V regulated output

Max 0,7A (700mA)

Own consumption See Table 1


7

The table below shows the power consumption in the control unit at communication with DAC, PCR or DBL (not feeding of DAC, PCR, DBL). D1 – D4 = DAC doors, A5 – A16 = Aperio ComHub doors.

DAC, PCR, DBL D1 D2 D3 D4 A5 A6 A7 A8

24V to RX9101 70 mA

100 mA

120mA

140 mA

167 mA

184 mA

201 mA

218 mA

A9 A10 A11 A12 A13 A14 A15 A16

235 mA

252 mA

269 mA

286 mA

303 mA

320 mA

337 mA

354 mA

Table 1

Calculation example for power consumption in a system.

In Table 1 we find the own consumption for RX9101 when communicating with DAC and ComHub. A ComHub consummates about 15 – 20mA and for the communication to DAC, see D2 – D4 Table 1.

In our example we have two wire connected doors and four Aperio ComHub. The calculation to get the idle power consumption will then be:

RX9101 including DAC 100mA

4 Aperio ComHub (4x20mA) 80mA

Own consumption DAC approx 70mA

Reader from Fel! Hittar inte referenskälla. 200mA

Approx sum 450mA

* When using 24V electric lock DAC and LCU shall be fed with 24V.


8

DAC

24V feeding KP-11:1&2 17 – 24V AC/DC *

Temperature range +5℃ – +40°C

Own consumption DAC, PCR, DBL 24V DC Max 50 – 100mA

Current consumption relay board Approx. 20mA/relay

Relay maximum load 1A

Total 12V current consumption in DAC, in other words, electric strike, reader and 12V regulated output

Max 0,7A (700mA)

Table 2

The table below shows the current consumption for DAC fed with 24V and with 1 or 2 readers connected.

Locked mode

Unlocked mode

Of that illumination in reader

DAC fed with 24V 70mA 100mA

1 Readers 155mA 210mA 15 – 20mA

2 Readers 240mA 290mA 30 – 40mA

Table 3

The table below shows DAC fed with 24V and with connected motor lock.

Operating Slowed down Normal mode/ Standby mode

DAC, PCR, DBL 24V fed and motor lock

Start peak in 0.1 sec.

Other run time

Run for 3 sec., pause 4 sec. for 5 times. Thereafter, run for 1 sec., pause 1 min.

Table 5 multiplied with the number of readers

EL650 550mA 280mA 700mA 190mA

8164 700mA 330mA 750mA 190mA

8087S 1.100mA 330mA 1.200mA 140mA

8000S 450mA 180mA 500mA 140mA

810/811S 400mA 150mA 400mA 140mA

Table 4


9

Readers

Current in 12V (from DAC)

Temperature range -40°C to +85°C

The tables below shows the current consumption for reader connected to DAC.

Normal Max

6485EM connected to DAC fed with 24V 100mA 190mA

Table 5

1 door

1 RX9101, 1-2 6485EM or 6585MF reader 1 TKN1, TKN2 or TKN40 Exit buttons 1 Electric strikes 1 2450PS or network switch with support for PoE PC for administration

4 doors

1 RX9101, including one 9101D3 board 3 DAC, PCR or 1 – 4 DBL 4-8 6485EM or similar (When DAC is used) 4 TKN1, TKN2, TKN40 or TKN50 Exit buttons 4 Electric strikes 3 Hi-O Motor lock via DAC530/DAC564 1 2450PS or more if the system requires so PC for administration

4 doors and 12 Aperio doors

1 RX9101, including one 9101D3 board with a 9101D3A board. 3 DAC, PCR or 1 – 4 DBL 4-8 6485EM or similar (When DAC is used) 4 TKN1, TKN2, TKN40 or TKN50 Exit buttons 4 Electric strikes 3 Hi-O Motor lock via DAC530/DAC564 1-12 Aperio ComHub with accompanying lock module ES100 1 2450PS or more if the system requires so PC for administration


10

DAC DAC is an intelligent unit where all door connections are made, for example readers, electric strike, exit button, door monitor switch, alarm etc. DAC comes in different versions; DAC420, DAC430 and the Hi-O versions DAC500, DAC530, DAC500R64 and DAC564.

The difference between DAC420 and DAC430 is that DAC430 can handle the older serial motor locks. DAC500 series is the latest in the DAC family and it uses Hi-O technology to communicate with the door environment. Hi-O is a technology offering support for plug-and-play and it is described more thoroughly later in this manual.

A DAC can be supplemented with a relay board DAC400RC64 giving access to six relays.


11

Terminal block DAC

Exit button

Unlocked when closed to 0V. The door will lock even if the input remains closed, "flank triggered".

Electric strike (15&16) Coil.

For function and voltage, see jumper link field page 13

ABP (KP-2:17&18) Alarm bypass

NO = Normal mode


12

Balanced Door monitor switch

KP-2:9&10

The door is presumed closed when SW (pin 13) is connected to 0V (pin 14) with DIP switch 6 in position OFF.

DIP switch 6 in position ON = Balanced output on SW (see sketch).

When a direct connected motor lock is connected the input works in parallel with the magnet in the lock.

2,2 k = OK. Resistor of 2.2k will be delivered with DAC, PCR, DBL.

These are the valid values for the input on DAC (13&14)

SAB Rin 1,8k

OK 1,8k Rin 3,3k

ALARM 3,3k Rin 15k

SAB Rin 15k

This function means that you get the whole chain (from loop board via DAC to door) double balanced and the DAC works as a "detector". See picture below.


13

Jumper links DAC Function and voltage for electric strike, pin 15&16.

To the right of the board are the jumper links deciding how the electric strike should operate and the feeding voltage.

Jumper link settings for different functions. Note! To be read from top to bottom.


