DE102021134203A1 - Network component and lighting network - Google Patents

Abstract

The lighting system according to the invention comprises a number of network components which are meshed with one another via a network, preferably a radio network such as the network (13). It is preferably a non-hierarchical network, for example based on Bluetooth. If the network (13) fails, control circuits (24) of the network components (11) involved first check whether operating voltage is still present via the general supply network (14a). This also applies in particular to network components (11) which have a digital input (D) supplied with information from a wired network, such as the network component (11k) or else others. If the digital information at the relevant inputs (D) is lost, the network components (11) do not automatically switch to emergency operation, but instead check beforehand whether the supply voltage of the general supply network (14a) is not still available and activate emergency operation and thus the second operating circuit ( 23) only if this is not the case. In this way, unnecessary emergency operation is avoided and the operability of the lighting system (10) is maintained with higher brightness than if the system (13) were to switch immediately to emergency operation with low brightness.

Description

A lighting system network component for operating a light source in a network consisting of several such lighting system network components from which an information-transmitting and -exchanging network is formed. Such a network can be used to switch light sources of the lighting system on and off, to dim them or to influence the light sources in some other way.

From the DE 20 2019 005 650 U1 a system for the wireless control of electrical loads, in particular also lighting devices with LEDs, is known. The LED drivers can be connected to a wireless switch, a smartphone and/or each other via a Bluetooth network.

For a similar network, the DE 11 2017 003 157 T5 , switch off unimportant functions or devices in such an intelligent network with the aim of avoiding a voltage drop or power failure.

The DE 10 2021 105 552 A1 proposes such a network with an emergency lighting system. If a failure of the BUS communication is detected, the entire emergency lighting system is switched to a safe state. The failure event is transmitted from module to module, with the received module reacting on the basis of its own programming, ie autonomously. The module decides how to handle an event.

Further prior art is formed by the following documents:

DE 10 2017 200 036 A1 , DE 10 2016 212 108 A1 , DE 10 2016 011 815 B3 , DE 10 2014 202 720 A1 , WO 00/2014198903 A2 .

The networked lighting system can experience network failures, both failures of the electrical supply network, i.e. the mains voltage, and failures of the information transmission network. In both cases, safe continued operation and, if necessary, the transition to emergency operation should be ensured.

The object on which the invention is based is derived from this, namely to create an improved lighting system network component.

This task is solved with the lighting system network component according to claim 1:

The network component according to the invention comprises a first operating circuit which has an AC voltage input set up for a general supply network. This is typically designed for a voltage of 230 V and also designed to absorb the power required to operate the LED and to cover its own losses. The network component can also have a second operating circuit, which has a DC voltage input set up for an emergency power supply network. This is designed to receive a DC voltage that is typically lower than the voltage of the AC mains voltage for the first operating circuit. The DC voltage input is also designed to absorb the operating power required to operate a light source, for example an LED, in emergency power mode. The first and the second operating circuit can use the same circuit components and circuits in whole or in part. However, they can also be realized in whole or in part in different structural units.

The network component also includes at least one network switching module, which is connected to the first and/or (if present) to the second operating circuit and is set up to be integrated into an information-transmitting network of other network switching modules that form nodes in this network. Such a network coupling module is in particular a coupling module set up for wireless communication; the network is accordingly a radio network. The network component according to the invention also includes a control circuit which is set up to check the integrity of the network and, in the event of at least partial failure of the network, to cause the first or (if present) the second operating circuit to operate the light source with a predetermined brightness level.

The control circuit can be part of the network switching module, the operating circuit or a separate component. The network component according to the invention can distinguish between different error cases and react to them appropriately:

A) If, for example, the general supply network fails, the network coupling module can report this failure to a control center via the network. This has its advantages in particular when the failure of the supply network is only local and affects a few light sources or a few rooms, for example. It is also possible to keep the network coupling module active from a local memory for a few seconds or minutes after the failure of the supply network.

