NL1023624C2 - Control module for modular automation system for electrical devices, has scenario control unit connected to interface for processor - Google Patents

Abstract

A scenario control unit (15) is connected to the interface (7) for the processor (2) in order to control one or more switch modules for electrical devices according to a pre-determined scenario via an actuator unit. The processor (2) is linked to a communication unit (3) for exchanging data with one or more remote switch modules for electrical devices. The interface is used to connect the actuator unit for operating one or more switch modules.

Description

Brief indication: Control module, scenario control means and an I modular automation system for switching electrical consumers.

I 5 DESCRIPTION

The invention relates to a control module for use in a modular automation system, which control module is provided with data processing means, communication means for data exchange with data processing means coupled to one or more remote switching modules for switching I electrical consumers and interface means coupled to the data processing means for connecting operating means for operating one or more of the switching modules.

Such a control module and switching module, in particular for use in a modular sleeve automation system for switching electrical consumers connected to an electricity network, such as, for example, lighting, audio and video equipment, household appliances and security equipment, are known per se in practice.

In order to achieve universal applicability, the known control modules are arranged such that the interface means respond to signal ground connection of one or more input terminals, for activation as a result thereof via the data processing means and the communication means according to activation or deactivate a switching module. The switching modules are designed in their simplest form for switching on and off a connected electrical consumer. In a more advanced embodiment, the switching modules can be designed, for example, as a dimmer circuit.

I 30 The communication between the control modules and the I switching modules is advantageously via the electricity network. For this purpose the modules are each provided with an address with which each module can be selected for data exchange for, for example, switching a relevant module. Two-way communication is preferred, because it allows for interactive switching and jumps in on deviations when, for example, a consumer to be switched, such as a lamp, is broken.

In a preferred embodiment, infrared or radio-controlled remote control means are added to the system for remote control of the various modules and the control modules are programmable for performing switching functions in a predetermined manner. These switching functions can in themselves depend on other switching functions of other control modules in the system and the reaction of the switched consumers.

In the light of this description and the invention, the term "switching" is to be understood to include any function with which the operation of a connected electrical consumer can be influenced. That is, suitably controlling the voltage supplied to a consumer or the current consumed by the consumer.

Because the interface means of a control module 20 respond to the connection of one or more input terminal points thereof to the signal ground, a switching module can be operated with simple operating means in the form of pulse switches or the like. For example for switching a consumer on or off, but also for activating a dimmer switch module, such as the above. For controlling a switching module with such a control module for performing more complicated switching operations, such as, for example, activating and deactivating electrical consumers according to a certain scenario, switching motors in different operating positions or, for example, controlling, depending on a sensor signal, a switching module, the interface means of a control module must be suitably and knowledgeable for this to be coupled with the relevant operating means. The number of scenarios is virtually unlimited in practice and depends strongly on a specific application.

It will be understood that with current control modules 5 the knowledge of an expert or specialist is indispensable for achieving a desired advanced switching scenario. In view of the associated costs, it has been found that the known automation system is used in practice only for a limited number of switching functions or switching scenarios. Mainly for switching consumers on and off in a specific order, switching consumers on time and the aforementioned dimmer operation.

It is therefore an object of the invention to improve the known control modules in such a way that they can also be installed and applied by less or even completely specialist users for more advanced control scenarios, without prejudice to the universal and modular structure of the control modules and the automation system as a whole.

According to the invention, this task is solved by scenario control means coupled to the interface means, arranged for controlling one or more of the switching modules with the operating means according to a predetermined scenario.

These scenario control means are adapted to control one or more of the switch modules according to a defined scenario, which may be application-dependent. The scenario control means are thereby arranged to control the control modules with appropriate, i.e., application-tailored, control means for the desired activation and / or deactivation of switching module (s).

By providing the scenario control means, in accordance with an embodiment of the invention, as a separate module for use with a control module, the universal construction of a control module is maintained, so that relatively simple switching operations can also be carried out with this if desired. In accordance with the inventive concept, the scenario control means can therefore essentially be applied to any existing control module, or any existing control module can be broken out with the scenario control means. Of course, the scenario control means adapted to a specific desired scenario can also be integrated into a control module, but at the expense of the universal applicability of such a control module.

In a preferred embodiment of the invention, the scenario control means are arranged for interactive communication with the interface means. With this, a scenario can therefore be controlled interactively, or activated, from the control module and, if desired, dependent on a realized switching function if the control module and a relevant switching module are also adapted for interactive or two-way communication.

