Micro Application Example

Integration through Communicaton with KNX/EIB
(with LOGO! and CM EIB/KNX)

Micro Automation Set 28

Table of Contents

Micro Automation Set 28

Entry ID 23810653

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Note

The Micro Automation Sets are not binding and do not claim to be complete
regarding the circuits shown, equipping and any eventuality. The Micro
Automation Sets do not represent customer-specific solutions. They are only
intended to provide support for typical applications. You are responsible for
ensuring that the described products are correctly used. These Micro
Automation Sets do not relieve you of the responsibility of safely and
professionally using, installing, operating and servicing equipment. When using
these Micro Automation Sets, you recognize that Siemens cannot be made
liable for any damage/claims beyond the liability clause described. We reserve
the right to make changes to these Micro Automation Sets at any time without
prior notice. If there are any deviations between the recommendations provided
in these Micro Automation Sets and other Siemens publications – e.g. Catalogs
– the contents of the other documents have priority.

Warranty, Liability and Support

We accept no liability for information contained in this document.

Any claims against us – based on whatever legal reason – resulting from the
use of the examples, information, programs, engineering and performance data
etc., described in this Micro Automation Set shall be excluded. Such an
exclusion shall not apply in the case of mandatory liability, e.g. under the
German Product Liability Act (“Produkthaftungsgesetz”), in case of intent, gross
negligence, or injury of life, body or health, guarantee for the quality of a
product, fraudulent concealment of a deficiency or breach of a condition which
goes to the root of the contract (“wesentliche Vertragspflichten”). However,
claims arising from a breach of a condition which goes to the root of the contract
shall be limited to the foreseeable damage which is intrinsic to the contract,
unless caused by intent or gross negligence or based on mandatory liability for
injury of life, body or health. The above provisions does not imply a change in
the burden of proof to your detriment.

Copyright© 2006 Siemens A&D. It is not permissible to transfer or copy
this Micro Automation Sets or excerpts of them without first having prior
authorization from Siemens A&D in writing.

Table of Contents

Micro Automation Set 28

Entry ID 23810653

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Foreword

Micro Automation Sets are fully functional and tested automation
configurations based on A&D standard products for simple, fast and
inexpensive implementation of automation tasks for small-scale
automation. Each of the available Micro Automatic Sets covers a frequently
occurring subtask of a typical customer problem in the low-end
performance level.

The sets help you obtain answers with regard to required products and the
question how they function when combined.

However, depending on the system requirements, a variety of other
components (e.g. other CPUs, power supplies, etc.) can be used to
implement the functionality on which this set is based. Please refer to the
respective SIEMENS A&D catalogs for these components.
The Micro Automation Sets are also available by clicking the following link:

http://www.siemens.de/microset

Table of Contents

Micro Automation Set 28

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Table of Contents

Table of Contents ......................................................................................................... 4

Application Areas and Usage ........................................................................ 5

Setup................................................................................................................ 9

Hardware and Software Components ......................................................... 12

Function Principle ........................................................................................ 14

4.1

Recording measured values ........................................................................... 14

4.1.1

Record filling level in oil tank using the SITRANS Probe LU .......................... 14

4.1.2

Record status of doors and windows with GAMMA wave AP 260.................. 15

4.2

Display values measured locally in the LOGO! logic module ......................... 16

4.3

Integrating components into the GAMMA instabus network........................... 17

4.3.1

Addressing inputs/outputs of LOGO! .............................................................. 17

4.3.2

Exchanging analog values between LOGO! and EIB/KNX............................. 19

4.3.3

Addressing of GAMMA instabus components ................................................ 20

4.4

Connecting GAMMA instabus with Ethernet................................................... 21

4.5

Visualizing the measured values transmitted via Ethernet/Internet ................ 22

Configuring the Startup Software ............................................................... 23

5.1

Preliminary remark.......................................................................................... 23

5.2

Download of the startup code ......................................................................... 23

5.3

Configuring Components ................................................................................ 24

5.3.1

Installing, wiring and networking the hardware............................................... 24

5.3.2

Configuring SITRANS Probe LU..................................................................... 25

5.3.3

Configure GAMMA instabus components....................................................... 26

5.3.4

Configuring IPAS ComBridge Studio .............................................................. 30

5.3.5

Configuring the Apache Webserver................................................................ 33

5.3.6

Configuring the LOGO! logic module.............................................................. 35

Live Demo...................................................................................................... 36

6.1

Testing the communication paths ................................................................... 36

6.2

General operating notes ................................................................................. 38

6.2.1

Simulate filling level in the oil tank .................................................................. 38

6.2.2

Simulating closed or opened entrance door ................................................... 38

6.2.3

Displaying filling level and threshold value at the LOGO! logic module.......... 39

6.2.4

Visualization with IPAS ComBridge Studio at the server................................ 39

6.2.5

Visualization by IPAS ComBridge Studio at a PC in the network ................... 40

6.3

Scenarios........................................................................................................ 41

6.3.1

Simulating and visualizing the filling level of the oil tank ................................ 41

6.3.2

Simulating and visualizing door status (open/closed)..................................... 42

6.3.3

Simulating a plant error at the LOGO! logic module ....................................... 43

Technical Data .............................................................................................. 44

Application Areas and Usage

Micro Automation Set 28

Entry ID 23810653

Application Areas and Usage

Automation Task

A real estate association manages 20 distributed real estates. Each of
these objects is equipped with a central oil heating system. With regards to
economic purchasing of oil, the estate manager likes to buy large quantities
with high discount rates. A prerequisite for planning the oil purchase is the
central detection of the oil reserves currently existing in the respective real
estates.

Additionally, the centrally recorded measured values should have the
following benefits:
• Transparent display and logging of the heating oil consumption in the

estates

• Flexible ordering of heating oil when market prices are cheap

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• Filling the heating oil tank shall be monitored locally using a display and

a signal lamp

In this context the following measured values shall be recorded and
monitored via a central control room. The control room is accessed via
internet.

Figure

1-1

Oil tank

Burglary

protection

Internet

Apart from detecting, transferring and displaying the tank filling level, an
alarm system is to provide security for the residents as well. The first step is
monitoring the opening and closing of each entrance door.

Application Areas and Usage

Micro Automation Set 28

Entry ID 23810653

Automation solution – Set 28

For distributed monitoring of measured values for the real estates, the data
of the individual estates are transferred to a control room via internet. The
control room consists of a SIMATIC Microbox PC 420 with visualization
software ComBridge Studio by IPAS.