B) Another error case can occur if one or more of the network components of the network have a DALI input and receive control commands via this. If the DALI voltage fails, this can in turn be reported via the network coupling module as a corresponding message to a control center or other network components. The network coupling module can also be set up to check whether the supply network is still active if the DALI voltage fails. The control circuit can be set up to cause the first operating circuit to continue to ensure the operation of the light source from the general supply network. Provision can also be made for the light source to be operated with a predefined brightness level that is independent of the DALI control. If, on the other hand, the control circuit or the network coupling module detects the additional failure of the AC voltage of the general supply network, a switchover to emergency power operation can be carried out. For this purpose, the control circuit is set up to activate the second operating circuit and to deactivate the first operating circuit. The control circuit can also be set up to carry out the emergency power operation again with a predefined brightness level. The brightness level can be fixed or specified by a control center and transmitted over the network to the network coupling module before the onset of emergency operation.

C) Another significant error case is the partial or complete failure of the information-transmitting network, so that no more control information is received or transmitted via the network coupling module. In this case, the control circuit detects the loss of integrity of the network and causes the first or the second operating circuit to operate the light source at a predetermined level of brightness. The control circuit is set up to activate the first operating circuit if the supply voltage of the supply network is still active. Otherwise, it disables the first operating circuit and enables the second operating circuit. In this case, too, the network switching module can also be set up to check whether the supply network is still active if the information-transmitting network fails. If this is the case, the control circuit can be set up to cause the first operating circuit to continue to ensure the operation of the light source from the general supply network. Provision can also be made for the light source to be operated with an independent brightness level. If, on the other hand, the control circuit or the network coupling module detects the additional failure of the AC voltage of the general supply network, the control circuit can be set up to switch over to emergency power operation. For this purpose, the control circuit is set up to activate the second operating circuit and to deactivate the first operating circuit. The control circuit can also be set up to carry out the emergency power operation again with a predefined brightness level. The brightness level can be fixed or specified by a control center and transmitted over the network to the network coupling module before the onset of emergency operation.

The error handling mechanisms mentioned enable the continued operation of the lights connected to the network components, in particular in the event of a partial or complete failure of the information-transmitting network. This in particular using the general power supply, if still available. In particular, it can be achieved that the network components do not simply switch to emergency power operation because the DALI signal transmission has failed.

The information-transmitting network is preferably a radio network. For this purpose, the network switching modules are preferably designed as radio modules. In particular, they can be embodied as Bluetooth coupling modules. The required ranges are thus provided, whereas on the other hand only a low power consumption is required.

The first and/or the second operating circuit can also have a digital control input which is set up for wired communication. The lighting system formed from the network components according to the invention can thus be connected to other lighting systems and/or other control devices. The digital control input can be a DALI input, for example.

The control circuit is preferably set up to couple the network switching module directly to a number of other network switching modules which number is less than the number of nodes in the entire network. The number of nodes in the entire network typically corresponds to the number of network switching modules in the network. It can be specified that each network coupling module is directly connected to a maximum of four other network coupling modules. Nevertheless, it can be ensured in this way that all nodes (network coupling modules) in the network can be reached on several paths. The failure of individual wireless connections between connected (“neighboring”) nodes thus leads to generally not to the disintegration of the network, ie to the inaccessibility of individual nodes.

The control circuit can have a memory space for the number of nodes in the entire network and/or a memory space for the number of active nodes in the network. Furthermore, the control circuit can be set up to check from time to time whether the number of accessible and therefore active nodes in the network is as large as the number of existing nodes. If this is not the case, individual nodes are unreachable. The control circuit can be set up to generate an error message immediately or, if desired, at a different point in time and to send it out via the part of the network that is still functional and thus send it, for example, to a central control device or another addressee.

The possibilities and advantages mentioned also apply to a method according to the invention for operating a light source with the features of claim 15. In addition to the advantages mentioned, the individual network components only activate the second operating circuit and thus the emergency lighting operating mode when the supply voltage of the general supply network has failed, but not if only the information-transmitting radio network and / or the digital control at the digital control input has become inoperable or disrupted.