In yet another embodiment, the invention provides that the scenario control means comprise control electronics adapted to a predetermined control scenario, in particular programmable control electronics. By means of this control electronics, input terminal points of the interface means are then suitably connected to the signal ground, for performing the desired switching functions.

This control electronics can, inter alia, be adapted to control one or more of the switching modules in accordance with a predetermined scenario in dependence on operating means in the form of one or more sensors, such as one or more sensors from a (non-exhausting) group comprising temperature sensors, light sensors, moisture sensors, smoke sensors, sound sensors and (electrical) - 5 magnetic field sensors. A large number of switching and control functions can be performed via this control electronics, including in the field of security, surveillance, etc.

Further embodiments of the control module according to the invention are provided, inter alia, with control electronics comprising one or more voltage and / or current comparators, for switching a switching module in the case of, for example, under- or over-voltage or in the event of too large a power draw from the electricity grid .

The invention also advantageously provides that the control electronics are arranged for time-dependent control of one or more of the switching modules, for which purpose the control electronics comprise, for example, one or more adjustable clock circuits.

In yet a further embodiment the invention provides that the control electronics are adapted to switch on a first switching module with a single operating switch and to switch off a second switching module simultaneously. With this, different consumers can be switched depending on each other via a single control command. In a simple embodiment, the control electronics comprise for this purpose one or more semiconductor diodes.

In a special embodiment for use with fan circuits in residential houses, the invention provides that the control electronics are adapted to set a fan motor at two different rotation speeds with two switch modules and three control switches. Hereby, without modification of the existing wiring or the existing power line system in for instance a house, a fan system for extraction and the like can be realized, wherein the operating means and the fan itself can be installed at various places in a house of choice.

Advantageously, a control module can itself comprise one or more switching modules included in the control module. The H control module can advantageously also be provided with plug means for connection to a wall socket of an electrical installation, with which the control module can then be provided with electrical energy, so that no batteries are required, as well as communicate via the electricity network with one or more switching modules .

The invention also provides scenario control means for use with a control module as set forth above, in particular scenario control means H with input means for connecting operating means and output means for connecting to one or more input connection points I of the interface means of a control module.

The invention also provides a modular automation system for use in an electrical installation, comprising at least one switching module for switching at least one electrical consumer, and at least one control module, wherein the or each switching module and control module is provided with data processing means and with communication means for data exchange between an I switching module and a control module coupled to the data processing means, wherein the or each control module is provided with interface means for connecting control means for operating one or more of the switching modules, characterized in that at least one control module I is provided with scenario control means coupled to the interface means, arranged for controlling one or more of the switching modules with the operating means according to I.

The modular automation system preferably comprises one or more remote control modules adapted to remotely control one or more of the switch modules, which remote control modules, switch modulus and control modules are adapted for data exchange via the electrical installation.

The invention will be illustrated in more detail below with reference to 7 exemplary embodiments.

Figure 1 shows a general electrical block diagram of an embodiment of a known control module.

Figure 2 shows a general electrical block diagram of an embodiment of a control module according to the invention.

Figures 3 to 7 schematically show embodiments of scenario control means according to the invention.

Figure 1 schematically shows a general control module 1 as is known per se in the prior art, for use in a home automation system for switching electrical consumers connected to an electricity network via one or more switching modules, such as lighting, household appliances, audio and video equipment, etc.

The module 1 comprises data processing means 2, e.g. of data originating from data processing means 2 and making received data suitable for processing by data processing means 2.

The modulator and demodulator means 5, 6 and the communication means 3 can operate in accordance with any protocol suitable for data exchange, whether or not via a proprietary or application-specific or via a standardized protocol. This is of no further importance for the purpose of the invention and this will then not be discussed further. It is important that each module in the I system can be identified via its own specific address and I data can be exchanged with it.

Interface means I 7 are furthermore coupled to the processing means 2, which means in this embodiment of the control module 1

Input means 8 and output means 9. The input means 8 have at least one input terminal 10, in a preferred embodiment, for example, four input terminal points 101, 102, 103 and 104 and a common signal ground 105. By connecting one or more signals 5 to the signal ground 105 via suitable operating means such as pulse switches (not shown) more of the input connection points 101, 102, 103 or 104 a switching command can be given to a specific switching module via the processing means 2 and the communication means 3. By appropriately programming or adjusting the data processing means 2, for example, each of the input terminal outlets 102, 103, 104 and 105 can correspond to a specific address or a specific switching module.

The output means 9, which are optional, are arranged in this embodiment as a switching module with suitable switching means 15 for controlling electrical consumers via output connection points 11. The output connection points 11 may, for example, be arranged for switching a consumer via a first output connection point 111 by means of a semiconductor switch, for switching a consumer via a second output connection point 112 via a relay or, for example, electrically isolating a consumer via an output connection point 113.