The sensor system is connected to a LOGO! logic module. Internal data
communication of each property occurs using the building installation bus
GAMMA instabus. The LOGO! communication module CM EIB/KNX is
used as interface between the LOGO! logic module, and the GAMMA
instabus

. The connection between the EIB/KNX components and the

internet is realized by the IP Interface N 148/21.

The visualization software IPAS ComBridge Studio in the control room
enables graphic display, operation and logging of measured values. Using
an integrated web server, internet capable devices such as PCs, notebooks
and PDA´s can comfortably access the measured values.

Figure

1-2

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Ethernet infra structure

Automation system LOGO!

GAMMA instabus EIB building installation technology

-Sensors
-Actuators
-Automation

-Sensos
-Operation
-HMI

-Operation
-Visualization
-Logging
-Web server
-User management
-etc.

HTML-based operating and

monitoring, mobile

Simple wiring

GAMMA instabus EIB

Ethernet

LOGO! communicaton module CM EIB/KNX

IP Router N 148/21

Standardrouter

Firewall

Standardrouter

Firewall

Internet

HTML-based operating and

monitoring, internet connection

required

Application Areas and Usage

Micro Automation Set 28

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A SIMATIC SITRANS Probe LU ultrasonic sensor records the filling level
in the heating oil tank and transfers it to the LOGO! expansion modules
AM2

via an analog input. Three signal lamps connected to the digital

outputs of the LOGO! logic module signal the following status.
• Heating oil tank empty
• Heating oil tank nearly empty
• Heating oil tank overfilled
The heating oil level is indicated by the integrated display of the LOGO!
logic module. The threshold values for the status of the signal lamps can be
changed using the LOGO! logic module.

GAMMA wave door/window contact

is used for monitoring the status of

the entrances (open/closed) is used. This door/window contact transmits
the status via radio to a wave / instabus UP 140 coupler.

Application Areas and Usage

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Application Areas

• In-house

installation

• Building

automation

Benefits

• Networking LOGO! logic modules via the GAMMA instabus
• LOGO! functionality can be expanded by GAMMA instabus

components

• Functionality of the LOGO! components not affected by a failure of the

GAMMA instabus network

• Clock/date synchronization of LOGO! devices via GAMMA instabus
• Favorable sensors for digital and analog measured value recording can

be connected with components from the GAMMA instabus via LOGO!

• LOGO! process data available in many systems (e.g. Ethernet, infrared,

radio, ISDN, PROFIBUS DP, USB, RS232) using GAMMA instabus

• Visualization, logging and archiving of LOGO! process data on the

• Configuration of the GAMMA instabus components via internet

Setup

Micro Automation Set 28

Entry ID 23810653

2 Setup

Layout Diagram

Figure

2-1

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DC24V+

DC24V-

SV+

SV-

SIG+

SIG-

+ -

- +

Bac

k p

lan

Line protection switch

- +

Close internet connection

2 l

Fig. 2-3 r

Wave / instabus UP 140 coupler to UP 114 bus connector

IP Interface N148/21

Connector

Data bus

USB Interface N148/11

Voltage supply. N125/21

MicroBox PC 420

SITRANS Probe LU

opt. SIMATIC PXS300

LOGO! CM EIB/KNX

LOGO! AM2

LOGO! Logic module

LOGO! Power

Micro Automation Set 28 consists of a LOGO! logic module (2) with relay
outputs and integrated time of day function. A SITRANS Probe LU (6) is
connected at an analog input of the LOGO! AM2 expansion module (3).

Furthermore, the communication module CM EIB/KNX (4) is employed
for providing a connection to the GAMMA instabus EIB/KNX network.

The DC 24V power supply for the LOGO! devices is provided by a
LOGO! Power 2.3A

(1). The SIMATIC MicroBox 420 PC (7) is also

connected to this power supply.

The USB interface N148/11 (9) serves as user interface for configuring the
EIB/KNX system. The Gateway IP Interface N 148/21 (12) connects the
GAMMA instabus with the Ethernet.

Setup

Micro Automation Set 28

Entry ID 23810653

The connector (11) connects the EIB/KNX data bus (10) with the CM
EIB/KNX communication module and the wave / instabus UP 140 coupler
(13) and the IP interface N148/21.

The DC 29V power supply for the EIB/KNX devices is provided by a
N 125/21 640mA

(8).

Figure

2-2

- +

DC24V+
DC24V-

SITRANS Probe LU

SIMATIC PXS300

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Note

Measuring the filling level in an oil tank requires using the SITRANS
Probe LU, as it is the only sufficiently Ex-protected ultrasonic sensor. In
this case, the wiring must be performed as described in figure 2-2 on the
left side.

If a water cistern is monitored instead of an oil tank, for example, the
more favorable ultrasonic sensor PXS300 can be used. The PXS300 can
directly connect to a 0 to 10V input of the LOGO! logic module. The
LOGO! AM2 expansion module is not necessary here. The inputs in the
LOGO!Soft Comfort program must be adjusted accordingly. The program
is commented at the respective locations. The wiring for the PXS300
ultrasonic sensor is described in figure 2-2 on the right side.

Note

The IP interface N148/21 (12) has no contact system EIB/KNX data bus
(10). The device can be installed directly at the internet connection
removed from other EIB/KNX components.

Note

For connecting the SITRANS probe LU (6) you use two sufficiently long
cables (1 to 2 m) to be able to test the functionality later without
problems.

Setup

Micro Automation Set 28

Entry ID 23810653

Network plan

Table

2-1

No.

1. Connecting the stations necessary for Micro Automation Set

28 to the internet requires respectively one internet
connection at all objects displayed in figure 2-3.
For safety reasons, the IP interface N148/21 should be
connected to the internet via a VPN connection

INTERNET

LAN

2. For testing and demonstrating the Micro Automation Set 28

the internet is replaced by a LAN as illustrated in figure 2-4.
All steps described in chapter 5 and 6 refer to networking
via a local LAN.

Figure

2-3

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Control Center

(MicroBox)

Client (PC)

Real Estate 1

IP Interface at

Router

IP address

???

DNS

???

Router at DSL

Fix IP / DNS

Router at DSL

Fix IP / DNS

Ethernet interface at

Router

IP address

???

DNS

???

Internet connection

dynamic IP

Ethernet

interface at

Router

IP address

???

DNS

???