• 1 ein mit untereinander vernetzten, z.B. der Raumbeleuchtung dienenden Netzwerkkomponenten aufgebautes Netz;
• 2 bis 7 geeignete Netzwerkkomponenten des Netzes nach 1.

Further details of advantageous embodiments of the invention result from the subclaims, from the figures of the drawing and/or from the associated description. Show it:

• 1 a network constructed with network components that are networked with one another, for example those used for room lighting;
• 2 until 7 suitable network components of the network 1 .

1 Figure 1 illustrates a lighting system 10 that includes a plurality of network components 11 (11a...11k), each connected to a general power grid 14a and at least some of which are connected to an emergency power grid 14b. Next is in 1 at least one network component 12 is illustrated, which can be formed, for example, by a portable mobile terminal device, for example a smartphone, tablet or the like. The network component 13 can thus be regarded as a control device 12, for example. One or more other control devices (not shown) can be provided.

The network components 11a to 11k are, for example, operating devices for light sources for room lighting. They form a network 13 among themselves, the nodes of which are the network components 11a to 11k including the network component 12 (control device). The nodes of this network are connected to one another by bold edges 15, via which adjacent nodes are connected in pairs in an information-transmitting connection, such as the network components 11a and 11b or the network components 11g and 11b. Other theoretically possible information transmission paths are entered in dashed lines as unused edges 16 . The information transmission paths used form a mesh-free network with a tree structure. Should a used information transmission path fail, the network components 11a to 11k can activate and use one or more of the previously unused information transmission paths shown in dashed lines.

The network components 11a to 11k can, according to each of the 2 until 6 illustrated basic structures or after 7 be realised. This illustrates the integration of a network component 11 into a supply network 14, which normally carries AC voltage (eg 230 V _AC ) and direct voltage (eg 24 V _DC or 230 V _DC ) in the event of emergency power. This network component has a combined AC/DC input and automatically detects the emergency power situation if DC voltage is present instead of AC voltage. An accumulator battery 14c is used for the DC voltage supply. A switching and charging circuit 14d is set up to charge the accumulator battery 14c and to connect it to a combined mains and emergency power input AC/DC in the event of emergency power. In addition, the switching and charging circuit 14d can be set up to forward incoming DALI signals via the mains voltage input AC to the combined mains and emergency power input AC/DC of the network component 11 . The accumulator battery 14c can be housed centrally in a building and can be used to supply some or all of the network components 11 .

2 first illustrates a network component 11 without an emergency power operation option. Network components of this type can also be added to the network 13 1 be integrated. The network component includes a first operating circuit 17 with the input AC, which is set up for connection to a general supply network 14a (230 V AC network). An output 18 provides the operating power required to operate a light source 19 with the appropriate voltage and the appropriate current.

The light source 19 can be an LED light source, for example. The operating circuit 18 can also have a digital control input D, which is set up, for example, to work according to the DALI standard. Several of the components can also be combined in one operating device or designed as individual devices with interfaces (plug connectors, terminals for connection).

A network coupling module 20, which can be provided with an antenna 21 in order to set up radio communication with other network coupling modules, is connected to the digital control input D. The network switch module 20 can be a Bluetooth switch module, for example. For the power supply, the network coupling module 20 can receive operating power from the first operating circuit, or as in 2 exemplified obtained via a power supply 22 from the general supply network.

Instead of the input AC set up for the general supply network 14a, the network component 11 can also have an input DC set up for the emergency power supply network 14b. While the network component 11 is only suitable for mains operation in the first case, it is only suitable for emergency power operation in the second case. Both types of network components 11 can be integrated into a network 13 according to the invention.

3 illustrates a network component 11 to which the above description applies accordingly. In addition, the operating device integrates the first operating circuit 17 for mains operation and a second operating circuit 23 for emergency power operation in one structural unit. The network component 11, like the network components 11, can 2 have a control circuit 24, which controls the operation of the first operating circuit 17 and optionally the operation of the second operating circuit 23. In particular, the control circuit 24 can be set up to control the operation of the first operating circuit 17 and/or the second operating circuit 23 depending on the error cases present:

A first case of error is the failure of the general supply voltage at the input AC. In such a case, the network component 11 after 2 shut down. However, the control circuit 24 can cause the network coupling module 20 to send out an error signal, for example using residual energy present, for example the charge of a storage capacitor, which signalizes the local failure of the general supply voltage at the input AC.