14

Terminal block Relay board DAC400RC64 Relay board DAC400RC64 are used for DAC420, DAC430, DAC500 and DAC530 but can also be used for RX9101 if no other doors than the basal one is to be used. Relay board DAC400RC64 has six relays.

The option between NO & NC is made with jumper links on relay 3 – 6 on the relay board. The desired functions are set in RX, see further in the user guide.

The following functions are a selection, the rest will be specified in the user guide.

Time-controlled output

Buzzer

Temporary ABP

Automatic door operator

Door position

Tamper

Permanent ABP

Pre-alarm at alarm activation

Free/D-N Day/Night function for motor lock. Jumper linked to 0V = Day.

Works as a free input when motor lock not is connected. All changes generate a log event.

Blocking input The purpose of the input is to prevent access to an alarmed section. When this input is broken DAC, PCR, DBL will be blocked. DAC will not accept exit button or valid code carriers.

The function depends on if it is an alarm interface or if it acts as a slave in an alarm zone.

Slave = Blocks only it self.

Alarm interface = Blocks concerned doors in the zone.


15

Indication on DAC Indications at DAC start up together with control unit, reader and motor lock.

At the upper left of the board there are four LEDs giving the following indications (PWR and WDG have some different behaviours depending on the DAC model, see each DAC manual.

PWR (Power) – Yellow indication shows that there is power and that Hi-O units are found and locked on the Hi-O bus during initiation/master reset.

WDG (OK) – Blue indication, normal flash approx. 2 Hz (2 flash/sec.) Master reset completed – approx. 20 Hz = fast flash (20 flash/sec.) LED lit – Error

TX and RX communication DAC to RX9101

TX (Transmit) – Green indication, flashes when DAC answers to commands from the control unit. If there is no flash the DAC isn't responding, this can be due to wrong address (the same address as another) or that the DAC isn't installed in the program.

RX (Receive) – Red indication, flashes fast at all communication with the control unit.

Flashes slow (irregular) = One or several installed DAC can have a communication problem, caused by for example a cable breakdown.

LED unlit = Communication cables OK, but the control unit do not communicate, or there are no doors installed in the program.


16

Readers ASSA has a vast range of different readers. The readers can be used both indoors and outdoors, IP54. The reader decode the information on the code carrier and sends it (via DAC) to the control unit. Validity check of the code carrier is made in the control unit. Some lack keypad. Others have built-in keypad and clear, back-lit symbols. The 12 non-corrosive push buttons have a distinct “push feeling” and the digits are illuminated.

The readers have a built-in tamper switch that sends an alarm to the software. The readers also has a buzzer that can be set to be activated at the events; door open to long and door forced.

Prox readers

6485EM/6585MF are touch-free readers with a serial interface.

Other readers with serial interface are: 6354M, 6355M, 6480EM, 6485EM, 6481EM and 6585MF. All can be connected to DAC420, DAC430, DAC500 DAC530 and DAC564.

Some of the readers also come in a Hi-O model. 5585MF is a Hi-O reader with Mifare technology and 5485EM is a Hi-O reader reading EM cards.

Mifare readers can read the public serial number or the sector number. The later is preferred since it gives a higher security.

Microwave reader

NMW270 is a touch-free long-range reader, 10 meters, suitable to use at garage driveways and approach gates.

Indications

Yellow arrow/card, red/green alarm status, yellow code symbol, red “man” and green “man”.


17

Assembly It is of the utmost importance that doors, door bolts, locks, hinges, etc. are faultless, otherwise you get a poor function. Door will not unlock, doors will be hanging on the lock bolt and so on. This gives a general bad impression of the premises. No access control system can compensate for a bad door function. In connection with fitting the readers the mechanical function should also be checked and adjusted (if necessary).

Agree ahead with the customer over what steps need to be taken before the installation begins.

The access control system is installed, among other, to provide high security within the company. To reduce the risk for equipment tampering, all cables should be concealed when possible. Concealed wiring is particularly important around doors; it is for example downright inappropriate to install the wiring from the exit button to the DAC unconcealed. If intruders get access to this wire he only needs to short-circuit the two cables to unlock the door, presuming that the exit button is activated. The exit button can be schedule-controlled and thus be blocked at certain times of the day. See more in the section Hi-O for further information regarding an easy and safe installation.


18

Mounting reader

Wall Assembly

The reader should be fitted at a height of 112 cm above the floor, measured from the lower edge of the casing. (120 cm CC)

An accessibility adjusted installation of a reader should be 90 cm over the finished floor. To facilitate the use of the reader at 90 cm height it can be fitted with an accessibility holder that angles the reader 35 degrees out. Holder TMV01 Art No.: S556 163 131

It should be placed as close to the door handle as possible, not on the “hinge side”.

Outdoors

To protect readers from snow, ice and dirt fallout readers subjected to this should have a protective cover.

Post Assembly

Sometimes it is necessary to mount the reader on a post, for example at a gate or garage entrance. Exact measurements of this post are hard to give since this depends on the type of vehicles passing (trucks, forklifts, private cars). Normal height is 110 cm above ground, but this is only to be considered as a guide line.

In some cases two readers can be mounted on different heights to facilitate for the driver. To reduce the risk of collisions with the post the reader should be mounted on a boom from the vertical part of the post. An alternative can be to use a long distance touch-free reader, for example NMW270, to provide easy and secure access of vehicles.


19

Doors

Normally existing doors will be used. Check that door opens and shuts smoothly and that it is equipped with a door shutter. If twin doors are used it is very important that the normally closed door is securely bolted with espagnolette or such like. Wiring for electric strikes should be conducted through special wire conductors with flexible cable, when twin doors are used. If you yourself not are a practising locksmith, leave all mechanical work around the door to a skilled person. It pays off in the long run. If the door is classified as a fire door, there might be specific regulations.