INTERNET

Figure

2-4

Control Center (MicroBox)

Client (PC)

Client (mobile)

Real Estate 1

IP Interface at

LAN

IP address

192.168.1.2

DNS

255.255.255.0

LAN

Ethernet interface

(Port1) at

LAN

IP address

192.168.1.1

DNS

255.255.255.0

Ethernet

interface at

LAN

IP address

192.168.1.3

DNS

255.255.255.0

W-LAN interface at

Access Point

IP address

192.168.0.4

DNS

255.255.255.0

HotSpot/

Access Point

t di

spl

aye

Hardware and Software Components

Micro Automation Set 28

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Hardware and Software Components

Products

Table

3-1

Component

No.

MLFB / Order number

Note

LOGO! Power 24V 2.5A

6EP1332-1SH42

LOGO! 12/24RC

6ED1052-1MD00-0BA5

LOGO! communication
module
CM EIB/KNX

1 6BK1700-0BA00-0AA1

LOGO! AM2 expansion
module

1 6ED1055-1MA00-0BA0 not applicable

when using
PXS300

SITRANS Probe LU and
hand-held programming
device

7ML5221-1AA11 and
7ML5830-2AH

SIMATIC PXS300

3RG6013–3RS00

Alternative to
SITRANS
Probe LU

SIMATIC Microbox PC
420

1 6AG4040-0AA30-0AA0 See note

Power supply
N 125/21, 640mA

1 5WG1125-1AB21

IP interface N148/21

5WG1148-1AB21

USB interface N148/11

5WG1148-1AB11

Door/window contact
GAMMA wave AP 260
with battery

1 5WG3260-3AB81

Koppler wave / instabus
UP 140

1 5WG3140-2HB11

UP 114 bus connector

5WG1114-2AB02

Note

The listed order number of the SIMATIC Microbox 420 contains the
following system configuration:

Celeron 400MHz, 100MHz FSB; 512MB SDRAM-133; 40GB HDD EIDE;
Windows XP embedded incl. SP2.

The system data can be adjusted under the following address:

https://mall.automation.siemens.com

There you select your language and select the “Products“ option in the
primary navigation. In “Product Tree Siemens A&D “ you navigate to
Automation Systems > SIMATIC industrial PCs > SIMATIC Box PC >
SIMATIC Microbox PC 420 and activate the ”Configurators“ tab.

Hardware and Software Components

Micro Automation Set 28

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Accessories

Table

3-2

Component

No.

MLFB / Order number

Note

Data rail 190 with connector

5WG1190-8AB02

Bus terminal 193, 2-pole, 4x

5WG1193-8AB01

25 ea.

Cover strip 192, 242 mm

5WG1192-8AA01

Top-hat rail for LOGO!, 483 mm

6ES5710-8MA11

LOGO! PC cable

6ED1057-1AA00-0BA0

Line protection switch

5SX2116-6

1 pole B,
16A

Top-hat rail for EIB/KNX
components, TH35-7,52
according to DIN EN50022

1 Specialist

dealer

Bus line for EIB/KNX,
YCY 2x2x0.8 green R/100

Specialist

dealer

Frame simple for UP140

5TG2551-0

Configuration software/tools

Table

3-3

Component

No.

MLFB / Order number

Note

LOGO!Soft Comfort

6ED1058-0BA01-0YA0

USB cable (type A –
type B)

1 Specialist

dealer

ETS3 Professional
Version 3.0d

http://www.konnex.org/knx-tools/

IPAS ComBridge Studio
Suite/Core and Webtab
Services

http://www.ipas-products.com

Registration at the “Customer Service“
necessary;
requires the license “Core and Webtab
Services“ for the following quantity framework
• Routers/Virtual Device: 1
• Client Manager/WebTab: 1

Note

Networking the Ethernet components in LAN requires a switch with at
least 3 ports.

Function Principle

Micro Automation Set 28

Entry ID 23810653

4 Function

Principle

4.1

Recording measured values

4.1.1

Record filling level in oil tank using the SITRANS Probe LU

Table

4-1

No.

Function

Note

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1. The SITRANS Probe LU is a

configurable measuring device for
continued filling level recording
using ultrasonic technology. In this
Micro Automation Set 28 the
measuring device is configured so
that the filling level (not the
distance) is output in relation to a
maximum height of the liquid.
The minimum distance between the
liquid surface and bottom of the
sensor is 30cm.

Min. 0,30 m

4,32 M

4 bis 20 mA

2. In the 4/20 mA standard the

measured filling level is transmitted
to the LOGO! AM2 expansion
module.

0-6 Meter

4-20 mA

0-600 cm

4,32m

14,4mA

432cm

3. Das LOGO! AM2 expansion module

has a 0/20 mA interface. Das
LOGO! logic module scales the
analog value from 0 to 600
centimeter

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.1.2

Record status of doors and windows with GAMMA wave AP 260

Table

4-2

No.

Function

Note

)

4. The door/window contact GAMMA

wave AP 260 is a surface-mounted
device with integrated radio
transmitter. The device
automatically recognizes opening
and closing of doors and windows.
The device must be attached
directly at the top edge of the door
or window.

Radio sensor with
integrated reed contact

Magnet

Uni-directional radio
signals in 868 Mhz
frequency range

5. The door/window contact contains a

reed relay. It consists of two
contacts sealed within a glass bulb
which close when a magnetic field
is applied.

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Max 10mm
Min 3mm

6. Magnet and radio sensor must be

fitted at a minimum distance of 3mm
and a maximal distance of 10mm
from each other at the door or
window.

7. On the side of the GAMMA instabus

network, a wave / instabus UP 140
coupler receives the radio signal
and transforms it into an electrical
signal according the EIB/KNX
specification.

)

8. The door/window contact module

GAMMA wave AP 260 distinguishes
three telegrams sent to the GAMMA
instabus

• Door/window was closed
• Door/window was opened
• Reporting the battery status

(every 24 h)

9. Using the configuration software

ETS teaches all available telegrams
at the wave / instabus UP140
coupler.

Telegrams which are not used can
simply be omitted.

10.

• During sending a telegram, the

LED of the door/window contact
briefly lights up.

• When a telegram is received,

the LED of the wave / instabus
UP140 coupler briefly lights up.

)

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.2

Display values measured locally in the LOGO! logic module

Table

4-3

No.

Function

Instructions

1. Some message texts have been

implemented in the LOGO! logic
module for local visualization of the
filling level.

A message text is permanently
displayed and three messages
appear depending on the current
filling level.