The control module 1 further comprises power supplies 12 for providing the various components of the control module with a suitable supply voltage. These food products 12 extract their electrical energy from the electricity network 4, for example directly or via the communication means 3.

The control module is arranged in a preferred embodiment for mounting in flush-mounted boxes of an electrical line system for receiving switches and wall sockets and the like.

The processing means 2 can be appropriately programmed or adjusted for switching operating means (not shown) with operating means connected to the input connection points 9 of the interface means 7, such as the aforementioned pulse switches, in one desired sequence of one or more switching modules, optionally interactive in dependence on a switching function performed by one or more of the switching modules 5, the state of a switched consumer, etc. The communication means 3 and the interface means 7 are for this purpose preferably adapted for two-way or interactive communication.

In order to make the control module 1 suitable for operating means other than pulse switches or the like, the invention provides scenario control means 15 coupled to the interface means 7, as shown in block diagram form in Fig. 2.

In the embodiment of the invention shown, the scenario control means 15 are added to the control module 1 as a separate component or module and are coupled with their output side 17 to the input connection points 10 of the interface means 7. The scenario control means 15 are adapted to control the switching modules according to a predetermined scenario by means of control means connected to the input side 16 of the scenario control means 15 (not shown). The number and type of operating means to be connected to input side 16 depend on the application and / or the desired scenario. For this purpose, the scenario control means 15 have control electronics 18 adapted to a predetermined control scenario, which may or may not be programmable or adjustable.

In other words, with the scenario control means 15 according to the invention, the control module 1 becomes suitable for switching arbitrary consumers with arbitrary operating means, wherein the control electronics 18 activate one for connecting the operating means and activating one according to a desired scenario. or more of the input terminal outlets 10 of the interface means 7 has suitable "intelligence". As a result, with an H universally designed control module, such as the control module 1 shown in Fig. 1, virtually any desired switching function can be performed via the I switching module or switching modules communicating with it, relatively simply without the need for specialist knowledge. by applying suitably implemented I scenario control means 15.

Advantageously, the scenario control means 15 can also be coupled to the output connection points 11 of the interface means 7, for effecting interactive communication with the interface means 7 and the connected switching modules, such as lines interrupted with I shown in Fig. 2.

FIG. 3 schematically shows a first exemplary embodiment I of scenario control means 20 according to the invention, with I control electronics 21 in the form of an adjustable clock circuit I15 for the time-dependent control of a switching module. In the I embodiment shown, the scenario control means 20 are suitable for connecting I on the output side 17 thereof to a single connection point, such as, for example, the connection point 104 of the connection points 10 of the I interface means 7 of the control module 1, and the signal ground 105.

On the input side 16, the scenario control means 20 are arranged for connecting control means in the form of an I pulse switch 22 for activating the control electronics 21.

A person skilled in the art will understand that the control electronics 21 can be adapted to activate different connection points 10 of the interface means 7 and, if necessary, to connect different control means. With these scenario control means 20, an I control module 1 can be made relatively simple for time-dependent control of consumers.

FIG. 4 schematically shows a second exemplary embodiment 30 of scenario control means 25 according to the invention, with control electronics 26 in the form of electronic components such as 11 operational amplifiers, resistors, capacitors, transistors, etc. for dependence on operating means such as sensors 27, including temperature sensors. , light sensors, moisture sensors, smoke sensors, sound sensors, (electro) magnetic field sensors and other sensors suitable for observing physical quantities, suitable activation and deactivation of switching modules. Here too, it holds that the control electronics appropriately convert the signals from the sensors 27 for activating one or more of the connection points 10 of interface means 7 of a control module. The control electronics 26 10 naturally also provides the sensors 27 with a suitable operating voltage. Preferably, the control electronics 26 are adapted for interactive two-way communication with the interface means 7.

A person skilled in the art can realize suitable electronic circuits for executing a desired control scenario, with or without interactive communication. Here again it holds that with the scenario control means 25, a control module 1 can be made suitable in a relatively simple manner for controlling consumers in dependence on observed physical quantities. Eye-catching applications are in the field of security and surveillance. FIG. 5 schematically shows a third exemplary embodiment of scenario control means 30 according to the invention, with control electronics 31 in the form of voltage or current comparators, for the voltage or current levels on the output side observed on the input side 16 of the scenario control means 30 17 activation of one or more of the input connection points 10 of the interface means 7. The order of activation of the input connection points is thereby determined by the control electronics 31.