If you have the possibility to make your own door choice, stable doors of high quality are recommended, regardless if they are made of wood, metal or steel.

Checklist for doors

Below follows some questions to be answered before a door can be connected to an access system.

QUESTION:

Does the door open without trouble?

Is the door torsionally rigid and stable?

Freedom from play on hinges?

Is it a twin door?

Does the door lock?

Is the door equipped with a door shutter?

Are there room for an electric strike?

Is motor lock for night locking required?

Is there an existing burglar alarm, magnetic contact?

If the door is equipped with an electric strike:

Does the electric strike work properly?

Is the electric strike worn down?

Is the voltage correct? 12V or 24V?

Does the electric strike stand continuous unlocking?

Is there a door monitor switch?

Is protective diode mounted?


20

Cables, dimensions for cables

It is important to use the correct type of cable.

UNIT DISTANCE

DAC, PCR, DBL – RX CONTROL UNIT *

DAC – READER#

ComHub – RX control unit

500 METER

500 METER

1000 METER

* DAC, PCR, DBL – locally at door.

# The distance can be up to 500 meters (totally), but normally a DAC is located at each respective door.

It is important to dimension the cables correctly to avoid voltage drops. Control unit, reader, electric strike all operates with a tolerance of ±10 %. The current consumption in each unit and the length of the cable decides the area of the conductor.

The formula for voltage drop calculation is as follows:

When the voltage is known: U = Sx2L X I a

U = Voltage drop in Volt. S = Resistivity – resistance per meter and at 1 mm

2 area (for copper

0.0175). L = Cable length (single length) in meters between power source and load. a = area in mm

2.

I = Amperage

U = 0.0175x200 X 0.2 U = 3.5V

0.2

The voltage drop on 100 meters, with a cable area of 0.2 mm2 and

amperage of 200mA give a 3.5V loss. In other words 20.5V at the load.

For voltage feed of the control unit a two-part wire is suitable.

Telephone cables (low voltage 12/24V DC). EKKX is a suitable standard cable. At risk for interference should TP-cables (twisted pairs) be used and as a minimum have a shield, for example ELAKY. The shielding is for protection of the cable against interference that can damage or interfere with the systems function.


21

Outside installation

Remember the mechanical protection. If there is risk of damages to the cable, by for example snow ploughs, the cable should be protected with sheet metal edges or valve.

Inside installation

Wiring should, as much as possible, be concealed. If this is not possible, cable ladders and the like should be used. It is particularly important to conceal the cables of vital functions or at least locate them on the locked side. For example cables for exit buttons, electric strikes and motor locks. See the section Hi-O for a safe encrypted installation.

Wire conducting

Wiring for electric strikes/motor lock should be conducted through special wire conductors with flexible cable, when twin doors are used, EA281 long.

Note! A multi-unit soft cable must be used. For further information about wire conductor products we refer to the product data sheet for each product.

Readers

Readers communicate with DAC via a 20mA current loop or via CAN and Hi-O. This means that ordinary TP-cables (twisted pairs) can be used since the reader normally is located near the DAC. The power supply goes through the same cable as the communication loop, this decides the area of the conductors. In areas with a lot of thunder, over voltage protection should be fitted.

Electric lock

Calculation of voltage drop must be made. The current consumption determines what area is called for.

The coils current power consumption determines the size of the cables. Calculate with a margin to avoid a to large voltage drop.

Mount the protective diode on the electric strike (electric latch, door lock, electric magnet or possibly intermediate relay) when control electronics is used. The diode protects electronics against transients (voltage tops).

Exit button

Recommended type of cable is EKKX 1x4x0.5 or equal.


22

Peripheral Equipment

RX9101 For further information on these products, we refer to the product data sheets for each product.

Transformer ST60S

ST60S is a protective transformer (240/24V 2,5A) with a ring-core that has thermal protection. It is a suitable power supply for all our access control products.

Article number 511 006 087

Transformer PSS60

PSS60 is a protective transformer (240/24V 2.5A) that can be mounted on a DIN rail. It is a suitable power supply for all our access control products.


Power supply unit 24V 2450PS

2450PS emergency power supply (240V/24V 5A) has two (2) outputs that each is two-pole fused with 2.5A, plus and minus individually fused. The unit is equipped with overvoltage protected, restorable fuses for overload protection and deep discharge protection with alarm relay.


DAC430

DAC430 is a communication unit and an intelligent connection terminal block intended to be fitted at each door. To each unit electrical lock, motor lock, reader, alarm and exit button can be connected. DAC430 can act as an alarm detector when relay board 400RC64 is used. DAC430 handles serial motor locks. Article number DAC430 S556 640 085

DAC500, DAC530 Hi-O

DAC530 has the same function as DAC430. DAC530 is a Hi-O unit that can use Hi-O components but also handles serial readers as 6485EM and 6585MF. Hi-O motor locks can be connected, but not serial motor locks. See page 25 for more information regarding Hi-O products. Up to thirty Hi-O units can be connected to DAC500/DAC530.

Article number S556 650 085, S556 650 1 085


23

DBL340, DBL342

DBL34, DBL342 are door leaf readers in a pleasant, slim design that can be connected directly to the RX control unit. The difference between them is that DBL342 has a door leaf monitor and exit button function in the inside handle.

Article number DBL340 S556 708 000, DBL342 S556 718 000

PCR40/PCR45

PCR40 is a compact reader for inside doors that can be connected directly to the control unit. PCR40 handles electrical locks, for example electric strike Solid575, and uses EM prox cards as decoding method.

Article number Black 556 511 084, Silver gray 556 511 086

PCR45 has the same functions as PCR40 but uses Mifare technology.