2. Permanent message text

The permanently displayed
message text contains the current
filling level (in meters) of the oil
tank. This message text has the
priority 0.

Prio0

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3. Dynamic message texts

The dynamic message texts appear
depending on the current filling level
in the oil tank. These message texts
have the priority 1 to 3 and are
displayed above the permanent
message text.

<0.20m

<1.50m

>4.00m

Filling

vel

Prio1

Prio2

Prio4

4. Next to the display of the message

texts, the threshold value signals
are output at three digital outputs of
the LOGO! logic module.

Threshold

value

Output

0 < 0.20 m

0.20 < 1.50 m

4.00 < 6.00 m

5. Several signal lamps are connected

to the three digital outputs, which
gives the person filling the tank the
following information:
• Filling level: empty (1)
• Filling level: almost empty (2)
• Filling level: overfilled (3)

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.3

Integrating components into the GAMMA instabus network

4.3.1

Addressing inputs/outputs of LOGO!

Table

4-4

No.

Function

Note

6. The communication module

CM EIB/KNX enables
communication between LOGO!
logic module and EIB/KNX network.
As a bus node at EIB/KNX the
LOGO! logic module is enabled to
exchange EIB/KNX telegrams with
other EIB/KNX devices or other
LOGO! logic modules.

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7. The following resources of the

LOGO! logic module can be used
via the GAMMA instabus:
• Digital

inputs

• Digital

outputs

• Analog

inputs

• Analog

outputs

• Parameters in the user program

of the LOGO! logic module
cannot be accessed.

• Access to the LOGO! logic

module by LOGO!Soft Comfort
via GAMMA instabus is not
possible.

8. Before the individual inputs and outputs are addressed, the resources must

be distributed. The virtual resources in the GAMMA instabus and the
physically available inputs/outputs of the LOGO! logic module are assigned
using the configuration software ETS and are adjusted manually.
The total of virtual and physically available resources always amounts to
the maximum upgrade of a LOGO!.

8/4 on LOGO! and 16/12 on EIB

4 DO (DO1-4), LOGO! side
8 DI (DI1-8); LOGO! side

12 DO (DO5-16), EIB side
16 DI (DI9-24); EIB side

10. The ETS configuration displayed at no. 4 is used in

Micro Automation Set 28. It represents the following hardware setup.

Function Principle

Micro Automation Set 28

Entry ID 23810653

No.

Function

Note

11.

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LOGO! 12/24 RC

AM2

Configuration of MAS 28 with all
physically available
inputs and outputs.

CM EIB/KNX

Virtually provided
input and outputs via
GAMMA instabus EIB.

DI9 to 24
DO5 to 16
AI5 to 8
AO1 to 2

12. In order to activate a motor

connected to the digital output DO1,
a virtual input (here I9) from the
GAMMA instabus must be
connected with the physical output
DO1 in the LOGO! user program.

LOGO! 12/24 RC

AM2 CM EIB/KNX

13. To activate a light in the GAMMA

instabus

via the LOGO!, a physical

input (here DI1) must be connected
with a virtual output (here DO%) in
the LOGO! user program.

DO5

LOGO! 12/24 RC

AM2 CM EIB/KNX

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.3.2

Exchanging analog values between LOGO! and EIB/KNX

Table

4-5

No.

Function

Note

1. Analog values exchanged between

LOGO! logic module and GAMMA
instabus

network are, as a

standard, interpreted as percentage
or floating point values. All
measured values have been
parameterized as percentage
values in ETS3. Switching from
percentage value to floating point
value must occur manually.

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Analog output used in MAS28 (filling level)

Not used second analog output

Floating-point value

Percentage value

2. For transmitting the actual analog

value, the virtual analog output in
the ETS configuration software
must be parameterized as floating-
point value.

Data type

Analog output at group address (1/1/1)

3. The analog output configured as

floating-point value can also be
specified further. Various measured
values such as temperature, speed,
seconds, etc., can be specified.

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.3.3

Addressing of GAMMA instabus components

Table

4-6

No.

Function

Note

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1. A GAMMA instabus network

consists of several areas (B), lines
(L) and nodes (TLN). In this Micro
Automation Set 28 the following
assignment is used:
• B: building (real estate)
• L:

floor

• TLN:

device

TLN

2. To be able to uniquely identify each

node in the GAMMA instabus
network, a physical address is
assigned for each device. The
physical address can be derived
from the topology described at no.1.
This physical address is assigned to
the device via the ETS configuration
software.

Node 3/ Device 3(LOGO!)
Line 1/ Cellar
Function area 1/ Real estate 1

3. A device-dependent number of

inputs and outputs is available for
each configured node. The number
of inputs and outputs is
automatically determined and
inserted by the ETS configuration
software according to the specified
device. The inputs and outputs are
referred to as communication
objects.

TLN

Communication objects

4. To be able to use a communication

object of the node, a group address
is assigned to it.
The group address defines a
function (e.g. switching staircase
light on). The respective
communication objects determine
the stations for this function.

Attention

: The group address

differs in writing by the slashes “/“ in
front of the physical address, which
is written with “.“.

Function Principle

Micro Automation Set 28

Entry ID 23810653

No.

Function

Note

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5. If only one communication object

(2) is assigned to one group
address (1), the respective
communication object is activated in
the GAMMA instabus. This means,
that the electrical signals are
assigned to the bus line. There is no
particular assignment to any other
communication object.
This function, however, is
insufficient for visualizing, for
example, the analgog value A1 of
the LOGO! in the IPAS ComBridge
Studio

Grp. Addr.

E13

Shutter3

Light5

Shutter8

Light1

LOGO!

LOGO!

Comm. objects

6. If several (min. two)

communication objects (2) are
assigned to one group address (1),
communication between two exactly
specified stations is possible.
Using this function, for example via
the input E13 of LOGO!, Light5 can
be activated in the GAMMA
instabus

network.

Grp. Addr.

E13

Rollade3

Licht5

LOGO! E13

Licht1

Rollade8

LOGO!

Komm. Objekte

Licht5

EIB!

4.4 Connecting

GAMMA

instabus with Ethernet

Table

4-7

No.

Function

Note

1. The IP Interface N148/21 serves as

an interface between GAMMA
instabus

networks or other data

processing devices using the
internet protocol. The IP Interface
N148/21 offers the option of
visualizing all input/output signals of
the LOGO! logic module on the PC.

ETHERNET

2. The IP Interface 148/21 must be

considered as a bus connector. All
signals pending at the EIB/KNX
bus-internal interface are converted.

