EP4402992A1 - Circuit assembly for a switched-mode power supply of an electric auxiliary device at the site of a connected electric load, building data processing device, socket module, and electric stairwell installation - Google Patents

Abstract

The invention relates to a circuit assembly for a switched-mode power supply of an electric auxiliary device (104) at the site of a connected electric load (103) located in a power circuit (100) in which a switch element (102) switches the operating state of the load with low losses while the auxiliary device is permanently supplied with electric energy. The circuit assembly has at least one bridge component (105) which is arranged in a parallel circuit with respect to the switch element (102), the circuit assembly has at least one support component (106) which is connected upstream of the load (103) such that the load (103) is supplied with power on the basis of the switch position of the switch element (102), and the circuit assembly has at least one auxiliary device (104), in particular a data processing device, which is arranged between the bridge component (105) and the support component (106) and which is supplied with power without interruption regardless of the switch position of the switch element (102), wherein the bridge component has at least one cyclically conductive switch element (107), and the support component (106) has at least one anti-cyclically conductive switch element (108) and a storage element (109). The invention also relates to a socket module and to an electric stairwell installation.

Description

Circuit arrangement for the clocked power supply of an additional electrical device at the site of a switched electrical consumer and building data processing device, base module and electrical stairwell installation

The present invention relates to a circuit arrangement for the clocked energy supply of an electrical auxiliary device installed at the installation site of a switched electrical consumer according to the preamble of claim 1, and a building data processing device.

Relevant documents in this area are DE 20 2021 101 687 U1 and DE 20 2017 005 523 U1.

DE 20 2017 005 523 U1 discloses a home communication system for multi-storey buildings with electrical loads that can be activated temporarily in communal systems. At least one communication module is installed in or on a temporarily activated electrical consumer of an existing communal system on any floor. In addition, a switching element is provided for further temporary activation of at least one electrical consumer. This is connected to the power supply of the communication module in such a way that a permanent power supply of the communication module is provided by permanently switching on the circuit for the electrical consumers carrying the communication module while maintaining the original switchability of the electrical consumer over the entire circuit. Specifically, an additional device for switching a consumer is provided in Fig. 3-5, with components designed as top-hat rails.

DE 20 2021 101 687 U1 shows a mechanical arrangement consisting of a base module for wall and ceiling lights. Here, priority is given to the mechanical and electronic interface of the individual modules.

Data processing devices for building automation are generally known from the prior art; For example, the use of digital controls and interface modules for mounting on standardized DIN rails in electrical distributors is common. As a rule, there is a central control computer with a data processing unit and interfaces in a wide area network (eg Internet) in combination with one or more application-specific modules with interfaces to the building-specific systems for use. These systems are usually powered via an integrated mains connection (e.g. 230 Vac) or via a direct voltage connection (e.g. 24 V). In most cases, the necessary infrastructure for installation and power supply is available in a building in excellent locations, such as utility rooms.

Data processing devices integrated in lighting systems, which, in addition to the installation site, also use the existing power connections of the lights and are also supplied with electrical energy from here, also correspond to the state of the art. Modern LED lighting systems already have integrated, sensor-based data processing units that use the power supply of the light. In these cases, the lights usually contain programmable, microprocessor-supported components, which, for example, also include status variables such as the presence of people or the ambient brightness in the decision-making process for switching the light on/off.

However, the systems described reach their limits when a data processing device that is dependent on a permanent supply of electrical energy is to be installed subsequently at the installation site of an electrical consumer whose circuit is switched via an external switch. For example, a lamp that is to be expanded to include a data processing device that requires a permanent power supply can only be switched on and off using a switch with relatively great technical effort. For this purpose, a known utility model describes a technical solution in which a switch and the associated load are operated in two separate circuits (cf. DE 20 2017 005 523). A switching signal, which is detected with the help of a sensor in a first circuit, is forwarded in the form of a switching command to the lamp in a second circuit and then leads to a corresponding switching action within the lamp.