Article number Black 556 545 084, Silver gray 556 545 086

Exit button TKN01/TKN02

Exit button to be used on the inside of locked doors where a simple push unlocks the door and, if required, bypasses the alarm. TKN-01 is used with an open assembly and TKN-02 with a closed assembly.

Article number 511 557 085/511 558 085

Exit button TKN40

TKN40 is a touch exit button to be used on the inside of locked doors where a simple push unlocks the door and, if required, bypasses the alarm. TKN40 open/closed assembly.



24

Peripheral Equipment DAC Interface 6390IF

Interface for handling of OEM readers, Wiegand, Proximity or clock/data (magnet).


Exit button TKN01/TKN02

Exit button to be used on the inside of locked doors where a simple push unlocks the door and, if required, bypasses the alarm. TKN-01 is used with an open assembly and TKN-02 with a closed assembly.

Article number 511 557 085/511 558 085

Exit button TKN40

TKN40 is a touch exit button to be used on the inside of locked doors where a simple push unlocks the door and, if required, bypasses the alarm. TKN40 open/closed assembly.


Peripheral Equipment Readers Rain Cover 6160RS

Rain cover 6160RS for the reader protects outdoor installations. It protect against snow and ice and should also be used in dirty environment as for example garages.


Code carrier

Code carriers come in different forms depending on the reader type to be used, cards or tags.


25

Hi-O components to the DAC500 family All Hi-O components uses plug and play at installation.

Exit button TKN50

TKN50 is a touch-free exit button to be used on the inside of locked doors together with DAC 500 where a simple push unlocks the door and, if required, bypasses the alarm. TKN50 open/closed assembly.

TKN50 is connected to the Hi-O bus.

Article number S515 000 085

EM reader 5485EM

5485EM is a Hi-O reader for touch-free cards with EM technology and open assembly. 5485EM is connected to the Hi-O bus. Comes as Black/Silver gray

Article number S555 485 084/S555 485 086

Mifare serial and sector reader 5585MF

5585MF is a Hi-O reader for touch-free cards with Mifare technology, 5585MF can read the public number on Mifare cards as well as card data stored in a locked sector. ASSA recommend the use of sector reading for the highest security. For open assembly. 5585MF is connected to the Hi-O bus. Comes as Black/Silver gray

Article number S555 585 084/S555 585 086

ASSA Solid585 Electric strike

Solid585 is a Hi-O electric strike with the same measurement and look as Solid575.


ASSA Motor lock

810C, 811C, EL654, EL754 are Hi-O motor locks, 810C comes in 50 and 70 mm depth and 811C comes in 35, 50 and 70 mm depth.


26

Master reset, initiation and addressing Master reset and initiation is performed to zero RX9101 and DAC, PCR, DBL to erase unwanted information from the memory, then the addressing is made.

The addressing is made on each DAC, PCR, DBL and reader to give them a unique address. These assigned addresses should not be altered.

Master reset and running mode for RX9101 Proceed as follows:

1. Switch off the power for the control unit.

2. Put DIP switch 6 in position ON and turn on the power again.

3. Wait until WDG, B and C LED is flashing.

ON: Clears the database in RX9101 at upstart and resets it to factory settings. Note! When this is done the RX9101 will lose all settings and new information must be loaded/fed to the RX9101.

OFF: Normal operation.

4. Switch off the power again.

5. Put DIP switch 6 in position OFF.

6. Turn the power on.

Restoring the password

It is possible to have several users in RX but only one can have full authority to the system. In the event the login information for this user has been lost there is a possibility to restore it to the delivery login, in other

words master without password.

Procedure for this:

1. Put DIP2 in position ON. Note! Don’t touch any other DIP switches. 2. Reset DIP2 to OFF.

Now the login for RX is restored to the delivery login. Which is master as user without password.


27

Initiation and addressing of DAC420/430, PCR, DBL

(With motor lock, see further in the DAC manual. Note that DAC500 demands another procedure, which is described on the next page.)

Proceed as follows:

With the power off, set all DIP-switches to the OFF position.

Turn on the power (approx. 10 seconds). When the WDG diode flashes fast the unit is reset to its default values.

Turn the power off and address DAC, PCR, DBL.

Turn the power on.

The DIP switches are numbered 1 – 8 and 1 – 5 are used for the addressing.

The table shows how the DIP switches should be set when addressing DAC. PCR, DBL.

Door/DIP 1 2 3 4 5

1 ON

2 ON

3 ON ON

4 ON

5 ON ON

6 ON ON

7 ON ON ON

8 ON

9 ON ON

10 ON ON

11 ON ON ON

12 ON ON

13 ON ON ON

14 ON ON ON

15 ON ON ON ON

16 ON

Table 7

Note! Address 0 is only to be used at initiation.

DIP switch 6 ON = Balanced IN on SW, KP-2:13&14 micro switch/door leaf. See more on page 12.

DIP switch 7 OFF DIP switch 8 OFF


28

Initiation and addressing of DAC500/DAC530 Before the commissioning you must decide how the motor lock or electric strike should be used, i.e. should an internal or external door monitor be used in the motor lock and/or should the electric strike work in fail safe or safe secure mode. Observe that the functions of the DIP switches differ between initiation mode and operation mode.

A Install and lock a newly installed Hi-O door environment

A1 Connect the Hi-O unit s to DAC Be sure to connect the cables between the Hi-O unit and DAC500/DAC530 correctly, CAN H to CAN H and CAN L to CAN L.

A2 Connect cables to power Connect power feed to the Hi-O unit from DAC. Don’t turn the power on yet.

A3 Select group for the Hi-O unit Select the correct group for the Hi-O unit, 1 or 2 depending on which unit that is installed.