In the ETS configuration software
an IP address is assigned to the IP
Interface 148/21.

Function Principle

Micro Automation Set 28

Entry ID 23810653

4.5

Visualizing the measured values transmitted via
Ethernet/Internet

The visualization software IPAS ComBridge is used for visualizing the
measured values in the control room (SIMATIC MicroBox PC 420). In this
Micro Automation Set 28 only parts of the functionalities are discussed.

Figure

4-1

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CBS C

tro

Core Services

OPC Engine

OPC Service

Visual Director

WebTab

Service

WebAccess

Engine

e-Mail

Service

Automation Engine

Database

Service

Scheduling

Service

Visual

Director

InfoPoint

Configurator

Configuration

Manager

Tools

Application

Core and WebTab Services bring
the EIB system to the DV network
and enables a fast table visualization

Automation Services execute
Automation functions directly
From the ComBridge Studio
Server PC: time relevant jobs,
e-mails and data base entries
using data analysis and
reporting

The OPC Service combines the
EIB with OPC Client systems

Visual Director is a complete
Web visualization with user
authentication, own navigation
structure and randomly placable
EIB display and control elements

Used in Micro Automation Set 28

Table

4-8

No.

Function

Note

3. All gateways to the GAMMA

instabus

networks are assigned to

the control room via the
Configuration Manager. In the
Configuration Manager one entry
with IP address is generated for
each device.

IP Interface 1

IP Interface 2

IP Interface 3

4. The variables are generated via the

InfoPoint Configurator. The path of
the variable is the gateway entry
with attached group address. The
group address is taken from the
ETS configuration.

Gateway address Group address

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

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Configuring the Startup Software

5.1 Preliminary

remark

For the startup we offer you software examples with test code and test
parameters as download. The software examples support you during the
first steps and tests with your Micro Automation Sets. They enable quick
testing of hardware and software interfaces between the products
described in the Micro Automation Sets.

The software examples are always assigned to the components used in the
set and show their basic interaction. However, they are not real applications
in the sense of technological problem solving with definable properties.

5.2

Download of the startup code

The software examples are available on the HTML page from which you
downloaded this document.

Table

5-1

No.

File name

Content

1 MAS28_ETS3_project_V1d0.pr4

Project file for ETS 3
Professional.

2 Set28_LOGO!_V1d0_en.lsc

Project file for
LOGO!Soft Comfort.

3 MAS28_CBCM_config_V1d0.csl

Configuration file for the IPAS
ComBridge Studio
Configuration Manager

4 MAS28_ETS3_project_db_V1d0.esf

Data base for the OPC
Server IPAS ComBridge
InfoPoint

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

5.3 Configuring

Components

Note

It is assumed here that the necessary software has been installed on
your computer and that you are familiar with handling the software.

5.3.1

Installing, wiring and networking the hardware

Table

5-2

No.

Instructions

Note

1. Installing the components from chapter 3

to the top-hat rail.

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2. Plug the LOGO! expansion module into

the LOGO! logic module and clip it in (see
note).

Wire all components.

See chapter 2

Using the provided program
components requires following to the
topology and IP addressing from
chapter 2.

4. Wire

all

components.

Switch on the power supply of all devices.

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

5.3.2

Configuring SITRANS Probe LU

Table

5-3

No.

Instructions

Note

1. Ensure that the display at the SITRANS

Probe LU has been activated.

(

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c %

▓

┴

▲ ▼

2. Use a hand-held programming device for

programming the ultrasonic sensor.

3. Leave the “RUN“ mode and activate the

“Configuration“ mode.

Step

Button

Function

Start configuration
mode

Select the parameter P001.

Step

Button

Function

Select P001.

▓

Set value to ”1“.

Step

Button

Function

Value input

Acknowledge

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

Configure the further values P002 to
P007. Proceed as described in no.4 and
5.
• P002:

• P003

• P005:

• P006:

6.000

• P007:

5.725

All parameters are explained in the
manual of the SITRANS Probe LU.

http://support.automation.siemens.com/W
W/view/de/19101050

(German)

http://support.automation.siemens.com/W
W/view/en/19101050

(English)

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7. Quit the configuration mode and start the

”RUN“ mode.

Step

Button

Function

Start “RUN“ mode

After the here described configuration of the SITRANS Probe LU the
current filling level is output in meters as 4 to 20 mA signal. The
SITRANS Probe LU offers a number of further functions such as the
automatic volume calculation depending on the tank shape used. The
parameters required for this are available in the manual (chapter
”Parameter Description“).

http://support.automation.siemens.com/WW/view/de/19101050

(German)

Note

http://support.automation.siemens.com/WW/view/en/19101050

(English)

5.3.3

Configure GAMMA instabus components

Table

5-4

No.

Instructions

Note

1. Connect the PC to the USB to the USB

interface N148/21 using the USB cable.

Open the configuration software ETS.

3. Import the *.pr4 file via “File/Import“.

4. Open the Project Management via

“File/Open(/)Manage Projects“

Select the Micro Automation Set 28
project (1) and acknowledge with
“Open“

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

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5. Switch on the power supply of the

hardware components.

6. To follow the steps below, the following

options should be set in your ETS
configuration software under
“View/Project-Views“

• Buildings: deactivated (1)
• All Devices: deactivated (1):
• Topology: deactivated (1):
• Group Addresses: deactivated (1):
• Project Root: activated (2)
The entire project is now displayed in one
window.

7. Switch the access point for the connection

with EIB to USB. Change to the
communication menu
“Extras/Options/Communications“
. Open the ETS connection manager via
the “Configure Interfaces“ button
(1). Create a new connection via the
“New“

(2) button and select the following

parameters.
• Name

(3):

”USB“

• Type (4): ”USB“
• USB Device (5): KNX/EIB-USB

interface

Acknowledge all windows with "Ok".

8. Establish the connection with the GAMMA

instabus

network.

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

9. Load the physical address into the USB

interface N148/11.
• Select device “1.1.1 Interface N

148/11 USB” (1) and press the
“Download“

button (2).

• Checkmark

”Local“

checkbox (3).

• Now press the “Program

Individual Address“

button (4).

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10.

Now load the physical address and the
user program to the remaining stations
Select building “Real estate 1” (1) and
press the “Download“ button (2).

11.

Load the physical address including the
application program (2) into the devices
(3) via the bus (1).

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

Then follow the instructions in the
program routine.

12.

• The physical address of the USB

interface N 148/11 was already
assigned. Cancel the download
process.