In execution after 3 If the supply voltage at the input AC fails, the control circuit 24 switches off the first operating circuit 17 and activates the second operating circuit 23, which receives voltage and operating power from the direct voltage input DC. At the same time, it can continue to operate the second operating circuit 23 in accordance with the information last received from the network switching module 20 . Alternatively, the control circuit 24 can continue to operate the light source 19 with a lower, fixed power. In addition, the control circuit 24 can cause the network switching module 20 to send out an error signal which signals the failure of the general supply voltage at the input AC. Alternatively, in this and all other embodiments, the network coupling module 20 can be provided to independently, i.e. without being prompted by the control circuit 24, detect the drop in the supply voltage in the event of a failure of the general supply voltage at the input AC and to transmit a corresponding error signal via the antenna 21 . The transmission power required for this can be obtained from the network coupling module 20 from a memory contained in itself, for example a capacitor.

4 Figure 11 illustrates an embodiment of a network component 11 in which the network switch module 20 is part of the first operating circuit. This can be designed as an independent structural unit as a device with its own housing. In addition, the second operation circuit 23 may be in the form of a separate device. The two devices can be connected to one another and to the light source 19 at their outputs. The second operating circuit 23 can be set up to only emit voltage and current at its output for operating the light source 19 if neither voltage nor current is supplied by the output 18 of the first operating circuit. For this purpose, the second operating circuit 23 can have a monitoring device. In this case, the control circuit 24 can be part of the first operating circuit 17 .

5 FIG. 11 illustrates another embodiment of network component 11 that is broadly consistent with network component 11 in accordance with FIG 4 matches. In addition, however, the second operating circuit 23 has a digital control input D, which can be set up, for example, to work according to the DALI standard. The first operating circuit 17 can accordingly 4 have their own network switching module 20 (not shown). Additionally or alternatively, the first operating circuit 17 can have a digital control input D (shown in broken lines). However, the first operating circuit 17 can also be designed without a network coupling module and without a digital control input.

In this embodiment of the network component 11, the second operating circuit 23 has a digital control input D, for example according to the DALI standard. The network coupling module 20 can be connected to this, which is connected via a supply part 25 to the direct voltage DC used for the emergency power supply. If the DC voltage at the DC input is correct, the network coupling module 20 can also be connected directly to the DC input without the interposition of the supply part 25 .

Another variant of the network component 11 goes out 6 out. In this embodiment, both the first operating circuit 17 and the second operating circuit 23 each have a digital control input D which connects the two operating circuits 17, 23 to the network coupling module 20 and the control circuit 24 via a digital bus. The digital control input D can in turn be set up to work according to the DALI standard. The network coupling module 20 and/or the control circuit 14 can be supplied with operating voltage, ie also with the corresponding operating power, via the power pack 22 and alternatively the supply part 25 .

The lighting system 10 with the network components 11a to 11k coupled via the network 13 works as follows:

To describe the operation, it is initially assumed that the mains voltage of the general supply network AC is present at the network components 11 . The DC voltage of the emergency power supply network DC is also present at the network components 11a to 11i and 11k capable of emergency operation. Network components without emergency operation capability, such as network component 11j, are not connected to the emergency power grid. For example, according to 2 be constructed. The other network components 11a to 11i and 11k are according to one of the 3 until 6 principles illustrated.