Group 1 = outside reader, motor lock, electric strike or exit button RTE. Group 2 = inside reader or external button for door automatic.

A4 Make sure that DAC500/530 is terminated This is done by putting the termination jumper link in position ON in DAC.

A5 Initiate and lock the Hi-O units to DAC a) Whit the power off, set DIP switch 7 and the “Door monitor” input to

desired position for initiation of the correct function of the unit (see initiation matrix on page 31 )

b) Turn the power on.

c) Wait until the WDG LED (blue) flashes fast and the PWR LED (yellow) is lit (can take up to 3 minutes, normally approx. 45 seconds).

d) Turn the power off.

A6Address DAC to correct address. Observe that the “Door monitor” input should be jumper linked in operation mode if not used.

A7 The door environment is now configured and locked to the DAC


29

B Add further Hi-O unit to a locked Hi-O door environment.

B1 With the power off, connect new unlocked Hi-O units according to A1 – A3.

B2 Initiate and lock the Hi-O units (and thereby the door environment) a) Whit the power off, set DIP switch 7 and the “Door monitor” input to

desired position for initiation of the correct function of the unit (see initiation matrix on page 31 ).




B3 Address DAC to correct address. Observe that the “Door monitor” input should be jumper linked in operation mode if not used.

B4 The door environment is now configured and locked to DAC

The communication in the Hi-O door environment is encrypted, locked to the DAC in question. This means that new units can’t be connected. The units in the door environment cannot be moved without unlocking them first.

If further units are added afterwards the initiation must be made again. To remain earlier functions, see the DAC initiation matrix on page 31.


30

C Move or remove a locked Hi-O unit

Important to observe Always unlock Hi-O units when removing them from a door environment; otherwise you cannot use them in another door environment.

C1 Unlock the door environment and the Hi-O configuration where the specific Hi-O unit is located. a) With the power off, set all DIP switches to OFF.

b) Keep pressing the tamper switch and turn the power on.

c) Keep pressing the tamper switch until WDG LED (blue) flashes slowly.

d) Wait until WDG LED (blue) flashes fast and PWR LED (yellow) is lit.

e) Turn the power off

f) You can now remove the Hi-O unit

C2 Initiate and lock the Hi-O units (and thereby the door environment) a) Whit the power off, set DIP switch 7 and the “Door monitor” input to

desired position for initiation of the correct function of the unit (see initiation matrix on page 31 )




C3 Address DAC500/DAC530 to correct address.

Observe that the “Door monitor” input should be jumper linked in operation mode if not used.

The communication in the Hi-O door environment is encrypted, locked and secure. This means that “Plug-and-Play” is disabled and that no new units can be added. The units in the door environment cannot be moved without unlocking them first.

If adding further units afterwards the initiation must be made again to keep the previous function. See DAC initiation matrix.


31

Initiation matrix DAC500, DAC530, DAC564 (Observe that this applies at initiation and not in operation mode)

Door monitor input DIP7 – Electric strike Explanation

Closed

OFF

Sensor in motor lock active. Safe secure function on electric strike

ON

Sensor in motor lock active. Fail safe function on electric strike

Open

ON

Sensor in motor lock inactive. Fail safe function on electric strike

OFF

Sensor in motor lock inactive. Safe secure function on electric strike

DAC500 in standalone mode

The Button input closed at initiation

The input will be flank triggered, i.e. DAC500 will lock the door according to set time if the input remains closed while running.

The Button input open at initiation

The input will be level triggered, i.e. DAC500 will set the door unlocked as long as the input is closed, which is normal mode.

Observe! If the electric strike is used in fail safe function, it must also be altered mechanically to this mode.

Addressing Hi-O units



32

Installation of Hi-O Components Connection diagrams, Hi-O components.

The Hi-O units can be connected as a bus or as a star connection.

Termination is normally only made in DAC and then by positioning the termination jumper link in position ON.


33

Addressing CL reader CL reader

(The addressing doesn’t apply for Hi-O readers) When connecting a reader to DAC the address should be 0 (zero).

When connecting both outside and inside reader the outside should have address 0 (zero) and the inside address 4 (four).

Outside reader = All DIP switches in position OFF (address 0)

Inside reader = DIP switch 3 in position ON (address 4)

Reader/DIP 1 2 3 4

Outside (0) OFF OFF OFF OFF

Inside (4) OFF OFF ON OFF

Note! If other reader types are used together with Interface 6390IF the interface should be addressed as above.


34

Checklist at start up Check that all the cable connections have been isolated and are

fastened.

Connect both door surveillance and blocking input to 0V if they not are used.

Check that the readers are addressed correctly. Inside reader with address 4 (DIP switch 3 ON) and outside reader with address 0 (all DIP switches in position OFF). If it are Hi-O readers the outside reader should have group 1 and the inside reader group 2

Address DAC, PCR, DBL

Install the door/doors in the program. See further in the user guide.

With the power on the LED indication (PWR in DAC, PCR, DBL and WDG in the control unit) should be flashing. See page 35.

The yellow arrow should be lit on all readers connected to DAC.

Check the voltage for the reader communication loop. You do this between connection C+ and C- in DAC. It should be approx. 2.2V if only one (1) reader is connected and the loop is intact. When two (2) readers are connected the voltage should be approx. 4.4V.

At the door 1. Press the exit button. The green man should be lit and the electric

strike open. If not, check the connections.

2. Press the exit button and open the door within 3 seconds. The electric strike should lock when the door has been opened. Otherwise, check the function of the door contact in the electric strike. Shut the door.

3. Press the exit button and open the door. Keep the door open for more than 30 seconds. The buzzer in the reader should start sounding. It should become silent when the door is closed.