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• Programming head at IP Interface

N 148/21 (left top, button at the
indention below the LED)

• Press the programming button at

communication module CM EIB/KNX
(marked as ”Prog. ↓“, second terminal
from the bottom, second terminal from
the right)

• For the UP 140 coupler, the button

must be kept pressed for 10 seconds
until the LED lights red.

The download of the application program
is started automatically.

IP interface N148/21

CM EIB/KNX

Wave / instabus UP 140 coupler

13.

Close the ETS configuration software.

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

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5.3.4

Configuring IPAS ComBridge Studio

WARNING

A correctly configured SIMATIC Microbox PC 420 is assumed. The
license for the IPAS ComBridge visualization software is necessary
for further proceedings. Please use the standard installation paths
in all cases.

Note

The installed Apache web server requires a sufficiently large swap file.
During creating the Micro Automation Set 28 a swap file larger than
400MB was used. Additionally, the swap file was moved to the larger
partition D:\. It is recommended to make the same settings.

Note

The installation of IPAS ComBridge on a SIMATIC Microbox PC 420
using Microsoft XP embedded operating system may cause errors during
the installation of Java RE. In this case you install the current Java RE
version from 1.5.0.X manually.

http://java.sun.com/

Table

5-5

No.

Instructions

Note

1. Install all components of the IPAS

ComBridge Studio Suite.

The installation file is available at

http://www.ipas-products.com

A registration at the ”Customer Service“ is
necessary. The license “Core and Webtab
Services“ is required for the following
quantity framework
• Routers/Virtual Device: 1
• Client Manager/WebTab: 1

2. Connect an Ethernet cable at the Ethernet

port 1 of the SIMATIC Microbox PC 420,
to install the topology described in chapter
2 (green line).

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

3. Set the IP-address as described in

chapter 2.

4. Open the “CBS Control Center“ on your

SIMATIC MicroBox PC 420.

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Start (1) all necessary services (2).

6. Start the Apache web server. Click the

Apache icon with the left mouse button.
Now select the ”Start“ option from the
”Apache/Start“

menu.

7. Open the ComBridge Studio

Configuration Manager via ”CBCM“.

8. Import the *.csl configuration file via

“File/Import“

Successful connection with IP Interface N
148/21:

Successfully started client:

At connected and correctly configured IP
Interface N 148/21 the connection with
this device is now established
automatically.

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

10.

Save the configuration via “File/Save
as“

and close the ComBridge Studio

Configuration Manager.

Attention

: When closing the ComBridge

Studio Configuration Manager make sure
to acknowledge the information window
with “OK”. The info-window appears in the
background and is mostly covered by
other programs.

11.

Open the InfoPoint Configurator via
”InfoPoint“.

12.

Open the Project Manager dialog.

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13.

Add a new project with the ”Add“ (1)
button. Assign your own project name (2)
and acknowledge with ”OK“ (3). Mark the
checkbox in front of your project name (4)
and acknowledge with ”Close“ (5).

14.

To generate the database for the Micro
Automation Set 28, open the
“Properties Dialog“

via ”Set

Properties“

15.

Import the *.esf database in the
”IB Data“

(1) menu via

”Open Exp. Data“

(2) and

acknowledge with ”OK“ (3).

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

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16.

Change to the “Web Editor“ view.

17.

Delete all default objects contained in the
InfoPoint via the ”Delete Row“ button
(1). Now add the database of the Micro
Automation Set 28 via Drag&Drop. Drag
the main group “Real estate 1“ (2) to the
window ”Webtab Editor“ (3).
The address of the objects (4) should now
have the following format: “IP Interface
N148:1/X/Y“. If this formatting starts with
the term “Gateway…“ right-click the main
group “Real estate 1“ and acknowledge
with the ”Reload“ button in the popup
menu.

18.

Save your InfoPoint configuration and
close the InfoPoint Configurator as well as
the ”CBS Control Center“.

5.3.5

Configuring the Apache Webserver

To be able to access the just configured database of the IPAS ComBridge
Studio visualization software, the Apache Webserver must be configured.

Table

5-6

No.

Instructions

Note

1. Open the ”CBS Control Center“ at the

SIMATIC MicroBox PC 420.

2. Open

the

“InfoPoint Configurator“.

Open the Project Manager dialog.

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

4. Select your project name (1) and activate

the checkbox ”WebTab“ (2). Press the
“Export“ (3) button and save the *.js file in
the default directory under any name.
Press “Close“ (4).

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5. Close the “InfoPoint Configurator“ and the

”CBS Control Center“.

6. Navigate to the folder “C:\Program

Files\Ipas GmbH\ComBridge
Studio\Webtab“ (1). Open the
“WebAccess.html“ (2) with a text editor.
(e.g. notepad)

7. Replace the default applet names with

those previously generated by you (3).
Save the file and close.

8. Navigate to the folder “C:\Program

Files\Ipas GmbH\ComBridge Studio
Web\__vhosts “ (1). There you create a
configuration file. To do this click the right
mouse button and generate a text file via
”File\New\Text Document“

and then

you change its ending to .conf (2).

Configuring the Startup Software

Micro Automation Set 28

Entry ID 23810653

Open this file with the text editor. Add the following entries to the Apache configuration
file.

• (1): Via this port the Apache Webserver accesses the HTML page with the

integrated Java Applet. (49900 – 65535). Please note, that the “__vhosts“ folder
must not contain configuration files with the same port address.

• (2): Here the directory is specified where the HTML page (WebAccess.html) is

located.

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10.

Restart the Apache web server. Click the
Apache icon with the left mouse button.
Now select the ”Start“ option from the
”Apache/Start“

menu.

11.

Close all opened programs at the
SIMATIC MicroBox PC 420.

5.3.6

Configuring the LOGO! logic module

Table

5-7

No.

Instructions

Note

1. Connecting the PC with the LOGO! logic

module at COM 1 via the LOGO! PC
cable.

LOGO! PC cable

Configuration PC

2. Open the *.lsc file with LOGO!Soft

Comfort.

3. Transfer the project into the LOGO! logic

module via ”Tools/Transfer/PC ->
LOGO!“

4. Set the LOGO! logic module into “RUN”

mode.

Live Demo

Micro Automation Set 28

Entry ID 23810653

6 Live

Demo

The functions and features of the Micro Automation Set 28 are displayed in
form of an example application for better understanding.

If the components have been correctly configured as described in chapter
5.3, the functionalities and features of program code and hardware can be
tested as follows.