FIG. 6 schematically shows a fourth exemplary embodiment 30 of scenario control means 35 according to the invention, with control electronics 36 in the form of three semiconductor diodes 37, 38 and 39 connected as shown in the figure. This embodiment of the scenario control means 35 is particularly suitable for setting a fan motor 40 of a home ventilation system or the like at different speeds. These fan motors 40 generally have a first and second winding 41 and 42 which are connected such that when the first winding 41 I is energized, the fan motor runs at a low speed, and when the second winding 42 I energizes, the fan motor 40 operates on, for example, half-force I and that with simultaneous energization of the two windings 41 I10 and 42 the fan motor operates at full force.

On the input side 16 of the scenario control means 35, control means 45, 46 and 47 are connected in the form of I pulse switches for switching the fan motor 40 in the low, middle (half) or high (full) position, respectively, by the I motor. respectively pressing a relevant switch 45, 46, 47.

For switching the fan motor 40, the first I and second windings 41 and 42 are connected to the electricity network I 4 via a first switching module 43 and a second switching module 44, respectively. The switching modules 43 and 44 are, in their simplest form, as explained above with respect to the control module 1, provided with communication means 3, modulator and demodulator means 5, 6, processing means 2 and output means 9 for switching a electrical consumer. In a more I advanced embodiment, the switching modules can also be provided with I input means 8, for interactive communication with an I consumer. For the sake of simplicity, the switching modules 43, 44 are shown as a switch in the figure.

The control module 1 is programmed such that when I connect the input terminal 101 of the interface means 7 to the signal ground 105, the second switching module 44 is switched off (does not become conductive). When the input terminal 102 is connected to the signal ground 105, the second switching module 44 is switched on (becoming conductive). When connecting the input terminal 103 to the signal ground 105, the first switching module 43 is switched off and when connecting the input terminal 104 to the signal ground 105, the first switching module 43 is switched on.

The circuit now works as follows. When switch 45 is pressed, the input terminal 104 of the interface means 7 of control module 1 is connected to the signal earth 105 via the scenario control means 35, which leads to switching on the first switching module 43. Via the diode 37 and the switch 45 the input terminal out point 101 of the interface means 7 is also connected to the signal earth 105, which is a command for switching off the second switching module 44. The fan motor 40 now operates in its low position, because only the first winding 41 via the first 15 switching module 43 is energized.

When subsequently the switch 46 is pressed, the input terminal 103 is connected to the signal ground 105, which leads to the switching off of the first switching module 43. Via the diode 38 and the switch 46, the input terminal 102 is also simultaneously connected to the signal ground 105, which leads to a switch-on command to the second switching module 44. The fan motor 40 now operates at half power, because only the second winding 42 is energized via the second switching module 44.

The operation of the switch 47 does not lead to a switch-off command, because only the input terminal 102 and via the diode 39 the input terminal 104 are connected to the signal ground 105 for switching the first and second switching modules 43 and 44 respectively, causing the fan motor 40 can run at full speed.

By applying the scenario control means 35, the user does not need special knowledge of connecting the

Iventilator 40 engine. The user only needs to connect the relevant scenario control means 35 to the input connection points 10 of the interface means 7 of the control module 1, to connect the control switches 45, 46 and 47 and the two switching modules 43 and 44. The switching intelligence or control scenario is accommodated in the control electronics 36 and the wiring of the scenario control means 35.

FIG. 7 shows a variant of the circuit of FIG. 6 wherein a fan motor 50 with three windings 51, 52 and 53 is used. During use, the winding 51 is continuously energized via a permanent connection to the electricity network 4 and the fan motor runs continuously at a low speed. Energizing the winding 52 causes the motor to run at half speed, or at an average speed, and by energizing the winding 53, the fan 50 runs at full power.

With the control module 1 as explained above, the first and second switching modules 43 and 44, and with scenario control means 55 with control electronics 56 provided with two semiconductor diodes 57 and 58 connected as shown in Fig. 7, 20 can now be used on the basis of the , control switches 45, 46, 47 connected to the scenario control means 55, as shown in FIG. 7, the following operation can be achieved.

By pressing the switch 45 the input terminal 103 becomes connected and via the diode 58 the input terminal 101 is connected to the signal ground 105, which leads to the switching off of the first and second switching modules 43 and 44, as a result of which only winding 51 of the fan motor 50 is energized and therefore operates in its low position. Depressing switch 46 leads to the input terminal 104 being connected to the signal ground 105, whereby the first switching module 43 is switched on and via the diode 57 the second switching module 44 is switched off, ie via 15 input terminal 101. The fan motor 50 now operates in its center position because the winding 52 is energized via the first switching module 43. Finally, pressing the switch 47 leads to the input terminal 102, connecting to the signal ground 105, whereby the second switching module 44 is switched on and the second winding 52 of the fan motor 50 is energized via this. The I fan now runs at full power.