4. Present a code carrier to the reader. The red man should be lit. This shows that the reader communicates with DAC, PCR, DBL/control unit.

This demands that the door is installed in the program, see further in the user guide.


35

Troubleshooting

DAC If the readers/door environment doesn’t work: With the aid of the LED indications, check that DAC, PCR, DBL works as it should.

PWR (Power) – Yellow indication, indicates that system is powered.

WDG (OK) – Normal flash approx. 2 Hz Master reset done – approx. 20 Hz = fast flash Lit – Error

TxD (Communication) – Flashes fast at answer to the control unit.

RxD (Communication) – Flashes fast at communication to the control unit.

Flashes slow (irregular) = One or several installed DAC, PCR ,DBL can have a communication problem, caused by for example a cable breakdown.

Fast flash = Communication with the control unit.

Unlit = Communication cables OK, but the control unit do not communicate, or all doors are uninstalled in the program.

RX9101

LED indications on the CPU board

WDG (OK) – Flashes fast approx. 15 Hz = The control unit is operating.

Flashes slowly together with LED B and C = Check DIP switch 1.

LED indications on ADD-ON board 9101D3

At each door connection there is a LED indication that always should be lit if a DAC, PCR, DBL is connected. LED Flickers a bit at communication with the door environment.

If Aperio ComHub should be connected the 9101D3 board must be supplemented with 9101D3A.


36

Readers PROBLEM STEP

The card symbol and the red man flash alternately.

Same address on the inside and outside reader (communication interference). Step: Address both readers correctly, the outside with address 0 and the inside with 4.

The card symbol goes out (flashes very slowly) and the green man gives a blink.

The reader do not communicate with DAC. Could be the following: DAC is in initiation mode. The communication to the reader is turned the wrong way. Cable breakdown on the reader cables. The outside reader is OK, but the inside is acting as above. Step: Address both readers correctly, the outside with address 0 and the inside with 4.

The card symbol flashes (lit and unlit every second).

Interruption in the communication between control unit and DAC, PCR, DBL, or the door hasn’t been installed in the program.

Red man lights up, despite a valid card being swiped

Wrong system number. Wrong format of “card data”. Check card and schedule number in the program. DAC, PCR, DBL blocked. Check the log over the current card. Check the blocking input in DAC.

The card symbol is lit. When the code carrier is presented to the reader the card symbol gives a blink but nothing else happens.

Wrong type of reader is set in the program. Step: Check that the correct reader type is installed, both hardware and software.


37

00

06

8e

30

07

5f

Description of RX9101

RX9101 connections

Button = Unlocked when closed to 0V. The door will lock even if the input remains closed.

SW = The door is presumed closed when pin 13 is connected to 0V (pin 12), and DIP3 = OFF.

DIP3 ON = Balanced input on

Door monitor 2k2 , see page 41.

LCU9101 must be restarted after selecting DIP3 = ON Balanced mode.

Electric strike (1&2) Coil For function and current, see jumper link field on page 40

Terminal blocks

Electric strike/Electric lock (Pin 1 = +, 2 = -)

ABP (Temporary alarm bypass)

Prepared for future Hi-O connection

Feeding to reader and Hi-O components Directly connected motor locks and CL readers

Button = Connection of exit button 0V = Common for SW and Button SW = Input for door monitor switch

Feeding of control unit 17 – 50V DC and 17 – 35V AC

RX9101 cannot be fed with 12V!


38

00

06

8e

30

07

5f

Location of LED indications on the main board


39

LEDs on the CPU board

There are a number of LEDs on the CPU board, each indicating different status modes. The different LEDs and their positions are described below.

Meaning of the LEDs.

PWR: (Power)

WDG: Blue (OK) Blue indication, flash approx. 2 Hz (2 flash/sec.) Access application started LED lit – Linux starting

CL: Red: Lit when readers are connected to the CL+/CL- port.

OL: (Over Load) Lit when the over voltage protection to 12V out is triggered, pin +12V/0V (feeding reader etc.).

A: Yellow: No function in RX mode.

Flashes slowly while the control unit tries to create a connection with the ARX server. Lit when the control unit is in contact with ARX.

B: Red: No function in RX.

Lit when the control unit have messages to send to ARX .

C: Green: No function in RX.

Receiving data.

D: Green: Session connected with the browser.

12V Over: Red: Lit when the over voltage protection to 12V out via RE1 NO/C is triggered.

Link: Lit at link. Unlit when there is no link.

100M: Lit at 100Mbit communication. Unlit when there is no 100Mbit communication.

ACT: Flashes at activity on the Ethernet port.

When the voltage is turned on for the board LED’s are lit to show that they are working. After approx, 1 second all LED’s are unlit, except the blue WDOG.


40

Jumper link fields RX9101

Hi-O termination

Selection of NO/NC relay 1 (Electric lock

relay)

00

06

8e

30

07

5f

Selection of NO/NC relay 2 (LFK)

12V out (1=+, 2=-) (12V Out on relay 1)

V in (1=+, 2=-) (V In power out on relay 1)

Potential free contact

DIP switch

DIP1 Telnet ON/OFF

DIP2 Mode ON Resets the user and password to master and empty password

DIP3 Balanced door leaf monitor contact

DIP4 Fixed IP 192.168.1.250

DIP5 OFF= https: or ON = http: Applies to RX9101

DIP6 Master reset samt testläge


41

DIP settings RX9101 main board

DIP1 Telnet

If DIP1 is in position ON when RX9101 is started it is possible to communicate with the control unit via Telnet. Used when the control unit should be configured via the Ethernet contact.

DIP2 Resets password and user

DIP2 in position ON resets the user to master without password.

DIP3 Balanced door monitor switch

DIP3 in position ON and two resistors of 2,2KΩ mounted on the door monitor switch, then restart the control unit.