Electrical load systems coupled to one another, such as lighting systems operated in groups and connected in parallel in the stairwells of buildings, are a further problem. If, in these cases, only individual lights are to be additionally equipped with data processing devices that have to be permanently supplied, there are no practical solutions today known, which allow the remaining lights in the same group to continue to be switched on and off via an existing light switch. In such cases, all the lights in a group usually have to be replaced with new, automatically functioning lights that are permanently connected to a power supply, which can be very expensive. In addition, every lighting and data processing system that is permanently connected to a power supply consumes a small amount of energy, even when it is ready for operation, which, when added up to the entire group, can have a considerable value.

Typical problems in the design and structural realization of data processing units distributed in a building thus arise when implementing a reliable supply of electrical energy to individual components. Certain technical building systems, sensors or actuators are often installed in remote, hard-to-reach locations within a building. So-called data collector and repeater components are usually used for the data transport of system, sensor or actuator data, which must be installed at different locations in the buildings concerned. Due to a lack of alternatives, these components are usually supplied with electrical energy either with batteries or with power cables specially installed for this purpose. The assembly of these devices and possible cable connections is relatively expensive and their operation causes a not inconsiderable maintenance effort, for example to replace batteries or repair damage caused by vandalism.

The result shows that the generic data processing devices for control and automation purposes in buildings that are assumed to be known are tried and tested, technologically diverse and functional, but these are particularly important with regard to future requirements for a decentralized use of increasingly powerful components, their inexpensive assembly, whose permanent and economical supply of electrical energy, their maintainability and repairability are in need of improvement.

The object of the present invention is therefore, taking into account the preceding explanations, to further develop existing electrical infrastructures, such as power cables and switch elements in the circuits of lighting systems, with the addition of new components, that an electrical system to be installed at the location of the respective consumer Additional device can be retrofitted with comparatively little effort and permanently supplied with electrical energy.

In addition, the invention can be used to create the mechanical and electrical prerequisites for installing a modern building data processing device as part of a digitization measure based on existing cable, lighting or bell infrastructures. Personnel trained in electrical engineering are able to install, operate and repair new information technology components easily and reliably at advantageous locations in the building.

The present invention solves this problem with a circuit arrangement having the features of claim 1 and a base module having the features of claim 9. According to the invention and particularly preferably, the circuit arrangement is used in an electrical stairwell installation. Advantageous configurations of the invention are the subject matter of the remaining dependent claims.

In an advantageous manner according to the invention, it has been found that it is an ideal way to install building data processing devices at the locations of switched electrical consumers in buildings and to permanently connect them there, preferably via at least two individual components that can be combined with one another and are electrically compatible with one another and that decisively supplement existing circuits to supply electrical energy.

With the invention, starting from the prior art, ie from a data processing device installed on a consumer, which is usually only uninterrupted with electrical energy by removing the switch element together with the consumer, a functionally separate power supply can be easily provided by simply adding two additional components implemented by data processing device and consumer. While the consumer continues to be switched on and off by the switch left in the circuit and negligible electrical losses occur in the operational state, the data processing device is continuously supplied with electrical energy regardless of the switch position. For further explanation, a circuit that is assumed to be present initially has a voltage source, a switch element and one or more loads that are temporarily switched on/off via a switch.

The new circuit arrangement for the permanent power supply of an electrical accessory installed at the consumer's site has a first bridge component, which is attached to the installation site of the switch element, is connected in parallel with it and periodically bridges it, so that the current flow is switched on and off cyclically. In the case of an AC circuit, the bridge component can be implemented, for example, in the form of a diode. The diode periodically conducts the flow of current for positive source voltages and blocks it for the duration of negative voltages. The parallel connection of bridge components and switches creates an electrical functional element that has two states. It conducts the current flow either continuously (switch closed) or only cyclically (switch open).

In a particularly advantageous manner, a new switch element can already be equipped with a bridge component that has the properties of the functional element described above and can therefore be inserted even more easily as an individual component into the new circuit arrangement.