A person skilled in the art will understand that many variants are possible for the scenario control means according to the invention, wherein, for example, with suitable switched semiconductor diodes and such different switching functions can be performed via a single control switch, etc.

The scenario control means according to the invention can, if desired, be integrated into a control module, as is schematically illustrated with broken lines 19 in Figure 2. This results in I application-specific control modules.

The control module 1 provided with scenario control means 15, 20, 25, 30, 35 or 55 and the switching modules 43 and 44 can form part of a larger automation system for switching electrical consumers, such as domestic I consumers. To this end, further control means in the form of I remote control means can be provided for remotely controlling I of the relevant consumers via one or more of the control modules I and switching modules.

By designing the connection 13 of the communication means 3 of an I control module 1 with the electricity network 4 as a plug connection, the control module 1 with the scenario control means I according to the invention can be connected to any wall socket of an I electricity network equipped with a automation system according to the invention. This also applies, for example, to the I switching modules. In a further embodiment of the invention, H the switch modules and the control modules are provided with suitable dimensions for mounting in flush-mounted boxes of an electric power line system behind relevant switches and wall sockets and the like.

The invention is not limited to the exemplary embodiments shown and discussed. On the basis of the above description, many modifications and additions are possible for a person skilled in the art, without thereby deviating from the inventive concept as laid down in the claims, which are considered to comprise all these changes and additions.

Claims (17)

2. Control module according to claim 1, characterized in that the scenario control means are arranged for interactive communication with the interface means. Control module according to claim 1 or 2, characterized in that the scenario control means comprise control electronics adapted to a predetermined control I scenario. 4. A control module according to claim 3, characterized in that the scenario control means comprise programmable control electronics. 5. Control module as claimed in claim 3 or 4, characterized in that the control electronics are adapted to connect one or more input connection points of the interface means I to signal earth I for controlling one or more of the I according to a predetermined scenario switching modules. 6. Control module according to claim 3, 4 or 5, characterized in that the control electronics are adapted to control one or more of the switching modules in accordance with a predetermined scenario in dependence on operating means in the form of one or more H sensors. 7. Control module as claimed in claim 6, characterized in that the sensors consist of one or more sensors from a group comprising temperature sensors, light sensors, moisture sensors, smoke sensors, sound sensors and (electro) magnetic field sensors. Control module according to claim 3, 4 or 5, characterized in that the control electronics comprise one or more voltage and / or I current comparators. 9. Control module according to claim 3, 4 or 5, characterized in that the control electronics are arranged for time-dependent control of one or more of the switching modules. Control module according to claim 9, characterized in that control electronics comprise one or more adjustable clock circuits. 11. Control module as claimed in claim 3, 4 or 5, characterized in that the control electronics are adapted to switch on a first switching module with a single operating switch in the form of an impulse switch and to switch off a second switching module simultaneously. 12. Control module according to claim 11, characterized in that the control electronics comprise one or more semiconductor diodes. Control module according to claim 3, 4, 5, 11 or 12, characterized in that the control electronics are adapted to set a fan motor with two switching modules and three impulse control switches at three different speeds of rotation. Control module according to one or more of the preceding claims, characterized by one or more switching modules included in the control module. 15. Control module according to one or more of the preceding claims, characterized in that the scenario control means are integrated in the control module. Control module according to one or more of the preceding claims, characterized by plug-in means for connection to a wall socket of an electrical installation. A scenario control means for use with a control module according to one or more of claims 1 to 14. 18. Scenario control means according to claim 16, characterized by input means for connecting I control means and output means for connection to the I interface means of a control module. 19. Modular automation system for use in an electrical installation, comprising at least one switching module for switching at least one electrical consumer, and at least one control module, wherein the or each switching module and control module is provided with data processing means and with the I data processing means coupled communication means for data exchange between a switch module and a control module, wherein the or each control module is provided with interface means I for connecting vafi control means for operating one or more of the switch modules, characterized in that at least one I control module is provided with I scenario control means coupled to the interface means, arranged for controlling one or more of the I switching modules with the control means I according to a predetermined scenario. 20. Modular automation system according to claim 19, characterized by one or more remote control modules adapted to remotely control one or more of the switch modules, which remote control modules, switch modulus and control modules are I adapted for data exchange via the electrical installation.