DIP4 Fixed IP 192.168.1.250

Can be used when you want to set up the control unit with the aid of a TP cable, used together with DIP1.

DIP5 https:// or http://

RX9101 always works in http:// mode, if you which to turn of the safe mode and run unencrypted DIP5 is set in mode ON and RS9101 is restarted. You are now in http:// mode.

DIP6 Master reset and a reset of the password

DIP6 in mode ON sets RX9101 in test mode. In the test mode you can check installed readers and lock, but not the motor lock. Normal position for DIP6 is OFF. Note! If DIP6 is in mode ON at an upstart the entire database will be deleted.

Master reset

Set DIP6 in position ON. The control unit makes a master reset on all parameters at upstart and resets RX9101 to the default settings.

Note! When this is done RX9101 will lose all settings and new information must be loaded or restored from a backup.

PWR


42

Balanced Door monitor switch

DIP3 ON = Balanced IN on SW. Resistor of 2,2k is delivered with RX9101. These are the valid values for the input on RX9101 (12&13)

SAB Rin 1,8k

OK 1,8k Rin 3,3k

ALARM 3,3k Rin 15k

SAB Rin 15k

This function means that you get the whole chain (from alarm central via RX9101 to door) double balanced and the RX9101 works as a "detector". See picture below.

RX9101 must be restarted after selecting DIP3 = ON Balanced mode.


43

Installation hardware

Connection of reader to RX9101

One reader

2

5

8

0

1

4

7

A

3

6

9

B

6485EMA S S A Æ

00

06

8e

30

07

5f

Outside reader DIP1 – 3 in mode OFF

Two readers

2

5

8

0

1

4

7

A

3

6

9

B

6485EMA S S A Æ

00

06

8e

30

07

5f

2

5

8

0

1

4

7

A

3

6

9

B

6485EMA S S A Æ

Inside reader DIP3 in mode ON


44

Electric strike with door leaf monitoring and exit button

00

06

8e

30

07

5f

+-

12V

NO

NC

12V out (1=+, 2=-) (12V Out on relay 1)

V in (1=+, 2=-) (V In power out on relay 1)

Potential free contact


45

RX9101 with ADD-ON board 9101D3 and DAC

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Term

ina

tion

12

34

56

78

00

06

8e

30

07

5f

24V DC+

-

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFFTerm

ina

tion

12

34

56

78

00

06

8e3

00

75

f

24V DC+

-

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Term

ina

tion

12

34

56

78

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Term

ina

tion

12

34

56

78

Give DAC the correct address to match the settings in the program!


46

Directly connected DBL34, DBL340, DBL342 to RX9101

00

06

8e

30

07

5f

24V DC+

-

RX9101 can also handle DBL connected directly to the control unit, the directly connected DBL are addressed to 1 (DIP1 = ON). The connections are made to 12V, 0V, CL+, CL- on the main board. Note! PCR or DAC should not be connected directly to the main board.

You can also connect up to three more DBL units to the control unit when you have the 9101D3 board installed, or a mix with DAC. The addressing is made in the same way as the addressing of DAC, see page 59.

00

06

8e

30

07

5f

24V DC+

-


47

VOXIO Reader (9101R4850) or (9101D3 with 9101D3A)

+12V

A

B

0V

1

Select Opendo as reader technology in the program.

Aperio ComHub (9101R4850) or (9101D3 with 9101D3A)

+12V

A

B

0V

RS485 A

RS485 B

12-24V DC

GND

For addressing of RS485 reader and ComHub, see table on page 59 – 60.

Maximum length of cable to ComHub is 1000 meters. At cable length over 500 meters 24V DC is recommended as feeding for the ComHub loop. See also the ComHub manual on how the termination should be made.

Use the voltage drop calculation on page 20.


48

Aperio ComHub (9101D3 with 9101D3A)

00

06

8e

30

07

5f

Ap

erio

RS4

85

Po

rt B

RS4

85

A

RS4

85

B

12

-24

V D

C

GN

D

RS4

85

A

RS4

85

B

12

-24

V D

C

GN

D

RS4

85

A

RS4

85

B

12

-24

V D

C

GN

D

23

Maximum length of cable to ComHub is 1000 meters. At cable length over 500 meters 24V DC is recommended as feeding for the ComHub loop. See also the ComHub manual on how the termination should be made.

Use the voltage drop calculation on page 20.

Aperio ComHub are addressed from 2 – 15 for door 2 – 15 and door 16 is addressed as 1. Max 12 ComHub can be connected between these addresses. In the program Aperio doors are installed as follows:

DAC, PCR, DBL connected door, and select correct reader technology


49

Connection Aperio 1-8 HUB

RS4

85

A

RS4

85

B

12

-24

V D

C

GN

D

RS4

85

A

RS4

85

B

12

-24

V D

C

GN

D

00

06

8e

30

07

5f

Ap

erio R

S48

5 P

ort B

23

DIP Function in HUB

1-4 Address

5 Not used

6 ON = 620 pull down

7 ON = 620 pull up

8 ON = Termination

9 Not used

10 ON = Internal antenna

OFF = External antenna


50

Termination of Aperio HUB RS485 buss

LCU/RX9101

HUB HUB HUB

BA A AB B

DIP 6 OFFDIP 7 OFFDIP 8 OFF

DIP 6 OFFDIP 7 OFFDIP 8 OFF

DIP 6 ONDIP 7 ONDIP 8 ON

LCU/RX9101

HUB HUB

BA AB

DIP 6 OFFDIP 7 OFFDIP 8 ON

DIP 6 ONDIP 7 ONDIP 8 ON

A B


51

Aperio 1-8 ComHub are addressed from 1-15. Aperio doors are installed in the software according to below:

B-D

E-F

G

Value on DIP -> 1 2 4 8

Address / HUB DIP 1 2 3 4

Address 1 ON

Address 2 ON

Address 3 ON ON

Address 4 ON

Address 5 ON ON

Address 6 ON ON

Address 7 ON ON ON

Address 8 ON

Address 9 ON ON

Address 10 And so on

A) Match the lock with correct HUB using the PAP software.