The individual network components 11a to 11k are networked with one another and form this 1 visible network 13. In each network component 11a to 11k, the respective control circuit 24 has stored the number of network components 11a to 11k, ie the number of network nodes. In addition, it has stored a number of neighboring nodes to which an active connection has been established in a corresponding memory location. For example, the network component 11j stores the addresses of the network components 11e and 11h as “neighboring” network nodes with which the network component 11j exchanges data as required. The network components 11a to 11k regularly or occasionally check the total number of network components that can be reached and compare this number with the stored number (in the example 11 if the network component 12 is not included in the calculation). This can be performed by the control circuitry 24 . If the respective control circuit 24 of a network component 11a to 11k initiates a test to determine the number of network nodes that can be reached and the result is a number (e.g. 9 or 10) that is less than the stored number of all nodes, the network component in question can immediately send an error signal send to report the error condition, for example, to a control center, for example, the network component 12.

• a) Eine Netzwerkkomponente reagiert sofort, falls nicht das gesamte System erreichbar ist.
• b) Eine Netzwerkkomponente reagiert, wenn ein bestimmter Prozentsatz der Netzwerkkomponenten des Netzwerks ausgefallen ist.
• c) Eine Netzwerkkomponente reagiert erst dann, wenn sie keine andere Netzwerkkomponente des Netzwerks erreichen kann.

The network component can be set up to implement three different reaction levels:

• a) A network component reacts immediately if the entire system cannot be reached.
• b) A network component reacts when a certain percentage of the network components of the network have failed.
• c) A network component only reacts if it cannot reach any other network component in the network.

The network component can be set up in one of the cases a), b), c) to switch from a stand-by (light off) to a state that includes a safe light brightness, preferably independently of input signals such as button actuations or motion detectors -signals. The power supply for this can certainly be provided by the AC supply network (230 V).

If the network component under consideration, for example the network component 11j, loses its radio connection to the associated network nodes, ie the network components 11e and 11h, the network component 11j in question no longer has any control information. Is it according to the example of the network component 11 3 constructed, the control circuit 24 first checks whether the general supply network has failed or not. If there is a failure, the control circuit 24 shuts down the operating circuit 17 and activates the operating circuit 23 to establish emergency operation. The control circuit 23 is thus fed from the direct voltage network DC. Also, the auxiliary supplies 22 and 25 and the power supplies 17 and 23 can always operate in parallel, so that no active switching is required is. Ideally, the respective supply is then constructed in such a way that an energy flow from the AC supply is preferred. The light source 19 now receives a current and voltage supply in order to generate a predetermined level of brightness.

In accordance with the network component 11 4 the control circuit 24 also activates the second operating circuit 23 in the event of failure of the supply network AC in order to enable emergency operation. In this case, the first operating circuit 17 is shut down.

The control circuit 24 also proceeds with the network components 11 according to FIG 5 or 6 .

What all network components 11 have in common, however, is that the control circuit 24 does not immediately go into emergency operation if the network 13 fails, but instead first checks whether the supply voltage of the general supply network 14a is still present. If this is the case, the first operating circuit 17 remains active. On the other hand, the second operating circuit 23 is not activated. Due to the failure of the operating information due to the failure of the network 13, however, the network components 11 switch to a predefined operating mode in that the control circuit 24 then sets a predefined brightness for the light source 19. This brightness can also be a predetermined mean brightness.

The lighting system according to the invention comprises a number of network components 11 which are meshed with one another via a network, preferably a radio network, such as network 13 . It is preferably a non-hierarchical network, for example based on Bluetooth. If the network 13 fails, control circuits 24 of the network components 11 involved first check whether operating voltage is still present via the general supply network 14a. This also applies in particular to network components 11 that have a digital input D supplied with information from a wired network, such as network component 11k or also network components 11 according to FIG 2 , 3 , 5 or 6 . If the digital information is lost at the relevant inputs D, the network components 11 do not automatically switch to emergency operation, but instead check beforehand whether the supply voltage of the general supply network 14a is not still available and activate emergency operation and thus the second operating circuit 23 only if this is not the case.