In addition to the diode described, the bridge component can also contain other electrical components, such as transistors, which do not make the current flow dependent on the direction of the current, but instead periodically release it, for example with the help of a time control, for a specific period of a given period and release it for the rest Block period of period.

The circuit arrangement also has a second carrier component, which is usually installed at the installation site of the electrical consumer. The carrier component also has an electrically conductive element that conducts the current flow periodically, with its switching behavior being designed inversely to that of the bridge component. The carrier component conducts current flow during the periods when the bridge component blocks current flow and blocks current flow during the periods when the bridge component conducts current flow. In addition to this, the carrier component also has an electrical storage element that absorbs a certain amount of energy when a current flows and this Amount of energy delivered to a downstream consumer during the power interruption.

In the case of an AC circuit, the carrier component can be constructed, for example, by means of a diode and a capacitor. The diode will block the flow of current for the duration of positive voltages and conduct it through for the duration of negative voltages. When the current flows, the capacitor absorbs a new charge and passes the stored charge on to the consumer when the current is interrupted.

The bridge component and the load component thus have complementary properties which, when combined, have the following effect in the supplemented circuit: a.) When the switch is open, the bridge component periodically restricts the current flow for a certain period of time, in which the load component blocks the current flow. Conversely, the bridge component interrupts the flow of current cyclically in the remaining time of the relevant period, while the carrier component then transitions into the conducting state. As a result, the flow of current through the load in a series circuit made up of a bridge element and a carrier element is permanently interrupted when the switch is open. b.) When the switch is closed, the status of the bridge component is irrelevant. The function of the series connection of the bridge component and the carrier component is determined solely by the state of the carrier component. This cyclically closes the circuit for a limited period of time within a period and then also charges the integrated storage element, which transfers its charge to the downstream consumer when the circuit is closed. As a result, the current flow through the consumer either only periodically (low capacity) or continuously (high capacity) depending on the capacity of the storage element and the electrical load of the consumer. c.) An additional electrical device arranged in front of the carrier component is periodically supplied with current via the bridge component, even when the switch is open. Thus, in the event that the additional device itself has a storage element, the current flow for the duration of the interruption carried by the bridge element, an uninterrupted power supply of the additional device can be guaranteed.

The bridge component has an electrical interface with at least two contacts via which it is connected in parallel to an electrical switching element. The component can advantageously be designed as a top-hat rail module that is mounted on a DIN rail next to a stairwell light machine and is electrically connected to the machine in such a way that it bridges the switching element of the machine. In another embodiment, the bridge component can also be accommodated, for example, as a flush-mounted module in the installation box of a light switch and electrically bridge the switching element there.

The carrier component has an electrical interface with at least three contacts. On the one hand, the power supply and a possible additional device and, on the other hand, the power output in the direction of the consumer are connected via these contacts. Depending on the particular application, this component can be designed as a separate ballast for an existing consumer or as a new integral part of a consumer. For the use of a carrier component in a lighting system, the component can advantageously be designed as a separate base module between a wall/ceiling and a wall/ceiling light. In this application, the power cables from the wall/ceiling and the lamp are connected to this module.

The additional electrical device, the circuit including the switched electrical load and/or the switching element are only optional components of the circuit arrangement according to the invention within the scope of the present invention.

Particularly advantageous embodiments of the carrier component are carrier components integrated into a consumer or an additional device. For example, a carrier component can be integrated into an LED lamp in the future, which is characterized by the fact that it only works in a specific current direction in a circuit comparable to an LED . The shape of such a device does not differ from the lamp shapes known today. As before, the device can simply be screwed or plugged into the holders provided for this purpose. Another advantageous embodiment is represented by additional devices, such as data processing devices of a building data processing system, which are mounted at the location of a light between the wall/ceiling and a wall/ceiling light. The housing of this application can, for example, correspond to a flat, round or square base device, which is equipped on one side with a contact point for attachment to a wall or ceiling by means of a screw, rotary or plug connection and on the other side with suitable recording devices for installation of a lamp. The latter can also be designed as a screw, rotary or plug connection. A well-known utility model describes a particularly advantageous embodiment in which a data processing module is integrated into a lighting system (cf. "Data processing module of a modular lighting system and lighting system", Beenic Buildings Intelligence GmbH, DE 20 2021 101 687).