B) Address the HUB, for example to address 2.

C) Set a unit adress, for example 1.

D) Save and close the window.

E) Open the window again, now you are presented with the unit ID for the lock.

F) Annotate the unit IDand give the door a proper name. ”Store room A”

G) Continue with the next door.


52

Terminal block description and connections on the 9101D3 board

Feeding of DAC for door environment 2 - 4: 12-35V AC/DC

Feeding out via electronic fuse to DAC

Communication to DAC

The same for the two following four-pole terminal blocks

Blocking input of LCU/Alarm area. IN3

External alarn activation input IN4

Programmable relays, realy 1 and 2

Aperio communication port and feeding for Com-HUB Feeding out 12V Max load 250mA


53

Trouble shooting guide and indications for Aperio doors

LED indications Answer

Aperio ComHub

If LED is switching between red and green in ComHub.

Communication error between RX9101 board and ComHub

Aperio door reader

Five fast red flashes. Internal error in the unit. Inside and outside units have probably been connected wrong.

After presentation of code carrier

Yellow flash The door unit has read the code carrier

Green LED Access granted

Red LED Access denied

Three slow red flashes

No communication to LCU or ComHub


54

Connection of electric strike, door monitor switch and exit button to DAC

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Term

ina

tion

12

34

56

78

+-

12V


55

Connection of exit button and reader to DAC

The Reader address = 0 (DIP1 – 3 = OFF)

DAC500

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

AL

AR

M

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC500

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Te

rmin

atio

n1

23

45

67

8

12

3

4

5

®

003

68:1


56

Connection of inside and outside reader on the same door

DIP3 = ON DIP1 – 3 = OFF

1

2

3

4

5

1

2

3

4

5

Inside reader Outside reader

CONNECTION

FROM DAC

12V

0V

Communication +

Communication --

00

322:1

® ®


57

DAC with relay board DAC400RC64


58

Easy installation with Hi-O via DAC500

DAC

12V OVER

VIN 12V

RE J8

J8

DC RE

NO NC

J2 LO

CK

ALA

RM

NO NC

J3

WDG

TxD

RxD

PWR

17-24V AC/DC

12V DC

AC/DC 1

AC/DC 2

C+ 3

C- 4

CAN H 5

6

12V 7

0V 8

C+ 9

C- 10

IN 11

0V 12

IN 13

0V 14

(+) NO/NC 15

(-) C 16

NO/NC 17

C 18

COM-LOOP

DAC

DOOR MONITOR

BUTTON

READER

COM-LOOP

AD

D-O

N C

AR

D

CAN L

ON

OFF

Term

ina

tion

12

34

56

78

2

5

8

0

1

4

7

A

3

6

9

B

6485EMA S S A Æ

-

Exit button TKN50

Hi-O Electric strike Solid585

The Hi-O bus can also be connected to motor lock, door automatic, reader etc. Several motor locks and electric strikes can be connected to the same DAC500.

Reader 5485EM/5585MF

Inside or outside reader

Outside reader = Reader DIP ”Group”/”Gr” in mode OFF.

Inside reader = Reader DIP ”Group”/”Gr” in mode ON.

Motor lock and Electric lock should have the group swithc in mode OFF.

Additions, expansions of Hi-O components

When adding components on the Hi-O bus, as readers, locks, exit buttons and door automatics, an initiation must be made, see page 28.

If a door automatic with Hi-O is connected, which in itself is fed with 230V AC, only the CAN-H and CAN-L of the Hi-O bus should be connected. (You shouldn’t have two feedings for the Hi-O bus.)


59

Addressing of Aperio ComHub, DAC and reader

Addressing of Aperio ComHub

Max 12 ComHub units can be installed and 3 DAC between address 2 – 16

Address DIP1

1

DIP2

2

DIP3

4

DIP4

8

DIP5

16

Basal door 01 The main board is not addressed

Door 02 ON

Door 03 ON ON

Door 04 ON

Door 05 ON ON

Door 06 ON ON

Door 07 ON ON ON

Door 08 ON

Door 09 ON ON

Door 10 ON ON

Door 11 ON ON ON

Door 12 ON ON

Door 13 ON ON ON

Door 14 ON ON ON

Door 15 ON ON ON ON

DAC door on door pos. 16

ON

Note! Aperio door on door pos. 16

ON


60

Addressing of VOXIO RS485 reader

DIP1

1

DIP2

2

DIP3

4

DIP4

8

DIP5

16

DAC Addressing VOXIO RS485 reader on DAC585

Reader

(In) ON

(Out) ON

LCU Addressing VOXIO RS485 reader on RX9101

(In) ON ON

(Out) ON ON

Addressing reader 6485EM, 6480EM, 6585MF

(The addressing doesn’t apply for Hi-O readers) When connecting a reader to DAC the address should be 0 (zero).

When connecting both outside and inside reader the outside should have address 0 (zero) and the inside address 4 (four).

Outside reader = All DIP switches in position OFF (address 0)

Inside reader = DIP switch 3 in position ON (address 4)

Reader/DIP 1 2 3 4

Outside (0) OFF OFF OFF OFF

Inside (4) OFF OFF ON OFF

Note! If other reader types are used together with Interface 6390IF the interface should be addressed as above.

Addressing of Hi-O units


Documents

RX IG - Assa Abloy