18. Longituds del cablatge 350 m 350 m 300 m Separació màxima entre dispositius de 700 metres. Longitud màxima total de 1000 metres. Distància màxima entre una font d'alimentació i un dispositiu de 350 metres
19. Àrea KNX Area F.A. F.A. F.A. A.L. A.L. Línea principal 1.0 Línea 1 Línea 15 L1 L15 1.15.1 1.15.63 1.1.1 1.1.63 1.1.0 1.15.0
20.
21. Sistema o món KNX 3 4 5 6 7 8 9 10 11 12 13 14 15 Area línea 0.0 Línea principal 1.0 Línea 1 Líniea 15 LK1 LK15 1.15.1 1.15.63 2 1.1.1 1.1.63 1.1.0 1.15.0 Area 1 BK1 1.0.0
22.
23. Adreces Físiques Actuator Sensor Actuator EMO Fuse Fuente de alimentacion 1.1.3 Bus 230V 1.1.1 1.1.2 1.1.4
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25. Adreces de grup Bereich Línea principal Línea 1 LK1 LK2 Pulsador 1 Luz 1 1/1/2 A 1/1/1 1/1/1 S 1.1.1 1.1.2 1.2.1 A 1/1/2 1.2.2 S 1/1/2 Detector movimiento Luz 2 Line 2 Direcciones de grupo en tres niveles
36. L N N N N Cablatge complert Cal que existeixin 4mm de separació entre el bus i els cables de potència. Cal que el bus tingui el mateix aïllament que el cable de potència.
Ventajas: Flexible, simple planning: you determine the functions and decide where the switches should be installed. You can even decide later whether switch x should really switch lamp y or whether another switch should fulfil this function. This also means: Flexibility for changes and expansion at any time - even after installation has been completed. Perhaps the switch at the lounge door should no longer control only one lamp, but rather dim all the lamps in the room? Changes present no problem and can be carried out without caulking and thus without the dirt this involves. And expansions are a lot less complicated than with conventional installations. Perhaps you want to use the switch not only to control the lighting, but also the music system, to create a cosy atmosphere at the touch of a button. No problem, as INSTABUS links the individual subsections of an electrical installation, such as the light and blind control. Complex demands can be fulfilled with considerably less effort and at less expense than with a conventional installation. Central display and operation of all technological functions in the house. Of course, you can also control Instabus from your PC in your study or display statuses - at the click of a mouse or with a touch-screen monitor. Instabus minimises operational and energy costs. The energy consumption through heating and lighting is controlled automatically and is constantly adapted to suit the current living situation. Example: window open - heating off, unnecessarily activated power-consuming devices are switched off, etc.
Ventajas: Flexible, simple planning: you determine the functions and decide where the switches should be installed. You can even decide later whether switch x should really switch lamp y or whether another switch should fulfil this function. This also means: Flexibility for changes and expansion at any time - even after installation has been completed. Perhaps the switch at the lounge door should no longer control only one lamp, but rather dim all the lamps in the room? Changes present no problem and can be carried out without caulking and thus without the dirt this involves. And expansions are a lot less complicated than with conventional installations. Perhaps you want to use the switch not only to control the lighting, but also the music system, to create a cosy atmosphere at the touch of a button. No problem, as INSTABUS links the individual subsections of an electrical installation, such as the light and blind control. Complex demands can be fulfilled with considerably less effort and at less expense than with a conventional installation. Central display and operation of all technological functions in the house. Of course, you can also control Instabus from your PC in your study or display statuses - at the click of a mouse or with a touch-screen monitor. Instabus minimises operational and energy costs. The energy consumption through heating and lighting is controlled automatically and is constantly adapted to suit the current living situation. Example: window open - heating off, unnecessarily activated power-consuming devices are switched off, etc.
Technology Of which devices does the INSTABUS EIB system consist? The basics Products System devices Sensors Actuators ETS
System devices Which devices are available? Power supply Coupling unit
Sensores
Sensors in the UP range Single, 2, 3 and 4-gang pushbutton insert Single and 2-gang bus coupling unit insert IR receiver Room temperature control ARGUS movement detector
Sensors in the UP range Single, 2, 3 and 4-gang pushbutton insert Single and 2-gang bus coupling unit insert IR receiver Room temperature control ARGUS movement detector
Sensors in the UP range Single, 2, 3 and 4-gang pushbutton insert Single and 2-gang bus coupling unit insert IR receiver Room temperature control ARGUS movement detector
Sensors in the UP range Single, 2, 3 and 4-gang pushbutton insert Single and 2-gang bus coupling unit insert IR receiver Room temperature control ARGUS movement detector
Actuators Flush-mounted UP Series installation REG-K Installation EB
Here is an example of an installation on INSTABUS basis. The simple structure of the system is clearly obvious. All devices are connected to each other via a separate cable, the so-called bus line. The system components communicate via the line. And it makes no difference whether switch x should now switch the light in the lounge or whether you decide years later that the same switch should also switch the lighting in the hallway. INSTABUS from Merten adapts flexibly to suit your wishes and requirements.