Further advantages, features and details result from the following description of preferred exemplary embodiments and from the drawings; these show:

Fig. 1 known view of an ordinary circuit;

FIG. 2 circuit of FIG. 1 extended by bridge component, carrier component and additional device;

FIG. 3 functional representation of FIG. 2;

FIG. 4 shows the implementation of FIG. 3 using the example of an AC circuit;

Fig. 5 Known wiring of ordinary automatic staircase lighting;

FIG. 6 Automatic stairwell light from FIG. 5 expanded by bridge components; FIG.

FIG. 7 shows the implementation of the bridge component from FIG. 6 using the example of a top-hat rail module with a circuit diagram;

8 example implementation separate carrier component with circuit diagram; Fig. 9 example implementation integrated carrier component in an LED lamp with circuit diagram

FIG. 10 Implementation representation of separate carrier components using the example of a base module for a wall/ceiling light; FIG.

FIG. 11 base module from FIG. 10 with circuit diagram;

FIG. 12 rear view of the base module from FIGS. 10 and 11 ;

FIG. 13 implementation illustration integrated carrier component using the example of a building data processing device integrated in a base according to FIG. 10;

Fig. 14 Block diagram of the building data processing device from Fig. 13.

Fig. 1 shows an ordinary circuit 100 consisting of voltage source 101, switch element 102 and consumer 103.

Fig. 2 shows the circuit shown in Fig. 1 expanded by a bridge component 105 and a carrier component 106 for the clocked power supply of an additional electrical device 104 and the consumer 103.

FIG. 3 shows a functional representation of the bridge component 105 and the carrier component 106 in the circuit from FIG. The carrier component contains a clocked switching element 108, which is closed for the duration T-t within one period, and one or more storage elements 109, which are exemplified as a capacitor and an inductor. The additional device 104 is connected to the voltage source 101 continuously when the switch 102 is closed, or in a clocked manner when the switch 102 is open, via the switching element 107 . The load 103 is only clocked when the switch 102 is closed and connected to the voltage source 101 via the switching element 108 .

FIG. 4 shows an implementation example of FIG. 3 in an AC circuit. The clocked switching element within the bridge component can be constructed with a diode 111 in this case. The clocked switching element In this case, conversion within the carrier component can also be carried out by means of a diode 112, which is operated in the opposite direction to the diode 111. The storage element within the carrier component is implemented as a capacitor 113 in this case.

FIG. 5 shows the known circuit arrangement of a conventional staircase timer 201 . The stairwell timer contains a relay or an electronic switching element that is activated via the button 203 installed in the stairwell and then switches on the stairwell lights 202 for a predetermined period of time.

FIG. 6 shows the circuit arrangement introduced in FIG. 5 supplemented by a bridge component 204 which is arranged in parallel with the switching element of the automatic staircase lighting device 201 .

FIG. 7 shows an implementation example of the bridge component 204 shown in FIG. 6 in the form of a top-hat rail module 205 that can be mounted on a DIN rail. This top-hat rail module has one or more electrical interfaces 206 with at least two contacts 206.1 and 206.2. In the example shown, these two contacts are connected to one another via a diode 111.

FIG. 8 shows an implementation example of a carrier component introduced in FIG. 4 in the form of a compact ballast with at least one electrical interface, which has a total of at least three, in the specific case four contacts. Inside this device there is a diode 112 connected between the two contacts 302.1 and 302.3 and a capacitor 113 connected between the contacts 302.3 and 302.2/302.4. According to the circuit from FIG. 4, the device shown is generally used as a ballast for an electrical load 103, which is only to be activated when the switch 102 is closed.