In this way, unnecessary emergency operation is avoided and the operability of the lighting system 10 is maintained with higher brightness than if the system 13 were to switch immediately to emergency operation with low brightness.

reference list

10

lighting system

11

Network components (11a ... 11k)

AC

general supply network 230V~

DC

emergency power grid

12

Network component / control device

13

network

14

supply lines

14a

general supply network

14b

emergency power grid

14c

charging and switching device

14d

accumulator battery

15

edge

16

unrealized connections / edges

17

first operating circuit

18

Exit

19

light source

D

digital control input (DALI)

20

Network coupling module

21

antenna

22

power adapter

23

second operating circuit

24

control circuit

25

supply part

QUOTES INCLUDED IN DESCRIPTION

This list of documents cited by the applicant was generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Patent Literature Cited

• DE 202019005650 U1 [0002]
• DE 112017003157 T5 [0003]
• DE 102021105552 A1 [0004]
• DE 102017200036 A1 [0006]
• DE 102016212108 A1 [0006]
• DE 102016011815 B3 [0006]
• DE 102014202720 A1 [0006]
• WO 00/2014198903 A2 [0006]

Claims (15)

Lighting system network component (11) for operating a light source (19), with a first operating circuit (17) which has an alternating voltage input (AC) set up for a general supply network (14a), with a network switching module (20) which is connected to the first operating circuit (17) and is set up to be integrated into an information-transmitting network (13) of other network switching modules (20) which form the nodes of this network (13). , a control circuit (24) which is set up to check the integrity of the network (13) and, in the event of an at least partial failure of the information-transmitting network (13), to check whether the general supply network (14a) is still active and, if this is the case The case is to cause the first operating circuit (17) to operate the light source (19) at a predetermined brightness level. lighting system network component claim 1 , characterized in that it has a second operating circuit (23) which has a direct voltage input (DC) set up for an emergency power supply network (14b) and which is connected to the network coupling module (20). Lighting system network component according to one of the preceding claims, characterized in that the general supply network (14a) is a 230 V network. Lighting system network component according to one of the preceding claims, characterized in that the general supply network (14a) and a DC voltage network (14b) provided for the emergency power supply use common lines leading to the network components (11), which have a switching and charging circuit (14d) with a central accumulator battery (14c) are connected. A lighting system network component as claimed in any preceding claims 2 or 3 , characterized in that the first operating circuit (17) and the second operating circuit (23) are separate structural units. A lighting system network component as claimed in any preceding claims 2 or 3 , characterized in that the first operating circuit (17) and the second operating circuit (23) are designed as a common structural unit. Lighting system network component according to one of the preceding claims, characterized in that the network coupling module (20) is a Bluetooth coupling module. Lighting system network component according to one of the preceding claims, characterized in that the first operating circuit (17) has a digital control input (D) set up for wired communication. A lighting system network component as claimed in any preceding claims 2 until 8th , characterized in that the second operating circuit (23) has a digital control input (D) set up for wired communication. A lighting system network component as claimed in any preceding Claims 8 or 9 , characterized in that the digital control input (D) is set up to work according to the DALI standard. Lighting system network component according to one of the preceding claims, characterized in that the control circuit (24) is set up to directly couple the network switching module (20) to a number of other network switching modules (20) which is less than the number of Nodes of the entire network (13). Lighting system network component according to one of the preceding claims, characterized in that the control circuit (24) has a memory location for the number of nodes in the entire network (13). Lighting system network component according to one of the preceding claims, characterized in that the control circuit (24) has a memory location for the number of active nodes of the entire network (13). lighting system network component claim 12 and 13 , characterized in that the control circuit (24) is set up, in the event of an at least partial failure of the network, before activating the second operating circuit (23), to first check whether supply voltage is still present in the supply network (14a) and the second operating circuit (23 ) only to be activated if this is not the case. Method for operating a light source (19) as a lighting system network component, in which an operating circuit (17) is operated by a general supply network (14a) with alternating current (AC), and/or a second operating circuit (23) is operated by an emergency power supply network ( 14b) with equal Voltage (DC) is operated, a network coupling module (20) integrated into a network (13) of further network coupling modules (20) to form a node of this network (13), with a control circuit (24) the integrity of the mains (13) and, if the mains (13) fails at least partially, operates the operating circuit (17, 23) with a predetermined brightness level of the light source (19) if the mains supply (14a) supplies alternating voltage to the alternating voltage input (AC).

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