Sensors and actuators A short introduction to the technology of INSTABUS EIB demonstrates how all this is possible. The system is divided into sensors and actuators, which are all connected to the bus line. Sensors are devices such as pushbuttons, movement detectors, wind sensors, clocks, brightness sensors or remote controls, which can process an order and pass it on in the form of data. They are the devices which give the orders, so to speak. Actuators are devices such as switching, blind and dimming actuators or also displays, which transform the data from the sensors into actions. They are the devices which carry out orders. They can, however, also send messages to the bus, e.g. communicate their status, which then appears on a display. The programming determines which actions are executed when, how and by which devices. The programming takes place with software (called ETS), in which all logical connections and parameters are set. Now it becomes clear why Instabus is so flexible and convenient for the user. The connections take place via the bus line, to which all system users are connected. The functions are not assembled rigidly, but rather logically, and can also be changed again in a logical manner.
Lines are connected via coupling units and this is then referred to as the EIB area. Up to 15 secondary lines can be connected to an EIB area via a line coupling unit and a main line. The coupling units metallically separate the lines and filter the telegrams so that the only telegrams transmitted into other lines are ones which have to be received there. This keeps the load to a minimum. The correct handling of coupling units is therefore very important. The EIB Tool Software creates the filter tables on the basis on the parameterisation; these are then loaded into the coupling unit.
Cable installation BUS Possibilities: Line Star or Tree structure Bus lines may be branched as required and require no terminating resistors.
Cable installation BUS Possibilities: Line Star or Tree structure Bus lines may be branched as required and require no terminating resistors.
Permitted cable lengths: One line contains the following distance data: Maximum length: 1000 m Max. distance between 2 devices: 700 m Max. distance between power supply and first device: 350 m
Lines are connected via coupling units and this is then referred to as the EIB area. Up to 15 secondary lines can be connected to an EIB area via a line coupling unit and a main line. The coupling units metallically separate the lines and filter the telegrams so that the only telegrams transmitted into other lines are ones which have to be received there. This keeps the load to a minimum. The correct handling of coupling units is therefore very important. The EIB Tool Software creates the filter tables on the basis on the parameterisation; these are then loaded into the coupling unit.
Lines are connected via coupling units and this is then referred to as the EIB area. Up to 15 secondary lines can be connected to an EIB area via a line coupling unit and a main line. The coupling units metallically separate the lines and filter the telegrams so that the only telegrams transmitted into other lines are ones which have to be received there. This keeps the load to a minimum. The correct handling of coupling units is therefore very important. The EIB Tool Software creates the filter tables on the basis on the parameterisation; these are then loaded into the coupling unit.
EIB overall system: The coupling units are used as backbone coupling units between the main line and the backbone line. The same coupling units are used as repeaters for 64 users each. Overall topology of EIB Up to 15 ranges can be connected to an EIB overall system via a backbone line. The transfer speed of the backbone is also 9,600 bit/s. This means there can be more than 14,000 users in an EIB system. In the case of systems with a very high backbone load (e.g. with visualisations or communication with management levels), it is possible to couple the main lines via gateways on the Ethernet, in order to be able to transport more data. In this way, systems with far more than 14,000 users can be created.
Physical address Each EIB device receives a unique address in the system via parameterisation The physical address provides the device with a name, i.e. a number It is divided into area, line and device number Example: Area Line Device 1.1.15 This physical address is loaded once via the bus from the PC into the bus coupling unit, whereby a small programming button must be pressed on the corresponding device. Physical address: Divided into area, line and device number. The physical address is noted at the points in order to understand which address has been allocated to the device.
Physical address
3-digit group address Group addresses are generated in order to determine the connections between the communications objects The group address allocates the functions to be executed It is divided into a main group, a middle group and a subgroup. These are used for the unambiguous allocation of the function. Example: Main group Middle group Subgroup Level Device Function 1st floor Lighting Lamp group 1 1/1/1 It is the task of the EIB System integrator to determine an optimal structure of the group addresses for the project in hand. Actuators can respond to several group addresses, but sensors can only transmit one group address.
3-digit group addresses
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
Cable installation 230/400 V
EIB operation The bus is connected to the PC with an RS-232 interface for operation. Now, the physical address and the application with the connections and parameters can be chosen and loaded into the EIB devices. This procedure takes approximately 20 seconds. The programming button on the device has to be pressed once to allocate the physical address. The remaining data can be changed at any time, e.g. if you wish to make changes at a later point from anywhere in the bus system.