FIG. 9 shows an LED lamp 401 in which the carrier component introduced in FIG. 4, consisting of the diode 112 and the capacitor 113, is integrated. The lamp also has a rotary or plug-in closure with an electrical interface 402 with two electrical contacts, as well as a DC/DC converter 403 and an LED array 404. Contrary to an ordinary LED lamp, which is usually connected to a bridge rectifier is equipped, has the LED lamp shown only has a single rectifier diode 112. As a result, this LED lamp can only be switched on if the source voltage has the correct polarity. This property, which is actually a disadvantage for an ordinary LED lamp, represents a decisive advantage for the circuit arrangement of the invention. An existing lamp that is already installed as a consumer in an existing circuit can be used with the new LED lamp 401 be retrofitted very easily, to function according to the invention, for example in the lighting group of a stairwell lighting, which is equipped at individual points with new data processing devices.

FIG. 10 shows the perspective representation of an implementation example of the carrier component introduced in FIG. 2 in the form of a base module 504 for mounting a ceiling or wall light. In the case presented, the base module is plugged onto a wall/ceiling mount 502 which is mounted on a wall/ceiling 501. The bracket has an electrical interface 503, which has at least two electrical contacts to which the power supply lines of the lamp are connected. The base module has a housing cover 506, which is also used to attach a commercially available wall/ceiling light, which in the case presented can be mounted on this cover by means of a screw connection. The electrical interfaces of the base module are shown in FIG.

11 shows the two electrical interfaces of the base module used as a carrier component, as well as a circuit diagram. The module contains an electrical interface 507 on the input side, which in the case presented is designed to be compatible with the interface 503 of the holder in FIG. 10 and has at least two electrical contacts 507.1 and 507.2. In addition, the module contains an electrical interface 505 on the output side, which also has two contacts 505.1 and 505.2 and, in the case presented, is implemented using two cable connections.

FIG. 12 shows a rear view of the socket module 504 from FIGS. 10 and 11 . The two contact pins 507, which are designed to be compatible with the electrical interface of the wall/ceiling mount 503 in FIG. 10, can be seen in this view. FIG. 13 shows the inside view of a base module 504 with an integrated carrier component 604, which is also equipped with the functional elements of a building data processing device as an additional device 104 (cf. FIG. 4), with the cover open. On the one hand, the carrier component with the diode 112 and the capacitor 113 as well as the electrical interface 507 for contacting the power supply and the electrical interface 605 for contacting a connected load are located on a common printed circuit board 601 . On the other hand, there is an AC/DC converter on the printed circuit board as an electrical power supply for the circuit part of the data processing unit 606. This AC/DC converter usually has a bridge rectifier 602 and a capacitor 603 connected to it. The circuit part of the data processing unit has a usually via one or more DC/DC converters 607, a control unit with a microprocessor 608 and input/output elements 609 connected to it.

FIG. 14 shows a block diagram of the circuit parts relevant for the power supply of the building data processing device and a consumer connected to it. Both the data processing device and a downstream electrical consumer, which is connected via the two electrical contacts 605.1 and 605.2, are supplied with energy via the two electrical contacts 507.1 and 507.1 of the power supply interface 507. In this case, the integrated carrier component 604 takes over the clocked power supply of the load. Data processing unit 606, consisting of DC/DC power supply block 607, microprocessor 608 and input/output elements 609, is connected directly to the power supply interface via rectifier bridge 602 and capacitor 603.

Reference sign

100 ordinary circuit

101 voltage source

102 switching element

103 consumer (example: lamp)

104 electrical attachment

105 bridge component

106 carrier component

107 periodically closing switch inside the bridge component

(duty cycle t; t < T: period duration)

108 intermittently closing switch inside the carrier component

(duty cycle T-t)

109 electrical storage element (examples: capacitor, inductance)

110 AC power source

111 diode inside the bridge component

112 diode inside the carrier component

113 Capacitor inside the carrier component

201 automatic stairwell light

202 staircase light(s)