Figure

6-1

Live Demo

Testing the Communication

(Chapter 6.1)

General Operation Notes

(chapter 6.2)

Scenarios

(Chapter 6.3)

6.1

Testing the communication paths

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The button at the wave/instabus UP 140 coupler serves for a quick function
testing of the GAMMA instabus communication
• with the LOGO! Logic module
• with the IPAS ComBridge Suite via IP Interface N 148/21

Testing the GAMMA instabus network

Table

6-1

No.

Instructions

Note

1. The button at the wave/instabus UP 140

coupler has been installed in ETS as a
button.

Start

On
Off

Status

2. During a value change, the status of the

button is transmitted to the LOGO! via the
GAMMA instabus. At a positive edge a
counter starts in the LOGO! logic module,
which appears on the display.

Status

On
Off

3 sec.

Counter to 3 sec.

3. The counter appears for three seconds.

The successful starting of the counter is
an indication of the GAMMA instabus
functioning up to the LOGO! logic module.

Live Demo

Micro Automation Set 28

Entry ID 23810653

Testing connectivity of IP Interface and IPAS ComBridge Studio

Table

6-2

No.

Instructions

Note

1. Open the “CBS Control Center“ on your

SIMATIC MicroBox PC 420. Enter “cmd“
via “Start/Run“ and confirm with OK.

2. Test the connection with the IP Interface

N 148/21 via the command
”ping 192.168.1.2“.

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- +

3. At the IP Interface N 148/21 you see the

respective Tx-LED light up for each of the
four ping commands.
If the LED lights as described, this is an
indicator for a functioning Ethernet
network.

- +

4. Pressing the wave/instabus UP 140

coupler button causes the line LED to
light up.
If the LED blinks as described, this is an
indicator for a correct connection of the
IP Interface N 148/21 to the GAMMA
instabus

network.

Note

The procedure described here can also be used for testing your
client PC.

Live Demo

Micro Automation Set 28

Entry ID 23810653

6.2

General operating notes

6.2.1

Simulate filling level in the oil tank

Table

6-3

No.

Instructions

Note

1. To simulate the filling level in the oil tank,

hold the SITRANS Probe LU vertical to an
even base and reduce or increase the
distance.
• To

increase

the simulated filling level,

the distance between base and
SITRANS Probe LU must be reduced

• To

reduce

the simulated filling lever,

the distance between base and
SITRANS Probe LU must be
increased

90°

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(

▓

Filling height in meter

2. To provoke an alarm message in the

LOGO! logic module, you simulate a
certain filling level of the oil tank.
• 0.00 to 0.20 meter
• 0.20 to 1.50 meter
• 4.00 to 6.00 meter

6.2.2

Simulating closed or opened entrance door

Table

6-4

No.

Instructions

Note

1. Simulate opening or closing the entrance

door. Remove the magnet from the
door/window contact and move the
magnet close to the contact again.

)

2x blinking

2. The red LED at the door/window contact

blinks twice and signals, that the
telegrams were sent to the
wave/instabus UP 140 coupler.

3. At the wave/instabus UP 140 coupler, the

blinking of the red LED twice signals that
the telegrams were received
successfully.

)

2x bliking

Live Demo

Micro Automation Set 28

Entry ID 23810653

6.2.3

Displaying filling level and threshold value at the LOGO! logic module

Table

6-5

No.

Instructions

Note

1. The LOGO! logic module permanently

shows the current filling level and the test
counter level (see chapter 6.1).

Current filling level in meter

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Current status of oil filling level

Minimal and maximal filling level
used for this threshold value (m).

2. If a threshold value is exceeded/short of

due to a change in filling level, the
respective warning relating to the
threshold value is indicated. The warning
and the filling level display from no.1 are
alternately displayed every two seconds
until the filling level has reached the
normal state (filling level meets no
threshold value).

6.2.4

Visualization with IPAS ComBridge Studio at the server

Table

6-6

No.

Instructions

Note

1. To display the measured values at your

server, start the ”CBS Control Center“ on
your SIMATIC MicroBox PC 420.

2. Open

the

“InfoPoint Configurator“.

Change to the “Web Editor“ view.

4. Start the generation of a JAVA applet via

the “Start Applet“ button.

Live Demo

Micro Automation Set 28

Entry ID 23810653

No.

Instructions

Note

Column 1

Column 2 Column 3 Column 4

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6. The generated Java applet automatically displays all configured variables and provides

functions for operation.
• (Column 1): name of the group addresses assigned in ETS
• (Column 2): address of the communication objects (IP Interface + group address)
• (Column 3): current value of the configured variables. The display varies

depending on the configured data type. (For a bit-by-bit display: GRAY Æ not yet
updated since the start of the Java applets, BLACK Æ out, YELLOW Æ on)

• (Column 4): Operating elements. The display varies depending on the configured

data type.

• (1): changes the status by pressing the button at the wave/instabus UP 140

coupler

• (2): changes the status for opening / closing the GAMMA wave AP 260

door/window contact

• (3): outputs the current value of the filling level sensors in meters. The value is

updated for value changes.

• (4): Here output Q4 can be set manually to simulate an error.

6.2.5

Visualization by IPAS ComBridge Studio at a PC in the network

Table

6-7

No.

Instructions

Note

1. Open the Internet Explorer at the

client PC. Now you can access the
Apache Webserver via yourlocal LAN.
• (1) Access to the HTML page of the

control center with Apache
Webserver.

• (2): Operator view see description

Table 6-6, no. 5-6.

Live Demo

Micro Automation Set 28

Entry ID 23810653

6.3 Scenarios

The scenarios of this chapter describe how the functionalities of the Micro
Automation Set 28 can be illustrated with the automation task. The general
operation of the devices is described in chapter 6.2.

6.3.1

Simulating and visualizing the filling level of the oil tank

Table

6-8

No.

Step

Note

2. Bring the SITRANS Probe LU into

position so that the display at the
measuring device balances between
1.50 m and 4 m.

(

▓

3. The status of the oil filling levis is OK. At

the LOGO! logic module the current filling
level is permanently displayed.

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4. Simulate the filling of the oil tank by

reducing the distance between bottom
and sensor. The display at the SITRANS
Probe LU must display more than 4 m
filling level.

(

▓

5. The status of the oil tank has now

changed to ”overfilled“. At the LOGO!
logic module, the permanent filling level
display is now alternately displayed with
the warning ”Tank overfilled“. Additionally,
the output Q3 is activated until the oil tank
filling level drops back down to 4 meter.