203 light button in the stairwell

204 Bridge components in the stairwell light application

205 bridge component as top hat rail module

206 electrical interface of the bridge component DIN rail module

301 carrier component in modular form

302 electrical interface of the carrier component module form

401 LED bulb (Example: E27 base)

402 electrical interface led lamp

403 DC/DC converter block inside LED lamp

404 led array inside led lamp

501 wall or ceiling

502 wall or ceiling mount

503 electrical interface inside the wall/ceiling mount

504 base module for luminaire mounting

505 electrical interface for connecting a lamp

506 base cover for luminaire assembly

507 electrical interface inside the base module (power supply)

601 circuit board 602 bridge rectifier

603 capacitor inside the power supply data processing equipment

604 carrier component within a data processing device

605 electrical interface for connecting a lamp 606 circuit part data processing unit

607 DC/DC converter within the data processing unit

608 microprocessor within the data processing unit

609 input/output elements within the data processing unit

Claims

Claims Circuit arrangement for the clocked power supply of an electrical accessory (104) at the location of a switched electrical consumer (103), which is located in a circuit (100) in which a switching element (102) switches the operating state of the consumer with low losses, while the accessory is permanently connected electrical energy is supplied, characterized in that the circuit arrangement has at least one bridge component (105) which is arranged in parallel with the switching element (102) and in that the circuit arrangement has at least one carrier component (106) which is connected upstream of the load (103), so that this load (103) is supplied with power depending on the switch position of the switching element (102) and that the circuit arrangement has at least one additional device (104), in particular a data processing device, which is connected between bridge components (105) and carrier component (106) and which is supplied with electricity without interruption regardless of the switch position of the switching element (102), the bridge component having at least one cyclically conducting switching element (107) and the carrier component (106) having at least one countercyclically conducting switching element (108) and a storage element (109). Circuit arrangement according to Claim 1, characterized in that the bridge component (105) is a diode (111) and the carrier component (106) have a diode (112) and a capacitor (113), the conducting directions of the two diodes being arranged opposite one another in the circuit arrangement and that the capacitor in the circuit arrangement is designed to absorb electrical charge for the period in which the diode ( 112) of the carrier component (106) conducts the current flow and to deliver this charge to a downstream load (103) when the diode (112) of the carrier component (106) interrupts the current flow. Circuit arrangement according to one of the preceding claims 1 or 2, characterized in that the bridge component (105) is part of a circuit of a staircase lighting installation in a building and there bridges the switching element of a staircase lighting device (201). Circuit arrangement according to one of the preceding claims, characterized in that the carrier component (106) is part of a circuit of a staircase lighting installation in a building, which also has stair lighting (202), the carrier component (106) as a ballast (301, 504). the stairwell lights (202) so that they can be switched via a stairwell machine (201) even after a bridge component (105) has been installed. Circuit arrangement according to one of the preceding claims, characterized in that the bridge component is designed as a top-hat rail module (205), preferably in such a way that this standardized DIN rail of an electrical distributor can be mounted. Circuit arrangement according to one of the preceding claims, characterized in that the bridge component is integrated into a switching element, preferably in such a way that only a single device is installed at the location of the switching element. Circuit arrangement according to one of the preceding claims, characterized in that the carrier component (106) is integrated into an LED lamp (401), preferably such that a lamp converted in this way can be adjusted depending on the polarity of its supply voltage. Circuit arrangement according to one of the preceding claims, characterized in that the carrier component (106) is designed as part of a base module (504) of a lamp, in particular a wall/ceiling lamp. Circuit arrangement according to one of the preceding claims, characterized in that the additional device (104) is designed as a building data processing device. Base module with the circuit arrangement according to one of the preceding claims, characterized in that the base module has two mechanical interfaces so that it can be arranged between a wall or ceiling (501) and a wall/ceiling light. Base module according to one of the preceding claims, characterized in that it has at least one electrical power supply interface (507) via which electrical energy is supplied to the circuit arrangement and at least one electrical interface (505) via which a downstream lamp is electrically connected . Electrical stairwell installation, in particular stairwell lighting system, building locking system and/or building signaling system, with a circuit and with a circuit arrangement according to one of the preceding claims.