3 seconds

Oil tank fill level in meter

6. Change to your Client PC to access the

Apache Webserver via the Internet
Explorer. Now you can monitor the
current filling level via the Ethernet
network.

Live Demo

Micro Automation Set 28

Entry ID 23810653

6.3.2

Simulating and visualizing door status (open/closed)

Table

6-9

No.

Step

Note

7. Change to your Client PC to access the

Apache Webserver via the Internet
Explorer. Observe the output field “Door
status detection“.

8. Remove the magnets from the GAMMA

wave AP 260 door/window contact to
simulate an open entrance door.

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9. At the Internet Explorer you can see how

the output field changes from gray or
black to yellow.

10.

Move the magnets to the GAMMA wave
AP 260 door/window contact to simulate a
closed entrance door.

11.

At the Internet Explorer you can see how
the output field changes from yellow to
black.

Live Demo

Micro Automation Set 28

Entry ID 23810653

6.3.3

Simulating a plant error at the LOGO! logic module

Table

6-10

No.

Step

Note

12.

Change to your Client PC to access the
Apache Webserver via the Internet
Explorer. Press the “On“ button in the
”failure lamp 1(Q4)“ line to simulate a
plant error at the LOGO! logic module.

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13.

Output Q4 at the LOGO! logic module is
activated. A small clicking sound can be
heard.

14.

The output area changes from gray or
black to yellow.

Technical Data

Micro Automation Set 28

Entry ID 23810653

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7 Technical

Data

LOGO! Power 24V 2.3

Table

7-1

Criterion

Technical data

Additional note

Supply voltage

85 to 264 V AC

Output voltage

DC 24 V (setting range DC
22.2 to 26.4 V)

Output current

2.5A

Dimensions (W x H x D) in
mm

72 x 90 x 55

LOGO! 12/24 RC

Table

7-2

Criterion

Technical data

Additional note

Supply voltage

10.8 V to 28.8 V DC

Digital inputs

I5, I6: High-speed counters
I7, I8: also used as analog
input (0-10V)
(I7 = AI1, I8 = AI2)

Digital outputs

4 relays

No short-circuit protection,
external fuse necessary

Clock (Time switch)

Available (date / time)

Dimensions (W x H x D) in
mm

72 x 90 x 55

LOGO! CM EIB/KNX

Table

7-3

Criterion

Technical data

Additional note

Supply voltage

DC 24 V

Inputs, max.

16 DE, 8 AE

Virtual

Outputs, max

12 DA, 2 AA

Virtual

Dimensions (W x H x D) in
mm

36 x 90 x 55

Technical Data

Micro Automation Set 28

Entry ID 23810653

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SITRANS Probe LU

Table

7-4

Criterion

Technical data

Additional note

Supply voltage

24 V DC

For transmission in mA/HART

Measuring range of sensor

0.25 to 6 m

measuring range mA/HART

4 to 20 mA

Precision of sensor

± larger value of 0.15% of the
measuring range or 6 mm
(0.24”)

Precision mA/HART

± 0.02 mA

Temperature compensation

Yes, integrated

Protection system

Casing IP67/IP68, Type 4X/
NEMA 4X, Type 6/NEMA 6

SIMATIC Microbox PC 420

Table

7-5

Criterion

Technical data

Additional note

Supply voltage

24 V DC

Processor

Celeron 400MHz, 100MHz
FSB,Profibus DP12

configuration possible

Main memory

512MBYTE SDRAM-133
(1x512MB)

configuration possible

Storage

40GB HDD EIDE

configuration possible

Operating system

Windows XP Professional

configuration possible

Dimensions (W x H x D) in
mm

262 x 134 x 52

GAMMA instabus power supply N125/21

Table

7-6

Criterion

Technical data

Additional note

Supply voltage

120 to 230 V AC

permitted range AC 102 to
253 V

Output voltage

29 V DC

permitted range DC 28 to
30 V

Output current

640 mA

Technical Data

Micro Automation Set 28

Entry ID 23810653

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GAMMA instabus IP Interface N 148/21

Table

7-7

Criterion

Technical data

Additional note

Supply voltage

24 V DC

permitted range DC 12 to
30 V

Interfaces

• EIB/KNX bus terminal

(black-red)

• Supply voltage (yellow-

white)

• RJ45

female

connector

GAMMA instabus USB interface N 148/11

Table

7-8

Criterion

Technical data

Additional note

Supply voltage

29 V DC

Interfaces USB

interface

Transmission rate

max. 12 Mbit/s

GAMMA wave AP 260 door/window contact

Table

7-9

Criterion

Technical data

Additional note

Power supply

Lithium battery, ½ AA 3.6V

e.g. sunshine type SL-750,
life approx. 5 years

Radio range

Approx. 100 m open space

Frequency band

868 MHz

KNX-RF standard

Dimensions (W x H x D) in
mm

• Sensor: 87 x 36 x 27
• Magnet: 40 x 10 x 10

GAMMA instabus wave / instabus UP 140 coupler

Table

7-10

Criterion

Technical data

Additional note

Power supply

29 V DC

Via user interface of the UP
114 bus connector

Radio range

Approx. 100 m open space

Frequency band

868 MHz

Dimensions (W x H x D) in
mm

55 x 55 24

Technical Data

Micro Automation Set 28

Entry ID 23810653

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LOGO!Soft Comfort V5.0

Table

7-11

Criterion

Technical data

Additional note

Program representation

Functional plan, contact plan

Simulation Yes

without

hardware

Online test

Yes

with connected hardware

Languages

6 languages (G,E,F,S,I,P)

Required operating system

WIN98SE/
NT4.0/ME/2000/XP,MAC OS
X,LINUX

Runnable on any Linux
distributions, on which Java 2
SDK Version 1.3.1 runs

LOGO!Soft Comfort V5.0

Table

7-12

Criterion

Technical data

Additional note

Program representation

Functional plan, contact plan

Simulation Yes

without

hardware

Online test

Yes

with connected hardware

Languages

6 languages (G,E,F,S,I,P)

Required operating system

WIN98SE/
NT4.0/ME/2000/XP,MAC OS
X,LINUX

Runnable on any Linux
distributions, on which Java 2
SDK Version 1.3.1 runs

Document Outline

Table of Contents
1 Application Areas and Usage
2 Setup
3 Hardware and Software Components
4 Function Principle
5 Configuring the Startup Software
6 Live Demo
7 Technical Data

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